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Home My WebLink About9.2 Motion to accept proposal for Village Hall HVAC Replacement Project design and construction engineering services for an amount not to exceed $92,400.00.Mr�GauC �'d'+rt;�iect engineeringSubject Motion to accept proposal for Village Hall HVAC Replacement Project design and construction for • not toexceed $921,400.00. /0 Meeting September 20, 2022 - REGULAR MEETING OF THE MOUNT PROSPECT VILLAGE BOARD - Fiscal Impact true Dollar Amount $92,400.00 Budget Source Capital Improvements Fund Category VILLAGEMANAGER'S REPORT Type Action Item A key goal of Mount Prospect's Strategic Plan is to maintain the village's infrastructure in good condition. One of this year's capital improvements is to remove and replace the heating, ventilation, air conditioning system (HVAC), including the roof top units, variable air volume boxes (VAV), and the building automation system (BAS) in the Village Hall building. The buildings HVAC systems are original from 2003 and have met their designed life expectancy. Presently, many of these HVAC components fail frequently. Staff is seeking to enter into a contract with a consulting engineering firm for design and construction engineering necessary to replace the referenced components. The proposed design will replace the existing HVAC systems, improve reliability and comfort, and increase energy efficiency. REQUEST FOR PROPOSALS: A request for technical and cost proposals was posted on the Demandstar website. Seven (7) consulting engineering firms responded submitting technical and cost proposals. Each firm was asked to submit as part of their proposal the following information: 1 Design Engineering • Review available original design and/or as -built documents to become familiar with the construction of the buildings HVAC system. • Evaluate applicability of local Energy Code requirements to this project. Determine the performance requirements for HVAC systems. • Perform a visual review of the HVAC system from the exterior and interior. • Review the HVAC study performed previously to ascertain viability of various options identified in the study. Construction Engineering • Conduct pre -construction meeting • Review contractor submittals • Review pay request • Perform on-site quality assurance • Prepare a field observation report • Prepare a photo report • Conduct periodic progress meeting with Village staff • Perform a final inspection and prepare "'punch list" of item to complete • Perform final walk through The consulting firm's submitted proposals were reviewed by staff on the basis of their understanding of Village goals as well as each firm's proposed resources and methodology. The responding firms were rated (with a maximum score of 100 points) according to these specific categories: company background, experience, scope of work, schedule, work effort and proposal content. The rankings are: 10 :101 00 10 1 Of_ •�0 Firm Background Experience Scope Schedule Work Content Total Effort 2 Maximum 20 20 25 15 10 10 100 Points Valdes Score Work Work Hourly Sub - Total 20 20 24 15 10 10 99 Eng. $79,300 $119 $13,100 $92,400 Eng. Syska Syska 98 650 75,990 $145 20 19 24 15 9 10 98 Hennessey Delta 96 839 102,090 $133 $10,047 Delta Progress Burns McDonald 19 19 24 15 10 9 96 Progress $69,920 $189 $16,630 $86,500 Eng. Burns KCE Eng. 86 371 $71,135 McDonald 20 19 22 13 9 10 93 Interface 19 19 23 15 6 10 92 Eng. KCE Eng. 19 19 20 14 4 10 86 Consolidated 19 20 20 5 5 5 74 Eng. COST •' • The cost proposal analysis is as follows= Firm Score Work Work Hourly Sub - Total Hours Cost Rate Consultant Valdes 99 776 $79,300 $119 $13,100 $92,400 Eng. Syska 98 650 75,990 $145 19,696 $95,686 Hennessey Delta 96 839 102,090 $133 $10,047 $112,137 Progress Burns McDonald 93 737 $144,655 $202 $4,500 $149,155 Interface 92 452 $69,920 $189 $16,630 $86,500 Eng. KCE Eng. 86 371 $71,135 $240 $18,000 $89,135 Consolidated 74 Not Not Not Not $152,400 Eng. Provided Provided provided Provided ' • KM Following review and ranking of the proposals, the top two consultants were interviewed by Village staff (Valdes and Syska Hennessey). Valdes Architecture and Engineering of Lombard, Illinois (Valdes) has a very strong project team with extensive experience designing building improvement projects. Notably, the Valdes Architecture and Engineering has completed similar building improvement projects for the Perkin Community High School, the Sauk Valley Community College, and the University of Illinois Chicago campus. Valdes has a thorough understanding of the project coordination, communication and documentation needs to successfully accomplish the project within the proposed schedule. It is the opinion of staff that Valdes has allocated sufficient and appropriate work effort to complete the specified scope of work. In addition, it is the opinion of staff that Valdes proposed hourly rate ($119/hour) and total fee ($92,400) is customary and competitive for this type of work. Alternatives 1. Accept proposal from Valdes Architecture and Engineering of Lombard, Illinois to provide design and construction engineering services for the Village Hall HVAC Replacement Project. 2. Action at the discretion of the Village Board. Staff Recommendation Staff recommends that the Village Board accept the proposal submitted by Valdes Architecture and Engineering of Lombard, Illinois to provide design and construction engineering services for the Village Hall HVAC Replacement project in an amount not to exceed $92,400.00. ATTACHMENTS: Valdes Response.pdf 144766 VOMP Village Hall HVAC Study_2022_07_14_Final Report (003).pdf RFP VH HVAC.2 (002).pdf 4 Response to: Request for Proposals Village Hall HVAC Unit Replacement August 19, 2022 August 19, 2022 Scott Moe Streets/Buildings Superintendent Public Works Department Village of Mount Prospect 1700 W. Central Road Mount Prospect, Illinois 60056 Re: Request for Proposals, Village Hall HVAC Unit Replacement Dear Scott: Valdes Architecture and Engineering (Valdes) is very excited to provide our response to your Request for Proposal for the Village Hall HVAC Replacement. Valdes is a multi -discipline design and procurement services firm with nearly 200 architects/engineers/designers and support staff. Our qualifications are demonstrated by our project portfolio which includes thousands of projects and a consistent track record of successful projects delivered. The size of our company is uniquely suited to supporting and/or managing not only large projects and ongoing programs, but also providing quick response and precise execution for smaller projects. Defined work processes and personal attention to detail are key elements in our success formula. Our reputation for Quality and Safety are well recognized throughout the architecture & engineering services community. I have arranged our response according to Exhibit A, Requirements for Technical and Cost Proposal. In reviewing our response, I hope you will keep the following in mind: We Ihnave the might expeirience-Valdes has a significant portfolio of experience executing HVAC and AHU replacement projects just like this one over that past 30+ years. We have included some recent projects in our response. We have extensive Municipal Cheint exlpeidence-Steve Ejnik, Project Principal and Mike Shrader, Project Manager have been working with municipal clients on renovation, planning and new facilities for almost their entire careers. We have included a recap of the projects we have completed for a variety of Chicagoland municipal clients for your review. We have standard, relpeatabie project execution processes that promote accuracy, responsiveness, and coordination. There's no magic to those processes, we just follow them religiously and because of this we enjoy project success after project success. We have a Iproject irnainageir who has been executing -these Ikiunds of Iprojects -for oveir 33 years. Michael Shrader, a licensed Architect, and project manager has been leading these types of projects for our municipal clients for all of his 33+ year career. Mike has seen it all and he knows how to anticipate areas where problems typically occur and mitigate them before they blossom into full blown crises. And, clients genuinely appreciate Mike's demeanor, attention to detail and follow through. We are a irrniinoirii-ty owned business -Valdes has been minority owned since its inception in 1992. We believe that our responsibility is not only to our clients, but also to the diversity community in helping other diverse firms succeed. Valdes Architecture and Engineering 1 100 West 22nd Street, Lombard, Illinois 60148 1 (630) 678-2804 6 We are thrilled to be responding to this request and ask that the Village of Mount Prospect award a contract to Valdes! Please contact me with questions or if further information is required. Thank you for your consideration. Sincerely, Steve Ejnik, PE, RA, LEED AP Vice President -Facilities Valdes Engineering Company Valdes Architecture and Engineering 1 100 West 22nd Street, Lombard, Illinois 60148 1 (630) 678-2804 7 Request for Proposals Village Hall HVAC Unit Replacements Village of Mount Prospect Company Addiress and irii f Firm History Lombard, Illinois Office Valdes Architecture and Engineering 100 West 22 d Street Lombard, Illinois 60148 Griffith, Indiana Office 211 West Ridge Road Griffith, Indiana 46319 FIRM HISTORY Owner and President Robert C. (Bob) Valdes, P.E. founded Valdes Engineering Company in 1992. With uncompromising dedication to service and quality, Bob guided our company from its humble beginning to the powerful engineering entity it is today. Since 1992, our company has grown to more than 200 professionals, offering a full range of industry leading expertise and services. Bob Valdes grew up in the City of Chicago and has lived in the Chicago metropolitan area essentially all his life. Bob earned his B.S. degree in Civil Engineering from the University of Illinois at Urbana -Champaign, and his MBA from the University of Illinois at Chicago. Bob is also a licensed Professional Engineer in Illinois and several other states. Bob spent the first 14 years of his career working for other engineering consultants in the Chicago area. Over that time he held positions of increasing responsibility, progressing from junior engineer, to engineer, to senior engineer, to principal engineer, to project engineer and then to project manager. Bob's progression from the lowest level of production engineering to overall project management responsibilities within the consulting industry provided the right background from which to design and build Valdes Engineering Company (VEC). During the 80's and early 90's, the "tech" craze was all the rage. However, Bob believed then as he does today, that the use of technology alone does not yield high quality. Bob believed then, as he does today, in using the fundamental principles of solid engineering and good management to achieve consistently good results. Bob also wanted to convey that there was a real live professional behind the work done by Valdes Engineering Company. Therefore, Bob used his own name for the new company. In 1997 the company expanded to 30 employees and moved to a larger office in Lombard, IL where its headquarters remain today. Over the next few years VEC continued to grow and diversify and by 2002 our client list included over 80 food, pharmaceutical, petroleum refining, chemical and consumer products companies. Another turning point for the company occurred in the spring of 2003, when VEC was awarded a cooling water piping project from BP in Whiting, IN. From that modest beginning, VEC has become a preferred supplier of engineering services to BP where we now support a wide range of capital and turnaround projects. With a significant base of work in Northwest Indiana, the company made the strategic decision to open a new 25,000 square foot office in Griffith, IN. This bold decision gave us a second major base of operation and an expanded presence in the region, providing VEC exposure to new clients and markets. Today as always, Bob comes to work at Valdes Engineering Company every day to ensure that the work product meets his high standards and that every document that leaves VEC continues to earn the right to his name. Valdes Engineering Company has come a long way since 1992. Over the years we have successfully executed .� VAI Arc:hitc a LK(' a nd Engineering 0 Company iress and I irii f Firm History thousands of projects for a diverse and impressive list of clients. Our work processes are geared toward identifying and understanding client requirements, allowing us to provide high quality services customized to each client. Bob's vision is the foundation of our success and the principles upon which we continue to grow and prosper. Valdes Engineering Company is a Minority Business Enterprise (MBE) as certified by the Chicago Minority Business Development Council, Inc. We were selected 2005 Minority Supplier of the Year to BP America and are a valued engineering resource to several Fortune 500 organizations. .� VA -1 Arc:hit(a tura:, and Engineering 10 Request for Proposals Village Hall HVAC Unit Replacements Village of Mount Prospect 12 STEVE EJNIK,. PE, RA, LEED AP VICE PRESIDENT - FACILITIES EDUCATION Northwestern University, Kellogg Graduate School of Management, MBA University of Illinois at Urbana -Champaign, BS Civil Engineering University of Illinois at Urbana -Champaign, BS Architecture REGISTRATIONS LICENSED ARCHITECT - IL, WI P.E. — IL YEARS OF EXPERIENCE 32 Mr. Ejnik is a Vice President working out of our Lombard Office. He is focused on expanding Valdes' national presence in our Facilities Business and is responsible for daily activities associated with project execution, strategic business planning, administration and business development. Steve also works closely with other Valdes offices supporting the firm's regional agenda for the Facilities Business, as well as all Valdes business lines across the country. Public Works Optimization Project, Village of Orland Park Orland Park, IL Principal in charge for the optimization of the existing public works building. Upgrades included expansion of truck fleet parking, salt storage, office renovations and additions as well as site planning for recently acquired vacant property around the public works facility. Renovations include office HVAC/electrical systems modifications/expansion. New High Potency APII Suite, ®Iltan Riceirca Brioscience Concord, OH Principal in charge for the renovation of existing wet laboratory space into a HPAPI suite for research and development. Project included significant HVAC modification along with new AHUs to ensure proper pressurization and air flow in the suite. Gowning and de -gowning rooms were also included. AHLU Replacement, Saul(Vaiiey Community College Dixon, IL Principal in charge for the design of a new fire station facility for this refinery along with renovation of several existing spaces to accommodate firefighting operations. The new fire station was designed to accommodate a blast force of 1.5psi due to proximity of the station to other refinery units. IHVAC upgrade, (East Moline Correctional Center East Moline, IL Principal in charge for the rehabilitation of the HVAC system including replacement of steam absorption chillers, cooling towers, pumps, air handling units and control systems in several different buildings in the correctional center. Also included was extensive roof replacement including roof sheathing replacement damaged by moist air being exhausted into the attic space of several buildings. 13 STEVE EJNIK, PE,, RA, LEED AP Einglineeriing Research Facility (ERF) Clean IR omi, University of Illliirnois at Chicago Chicago, IL Principal in charge for a project to upgrade the existing mechanical, electrical and plumbing infrastructure serving the clean room facility, correct deficiencies that are present and meet the clean room performance requirements. Meclhannicall IEnngirneer Retainer, Illlllirnois State University Normal, IL Principal in charge for a three-year retainer agreement for mechanical engineering services. Architecture & Engineering ID/110, Geinerall Services Adinniiinistratiorn State of Ohio Principal in charge and project manager for services provided to the U.S. General Services Administration for architecture and engineering assignments relating to building upgrades, renovations, and additions to federal buildings in the state of Ohio. The team for this five-year contract includes multiple specialty subconsultants and socioeconomic firms. Project included assessment of existing outside air intake louvers which were leaking and allowing coils to freeze in the air handling units. Specified new ultra-low leakage dampers to replace existing and generated construction documents to allow competitive bidding. Provided acoustical analysis and recommendation for minimizing air handling unit vibration and ambient noise in federal courtrooms around the courthouse. S cgsStar Tu. g�i...... Existing air handling unit at the top of this stair tower was leaking significantly. Prepared design documents to replace the air handling unit and associated structure and roofing. Jurist C� � �g._g�s:.. Existing jurist space was plagued with areas with extreme cold and hot temperatures making for a very uncomfortable situation. Designed mechanical ventilation to adequately move tempered air throughout the space to remove stratified air. US...Customs._ ...1 gratia a Service US IS0ffice _Renovation Renovation of existing office space to accommodate expansion of the USCIS office space. Project included reuse of some of the existing doors and hardware along with an evaluation of the existing HVAC system, which was found to be deficient. Demolition, HVAC renovations, new wall partitions and finishes were included. Extensive care was taken to recreate the existing lighting pattern on the ceiling as the Celebrezze Federal Building is on the National Register of Historic Places. !! S ._ Lice Renovation An extensive and complex renovation of an existing office space in a Courthouse and Federal Building. The existing space was occupied by the Bankruptcy Attorney's office and the USMS desired to renovate to utilize as a new office space for their operations. Spaces included offices, two shelter in place (SIP) spaces, detention cells, FIT room, control center, vault and a variety of specialty spaces. Complex fire alarm and life safety provisions were necessary for this multi -use space. Also, detention areas required extensive detailing and planning as the walls were planned to be steel partitions which had to be moved to the floor via freight elevators with limited space. Also, existing floor structure had to be reinforced to accommodate new heavier partition loads. o SENIOR PROJECT AA EDUCATION University of Illinois -Chicago — Bachelor of Architecture / Minor — History of Art & Architecture REGISTRATIONS RA—IL YEARS OF EXPERIENCE 35+ Mr. Shrader has over 35 years of experience as a client and project manager, project architect, and construction administrator for a variety of corporate, industrial, government, and higher education projects primarily located in the state of Illinois. Mike has been successful throughout his career in establishing true partnerships with each of his clients by earning their respect, trust, and support during the course of the project from initial selection to occupancy of their facilities. Public Works Optimization (Project, Village of Orland Park Orland Park, IL Project Manager for the optimization of the existing public works building. Upgrades included expansion of truck fleet parking, salt storage, office renovations and additions as well as site planning for recently acquired vacant property around the public works facility. Renovations include office HVAC/electrical systems modifications/expansion. A1H U Replacement, moll(Valllley Community College Dixon, IL Project Manager for the design of a new fire station facility for this refinery along with renovation of several existing spaces to accommodate firefighting operations. The new fire station was designed to accommodate a blast force of 1.5psi due to proximity of the station to other refinery units. (HVAC upgrade, (East Moh ne Correctional Center East Moline, IL Principal Manager for the rehabilitation of the HVAC system including replacement of steam absorption chillers, cooling towers, pumps, air handling units and control systems in several different buildings in the correctional center. Also included was extensive roof replacement including roof sheathing replacement damaged by moist air being exhausted into the attic space of several buildings. Smmnaill Scale HIPAIPI IKilo Laboratory Oloirn IRicerca Concord, OH Project manager for the interior renovation of existing space to create a HPAPI small scale HPAPI kilo lab. Existing rooms 106, 107, and 108 located on level 1 of Building B will be repurposed to provide the needed space for the small scale HPAPI facility. The facility will include: • Common corridor. • Material airlock. • Personnel airlock. • Equipment airlock. • Production area. • Office area. • Technical space. o 15 SENIOR PROJECT MANAGER The HPAPI facility design will allow for the installation of two glove box isolators, necessary buildout fit and finish, comfort cooling chiller upgrade, stand-alone HVAC and exhaust systems, and necessary utilities including their distribution. Engineering Research Facility (ERF) Cleain Room University of Illinois at Chicago Chicago, IL Project manager for a project that upgraded the existing mechanical, electrical and plumbing infrastructure serving the clean room facility, corrected deficiencies that were present and meet the clean room performance requirements. West Heating INaint Addition, Northern Illinois University DeKalb, IL Project Manager for the design of an addition to the West Heating Plant at Northern Illinois University. The addition will house three new boilers, a co -generation unit, and plant support space including office space, lockers / restrooms, and training room. The project included bridging documents (Basis of Design, specifications, and drawings) that were then used by the Illinois Capital Development Board to solicit design -build proposals from local contractors. Argonne National Accelerator Laboratory Argonne, IL Project manager for a multi-year term agreement to provide architecture and engineering services. Task orders included work on lab -wide site work projects and the renovation of existing interior spaces. Projects executed included: • FY 2015 / 2016 Campus Wide Site Work Program • FY 2016 / 2017 Campus Wide Site Work Program • Building 202, 8169 Conference Room Rehabilitation • APS Booster Tunnel Waterproofing • East / West Cabling Plant - Scope Definition • Building 201 Cooling Tower Rehabilitation and Canal Water Main Replacement • Building 377 Cooling Tower A/B Replacement • Building 208 F -Wing Rehabilitation — Conceptual Design • General architectural / engineering support activities including peer reviews and vehicle charging stations Innovation Park Incoming Quality Laboratory Expansion - Avexis Libertyville, IL Project manager for expansion of approximately 16,000 square feet for Incoming Quality operations including first - floor offices, cleanrooms, sample booth, room temperature retain storage, incoming quality labs, walk-in freezer, storage racking, mechanical and electrical areas, and shops. A second -floor mezzanine included for the cGMP classified space and for light industrial storage over the office space. The project proceeded through Design Development before being canceled by the Client. Wallgireens" Ann ual R'TIJ Replacement Program Walgreen Company Deerfield, IL Project manager for annual roof top mechanical unit (RTU) replacement program. Provided recommendations for over 800 retail stores throughout the United States and Puerto Rico. The project completed in a compressed schedule to align with fiscal budget requirements for procurement and construction. �l ho Cancord Grout o - II ey Persarvnd C IIE IIR . If.::Nrectoir, Cosf Mainagerneint About JdhIri John, us knvoNed fin the pirepairafloin of o�l stages of cost esHinnates froinni coinceptu(,..ill deli in thirough coinistin.ictbin docurnents and cha.. inge oirders foir various uinsfitufioins, airchtects/eingfineeirs aind private cIlieinits. I N Ihas beein kivolved urn a Wde variety of 1pirojecfs foir flhe flirim's goveirininneintall and 41SNILAOI`10ll c5eints. 111hno wJue r')f Illheso protects exceeds $3 IBJilllllioin. Johin, cooirdlinates 1Hhe Airc['Oecfuirol, CMl,. Sfiruchjiral, and M F1 sysfer"r'lis to care ate a cohesuve and coryipireheinsive esfiiirnate. II e 'ii's respoins'i'L)b for cireafling coinnipaifisoins betweein flhe Concoird Group's esflim(:,Ited costs r.jind those of coin, firactoirs' oar otheir esflinnating firms, 'IIID enler ice asollrllnl Illlllilnois 4U11-111va-SHY Challk--siclln, IIi c'4 Science, induslricl� Airgoi- : ii i -m, MckallJs ucsiginda�!��)oialoiy Airgoinii-uPOH Cost : 'sflimafling seirvices foir the Mateirb�s Des�gini I aboirafoiry. Tota�� squaire �ochnr�)Ir�)qy C(�mccnimfion an foot(,.ige (,')f 105,000 S[". Fota�l coinsfirw"floin cost of $65 Mflfioin. Coi, Airgoinine ',Iahoinall Il cjlboiniloiies Aldvninced IIliroa Gni CiryslalHfzaHoini acflfly �Prafessla'idl AffidRalians A rg o in ii i c Assocbibin foii II o Advo f:. ,,ii(-',,nh C�:'.)st E 'stfr-nntfing seirvic-es for coinceptucfl estfir-nates for two bufl6ing of Cod i Ingh"Icolling (Ci i:1) aHleirinafives. Opflions hn6ud :� ed a sfnigle sfoiry bufldiing of 45,000 &F� or'a two storybuH6ing of 49,000 Sf::. F.:.sfiiimiated coinsfirucHoin cost of $19 MJlIbin to $23 Mlilltioini (based oin alteinn(..jffveseected), 21 "rill s Wfilhl11 C,olllicoll + I Iuii due 1) niveii sflhy. C61E.)ge of Ve ll eiriii airy Medrfim:.' Wes �l La [aye e,, 111`4 2 o�a�� yo(��iiis of ox�,-,�oiiicince Cost I sHinnafling services foir the new 74,580 &1"' College of Veteiriinairy ,1 Med61nie faciRy. Fotall consfiruchoin cost of $ f 05 Whom Fluldule, lJl-llvCl-SflY' Ifuunasflloy 3k,)sciejqC() WC,,S11 II afa:,cyollllc,, 1111`11 Cost F.:'sflimafling services foir the new 29,000 Sf::� Bbscieil-nce facfH.y. Totall consfirur-floin cost of $123 MlHbin. PUil'l(JIUO UliVOII'Sfly, Q('11-ul �cll-t S(Jhooof MIJIIKIgOIITIClli11 A IIU Jim sf Il of aye Ho, I I'll ost F.::sflinniatfing services for the renovahoin or) the IKrcarninerf bAelfin g. Fotall coins I i I k)ini cost of $3 MJlItioin, 17 ROLANDo EsQuIVEL, PE SENIOR ELECTRICAL ENGINEER EDUCATION University of Illinois at Urbana -Champaign, BS Electrical Engineering REGISTRATIONS PROFESSIONAL ENGINEER— IL YEARS OF EXPERIENCE 12 Mr. Esquivel is a licensed professional engineer providing electrical engineering design services for a wide variety of project types. Rolando excels at creating unique solutions as well as and applying proven solutions to project designs. Mr. Esquivel is experienced in power and lighting designs for classrooms, offices, laboratories, healthcare, assembly, and event centers through to super tall high-rise projects. Mr. Esquivel provided electrical engineering design services on the following projects. For some of the projects, he functioned as the project engineer and for other projects he functioned in a support role. HIGHER EDUCATION • Turner Hall - University of Illinois at Urbana Champaign — Classrooms and Office Renovation • Surveying Building - University of Illinois at Urbana Champaign — Classrooms and Office Renovation • Speech & Hearing - University of Illinois at Urbana Champaign — Classrooms and Office Renovation • University of Illinois at Chicago • University of Chicago • Graduate School of Education - University of Pennsylvania — Office and Classroom Expansion • Hazelton Library - Pennsylvania State University —Complete Renovation of Existing Library • Siegel Hall — Illinois Institute of Technology — Fire Alarm System Renovation HEALTHCARE • DeVry — Carrington Phoenix, Arizona — Dental School with Operatory Lab and Classrooms. • EP Lab UoC — University of Chicago Medical Center — Chicago, Illinois — Electrophysiology Lab • CCHS — Illinois Medical District, Chicago, Illinois — Cook County Healthcare System Ambulatory Building • EP Lab UIC — University of Illinois at Chicago Medical Center — Chicago, Illinois — Electrophysiology Lab • Heart Rhythm Center— Promedica Hospital — Toledo, Ohio — Electrophysiology Suite of 3 ORs K-12 EDUCATION • Chicago Public Schools — Chicago, Illinois — Existing School Renovations • Andrean High School — Merrillville, Indiana — Existing Facility Evaluation and Condition Report • School District 207 — Park Ridge / Des Plaines, IL — High School Renovations VAI J"DES Architecture and Engineering 18 ROLANDo EsQuIVEL, PE SENIOR ELECTRICAL ENGINEER LABORATORIES • ACF - NASA Glenn Research Center — Cleveland, Ohio — Specialty Testing Laboratory Facility ASSEMBLY AND EVENT CENTERS • Wrigley Field Modernization — Chicago, Illinois — Modernization of Chicago Cubs Baseball Stadium RESIDENTIAL • 1035 W Van Buren — Chicago, Illinois — High -Rise Residential Building • 777 N Van Buren — Milwaukee, Illinois — High -Rise Residential Building • One Hundred — St. Louis, Missouri — High -Rise Residential Building • Playhouse Square — Cleveland, Ohio — High -Rise Residential Building • Woodlawn Station — Chicago, Illinois — Mid -Rise Residential Building OFFICE • Harper Court — University of Chicago — New High -Rise Office Tower • Navistar Corporate Headquarters — Lisle, Illinois — Multiple Office Building Campus • Harris Keller Center — University of Chicago — Full Office Renovation SUPERTALL HIGH-RISE • Kingdom Tower—Jeddah, Saudi Arabia—Supertall Office, Retail, and Residential Building • King Abdullah Financial District — Riyadh, Kingdom of Saudi Arabia — New Office and Residential Towers • Wanda Tower — Chicago, Illinois — Design -Build Narrative and Consulting SPECIAL OCCUPANCY • Illinois Street Dining Facility - University of Illinois at Urbana Champaign — Classrooms and Office Renovation • Moddy Bible Institute — Chicago, Illinois — Radio Broadcasting Facility VAI ES Architecture and Engineering 19 110-1 EL GLEASON, PE PRINCIPAL MECHANICAL ENGINEER EDUCATION University of Florida — B.S. Mechanical Engineering REGISTRATIONS PE- 34 States NCEES Record Holder LEED Accredited Professional QCxP - Qualified Commissioning Provider YEARS OF EXPERIENCE 17+ SOFTWARE SYSTEMS Carrier HAP, Trane Trace Design Master - HVAC, AutoCAD, Revit MEP, Caesar II As a Principal Engineer, Mr. Gleason performs as a department lead and manages department scope, execution plan, budget, and schedule for projects while directing the activities of multiple engineers and designers within the project. Other responsibilities include checking project deliverables, mentoring junior staff, verifying field conditions and constructability of designs, and interpreting engineering drawings and specifications in the field. He also identifies areas and implements processes to continuously improve the execution of the department. He develops project scopes; manhour estimates and schedules while interfacing with internal and external stakeholders to ensure project goals are accomplished. All tasks and responsibilities are performed with an emphasis on safe design and execution. Fire Stadion Remodel - Glenview Fire Station # Glenview, IL Principal Mechanical Engineer— Remodel of an existing Fire Station. Areas remodeled included bunk room, fitness room, locker rooms, restrooms and kitchen/dining room. Public Works — City of StaMey Stanley, ND Engineer of Record — New approximately 10,000sf public works building. Building included approximately 8,000sf of maintenance facility space and 2,000sf of commercial office space. Boiler Replacement - Westmont Public ILibrary Westmont, IL Principal Mechanical Engineer— Boiler replacement/upgrade project at library. Primary School Renovations -White Water School (District White Water, WI Engineer of Record - District -wide renovations and additions to five elementary and middle schools with a project budget of $23 million. Renovations included new equipment, ductwork, and plumbing. High School Addition/Renovations - Baraboo High School White Water, WI Engineer of Record - Renovations and additions to Baraboo High School. The total building size is 220,000 s.f. with 25,000 s.f. of new construction and 195,000 s.f. of plumbing, fire protection, HVAC and other renovations with a construction budget of $18 million. HVAC modifications included new chiller and boiler plants. (HVAC Improvements and Upgrades - Addison School District #4 Addison, IL Engineer of Record — Provided engineering service for multiple projects across all the nine schools within the district. Work included full plumbing replacements, Built-up air handing unit replacements and boiler upgrades and DDC control upgrades. DE -�� VAI ENGINEERING COMPANY 20 10- EL GLEASON., PE PRINCIPAL MECHANICAL ENGINEER Diixoin IEllemneinU;ary School — Chicago Public Schools Chicago, IL Principal Mechanical Engineer - Replaced two existing 7,OOOmbh 80+yr old steam boilers with new condensing boilers. Entire system was updated from steam to hot water heating, including new fin tube radiators, pumps and piping. Coahuila Creek High School Whitfield C tuinty School District Dalton, GA Principal Mechanical Engineer— Provide mechanical design for a ground up 3 -story, 260,OOOsf high school. New construction budget was approximately $40 million. 600 ton HVAC system consisted of high efficiency condensing boilers, water source heat pumps and fluid coolers. Eastbrook IMiddle School Whitfield Co uinty School District Dalton, GA Principal Mechanical Engineer— Provide mechanical design for a ground up 2 -story, 135,OOOsf high school. New construction budget was approximately $25 million and largely funded due to $15million in savings from the Coahuila Creek High School. HVAC system consisted of high efficiency condensing boilers, water source heat pumps and fluid coolers. Assisted Liviiing IFacillirty .•• Evergreen Place Chillicothe, IL Principal Mechanical Engineer - A new, 93 -unit assisted living apartment home. Measuring 94,400sf at an estimated cost of $11 million. Hloslpitall Air IHaindlleir luunlproverneints — Stainfoird Uniiveirsirty Palo Alto, CA Engineer of Record —Scope of work included modernization of (2) air handling units located in the hospital interstitial space. Due to space constraints, new units could not be installed. Individual components were selected and retrofitted in place including fans and heating and cooling coils. Incus ,Statioin — PACE Plainfield, IL Engineer of Record — New bus station and parking lot. Bus station had a large waiting room, restroom and mechanical room space. Oak (Forest (Mehra Statioin IMIETRA (Rail Oak Forest, IL Principal Mechanical Engineer—A new Metra train station. HVAC system consistent of geo-thermal water source heat pumps. Reinaiissance on Mahn lrlhe Reinaissance Corrulpainies Williston, ND Engineer of Record - MEP services for a new, seven -story, mixed-use building in a vibrant downtown setting. Over 135,000 square feet with a total construction budget of $14 million. Larson also designed special features, including an attached, heated parking facility, a large roof terrace with outdoor kitchen equipment and a pergola, a fitness center, and individual heating and cooling control in all apartments. SENIOR A' EDUCATION Saint Louis University— B.S., Mechanical Engineering REGISTRATIONS P.E.—IL, FL REGISTERED ENERGY PROFESSIONAL (CITY OF CHICAGO) LEED® GREEN ASSOCIATE YEARS OF EXPERIENCE 40+ Mr. Escobar is a Professional Engineer with over 40 years of multi -disciplinary (Mechanical, Plumbing, and Fire Protection) experience within the A/E/C industry on a variety of system types. His career expertise has included extensive involvement within the commercial, institutional, production and industrial facilities markets. As Project Manager/Engineer, his responsibilities have included all phases of the design building processes, including: pre -conceptual analysis, preliminary design, development of construction documents, bid phase procedures as well as system's commissioning. His seasoned experience has also included: comparative systemic energy/cost modeling with life cycle projections, procedural calculations, system evaluations, construction observation, strategic problem solving, quality control adherence and administrative activities. Mr. Escobar was a past member of several Professional Affiliations, including ASHRAE (American Society of Heating, Refrigerating, and Air -Conditioning Engineers) and AEE (Association of Energy Engineers). Building G (HVAC Upgrades — Pekin Community IHigh School Pekin, IL Provided the construction documents for the HVAC upgrade to Building G at Pekin Community High School. The project included engineering design, design documents, permitting, estimate of probable construction cost, bidding, and part-time construction administration. Building G, constructed circa 1962, consists of roughly 82,000 square feet of education facilities including science laboratories, physics laboratories, classrooms, media room, administrative offices, and other educational space requiring exhaust systems. Project is estimated to cost $4 million. The engineering design included mechanical, electrical, plumbing, architectural, and structural, for replacement of HVAC systems, including four (4) primary air handlers, ductwork, chilled water and heating water piping, boilers, variable air volume (VAVS) terminals, instrumentation, and controls. The design included structural and architectural modifications to accommodate new mechanical rooms, return ductwork, and energy conservation measures. The air handling units are modular to accommodate installation in an existing crawlspace, which provides access for maintenance, without disturbing classroom activities. Building A HVAC Upgrades Pekin Community High School Pekin, IL Provided the construction documents for the $2.63 million HVAC upgrade to Building A at Pekin Community High School. The project included engineering design, design documents, permitting, estimate of probable construction cost, bidding, and part-time construction administration. Building A, constructed circa 1973, consists of roughly 89,000 square feet of technical education facilities, including an automotive lab, woodshop, computer (drafting, graphics, computer science) laboratories, classrooms, art workshop, science classrooms, administrative offices, day care, foods laboratory, and other education facilities requiring custom exhaust systems. The engineering design included mechanical, electrical, plumbing, architectural, and structural for replacement of HVAC systems, including nine (9) roof top air handling units (AHUs), ductwork, chilled water and heating water piping, 66 variable air volume (VAVS) terminals, 19 exhaust fan replacements, 3 new exhaust fans, instrumentation, r • r 22 f SUBJECT r MATTER ■ and controls. The HVAC design included structural and architectural modifications to existing roof curbs, in addition to improvements in energy efficiency with LED lighting, return duct, and AHU design. The project was bid and constructed within the contract budget with minimal field change orders. Rental air/Pairkiu"ng IFaciRty and Transit System (A"f"S) Expansion & Modernization ... O'Hara International Airport Chicago, IL Design of mechanical and plumbing systems with the goal of the facility is to consolidate all rental car operations at O'Hare under one roof. Each rental car company using the facility will have a dedicated customer service area, self-service kiosks and back office area. An expansion of the existing airport light rail system will connect the facility to the O'Hare airport terminals. The mechanical systems designed included HVAC systems using a new geothermal plant throughout the facility. Energy conservation was implemented using the LEED point system. Other implemented features are rain harvesting and snow melting systems. The proposed project budget was $800M. Various Projects AlblbVie North Chicago, IL & Abbott Park, IL • Replacement of Air Handling Units -North Chicago Bldg. P8A, Bldg. P1E • Plumbing -North Chicago Bldg. A4 New Water Heater • Plumbing -North Chicago Bldg. A4 New Somat Machine for Dishwashing Operations • Providing Outside Air Intake Hood -North Chicago Bldg. P1 for Boilers' Combustion Air • Replacement of Laboratory Exhaust Fans- Abbott Park Bldg. Ap10 • Replacement of Office Exhaust Fans -Abbott Park Bldg. Ap30 • Campuswide Fire Protection Modifications -Various Proposals • Preliminary Engineering and Cost Estimate -North Chicago Bldg. R12 Replacement of Process Condensers and Vacuum Equipment, Basement Walk -In Cooler Modifications • Building R12 Vacuum System Evaluation Report • Building R8 Replacement of Air Handling Units AS02, AS03, ASO4 in various phases • Building R8 New Energy Heat Recovery System • Building R8 Process Vacuum Pump Replacement • Building AP9 Lower Level Piping Upgrade Hotel Bellevue Chicago, IL Mechanical, Plumbing and Fire Protection design, construction and specification development for the integrated systems involving a new 22 floor (247 guest room) hospitality center serving the Chicago downtown district. Development included guest suites, meeting centers, banquet facilities, kitchen and dining services designed within Chicago's high-rise code development. irnbassy Suites IHotell Rosemont, IL, Southfield, MI, Deerfield, IL, & Lombard, IL Mechanical, Plumbing including a domestic hot water storage tank and Fire Protection design, construction and specification development for the integrated systems involving new hotel buildings ranging from 7 to 11 stories. Development included guest suites, meeting centers, banquet facilities, kitchen and dining services, indoor fitness/pool/spa services and atria areas. M10-1ELE TYDUS, SE, PE SENIOR STRUCTURAL R I" EDUCATION University of Illinois — B.S. Civil Engineering REGISTRATIONS P.E. — IL, MN S.E. - IL YEARS OF EXPERIENCE 23+ SOFTWARE SYSTEMS Autodesk AutoCAD, Navisworks and Revit, Bentley MicroStation VBi, Fastrak, RISA 3D and Floor, RAM Elements, RAM Structural Systems, MathCAD, PSBeam, PYWall, Safe, Structure Point Slab and Beam, TEDDS and STAAD Pro Ms. Tydus is a Senior Structural Engineer with experience designing structural systems for higher Education, Government and Industrial clients. Her responsibilities include designing structural systems with steel, concrete, masonry and wood along with checking project deliverables, mentoring junior staff, verifying field conditions and constructability of designs, and interpreting engineering drawings and specifications in the field. She also identifies areas and implements processes to continuously improve the execution of the department. She develops project scopes; manhour estimates and schedules while interfacing with internal and external stakeholders to ensure project goals are accomplished. All tasks and responsibilities are performed with an emphasis on safe design and execution. Second District Appellate Court, Illllinois Capital Development Board (CDB) Elgin, Illinois Project Structural Engineer for design documents for the repair of steel supporting large windows on three sides of the Courthouse. Responsible for specifications related to the window support repair and for generating cost estimates for the project. Fleet Management Garage, City of Chicago Chicago, Illinois Provided structural engineering services for the renovation of the existing a 2FM Off Road Vehicle Maintenance facility at 3757 W. 54th Street. Efforts included site inspections and analysis of the existing structure for the support of new mechanical units and hose reel supports as part of the work to convert this existing building to a Vehicle Maintenance Facility. Provided construction documents and construction administration services. HarroldWashing-ton Library Renovations, City of Chicago Chicago, Illinois Provided structural engineering services for the renovation of the existing library for the addition of a generator for life -safety, along with design of a fire -rated room enclosure with mezzanine roof. Tasks included on-site observation and analysis of the existing floor slab to support the addition of a large generator and fuel tank. Provided construction documents for the reinforcement of the existing floor slab using fiber -wrap along with construction administration services for the project. Historical Building Renovation, U.S. Army Corps of Engineers Ft Benning, Georgia Renovation of an existing historical building that required structural evaluation and design of new structural steel framing for stair/mechanical openings and an interior elevator shaft. Project also included the design of light -gauge and tube steel frames around existing window openings to take blast loads per USACE standards. VAI I S..-, ENGINEERING COMPANY 24 M10-1ELE TYDUS, PIE, SIE SENIOR STRUCTURAL ENGIN r. Illilnoils Medical District Station Rehabilitation, C"I"A Chicago, Illinois Provided Structural Engineering services for the preparation of design drawings for the Congress Blue Line Medical District Station renovation. Acted as Lead Structural Engineer for construction administration portion of the entire design work for the rehabilitation/renovation of Stationhouses, Concourses and Platform structures at the three stationhouses comprising the Congress Blue Line Medical District stop (Damen, Paulina, and Ogden). Miscellaneous Structural Design, US Generall Services Administration Chicago, Illinois Projects include structural evaluation for renovations, new concrete sidewalk ramp addition for a cast -in-place garage structure, slab repair design and details, concrete infill for basement location and repair of existing building columns. Building 8C & Terlrruilrnall 3- IH/IIS Concourse Renovations, O'lHare Airport, Chicago DOA Chicago, Illinois Project included the analysis of existing penthouse floor structure for new mechanical units, design of temporary rooftop supports for mechanical units along with the design of temporary supports for ductwork, piping, and security fencing. Responsible for providing specifications and cost estimates for the project. Medical Office Building, St. lBernard Hloslpitall Chicago, Illinois Lead Structural Engineer responsible for a design -build project for an 70,000 sq. ft. medical office facility. Executed the design of the building and drawing production in Revit. The structure consists of a steel beam/column superstructure with pre -cast wall and glass exterior and concrete spread/strip foundations. Responsible for developing specifications and contract documents along with providing construction administration for the project. Talbot I..alb Additi ln, University of Illinois at Urbana-CIhaimpaigla Urbana, Illinois Project Structural Engineer for design of an approximately 9000 sq. ft. addition (with a basement level and two stories) to an existing university classroom/laboratory building. Drawings were produced in Revit. The structure consists of steel beam/ column/roof joist superstructure with masonry wall and glass exterior. Boiler Room Addition, Moraine Valley Community College Palos Hills, Illinois Project Structural Engineer for design of a boiler room addition. Grade beam/pile foundations supporting steel column and beam structure with metal deck roof. Structural Analysis, Northwestern University Evanston, Illinois Structural evaluation of an existing aquatics room for new tanks and lab equipment. Underground Lift station, College of Du illage Glen Ellyn, Illinois Design of an underground lift station. Cast -in-place concrete. Facade Repair, Edward Colles School, Chicago Public Schools Chicago, Illinois Provided structural engineering services for the repair of existing historic terra cotta/limestone door and window lintels along with the design of a concrete ADA accessible ramp at the entrance to the building. Coordinated design details with peer reviewer to meet client and permitting expectations. VALD'1,�,_J'S ENGINEERING COMPANY 25 Request for Proposals Village Hall HVAC Unit Replacements Village of Mount Prospect Buildings A & G HVAC Replacement Pekin Community High School, Pekin, IL Building A HVAC Upgrades Provided the construction documents for an HVAC replacement project to Building A at Pekin Community High School. The project included engineering design, design documents, permitting, estimate of probable construction cost, bidding, and part-time construction administration. Building A, constructed circa 1973, consists of roughly 90,000 square feet of technical education facilities, including an automotive lab, woodshop, computer (drafting, graphics, computer science) laboratories, classrooms, art workshop, science classrooms, administrative offices, day care, foods laboratory, and other education facilities requiring custom exhaust systems. The engineering design included mechanical, electrical, plumbing for replacement of HVAC systems, including nine roof top air handling units (AHUs), ductwork, chilled water and heating water piping, 66 variable air volume (VAVs) terminals, 19 exhaust fan replacements, 3 new exhaust fans, instrumentation, and controls. The HVAC design included structural and architectural modifications to existing roof curbs, in addition to improvements in energy efficiency with LED lighting, return duct, and AHU design. The project was bid and constructed within the contract budget with minimal field change orders Size: 90,000 s.f. Cost: $3.2MM Completion 2017 Project Cost $8,400,000 Services Project Management Mechanical Engineering Plumbing Engineering Fire Protection Engineering Personal experience of Eduardo Escobar 27 Building G HVAC Upgrades Provided the construction documents for a HVAC replacement project to Building G at Pekin Community High School. The project included engineering design, design documents, permitting, estimate of probable construction cost, bidding, and part-time construction administration. Building G, constructed circa 1962, consists of roughly 90,000 square feet of education facilities including science laboratories, physics laboratories, classrooms, media room, administrative offices, and other educational space requiring exhaust systems. The engineering design included mechanical, electrical, plumbin, for replacement of HVAC systems. The project included demo of around 300 FAU's, 2 AHU's, ductwork, all the piping to the FAU's, walls, ACM flooring, lighting, concrete and footings. The new installation was creating 4 new mechanical rooms, each housing one Carrier AHU to supply mixed air temps out to around 96 new VAV's with reheat, all new piping to units and VAV's, 4 new condensing boilers, new walls, all new duct work throughout the building, and lighting changes. The air handling units are modular to accommodate installation in an existing crawlspace, which provides access for maintenance, without disturbing classroom activities. Size: 90,000 s.f. Cost: $5.21MM HVAC and Roof Replacement East Moline Correctional Center, East Moline, IL The Air Handling Units (AHU's) associated with Housing Units 3 & 4, the Chapel, Vocational Building and Education Building are all beyond their anticipated service life. The AHU's all are constant volume, single -zone or multi -zone with fixed amounts of outside air. For Housing Units 3 & 4, the OA amount appears to be insufficient, given the application, which has contributed to negative building pressure. All of the AHU's are experiencing maintenance issues due to age. The existing chiller units are absorption style units utilizing lithium bromide chemicals. Finding replacement parts required for normal maintenance has become a challenge and the chillers are experiencing numerous maintenance issues. The existing cooling towers are in an advanced state of dis-repair and decay. The campus boiler system is also beyond its useful life and has experienced boiler failure with repeated maintenance issues. In recent months, the softened water system feeding the water -tube boilers has been de -commissioned. The new HVAC systems for East Moline will include high efficiency chillers, refurbishment of the boiler make-up water system, replacement of AHU's and upgrade to system controls where applicable to provide more system reliability and energy efficient operation. Client East Moline Correctional Center/ Illinois Capital Development Board Completion 2023 Project Cost $7,100,000 Services Architecture Structural Engineering Mechanical Engineering Plumbing/Fire Protection Electrical Engineering VAL D El S Architecture & Engineering 29 HVAC and Roof Replacement East Moline Correctional Center, East Moline, IL The project also includes repair and/or replacement of several areas of the roof structure due to moist air in the attic space which has supported mold and mildew growth on the underside of the roof structure. Once the structure is repaired or replaced, the entire roof system on Housing Units 3 & 4 will also be replaced due to age and its advanced state of degradation. VAL D El S Architecture & Engineering 30 Mechanical/Electrical Renovation, ERF Clean Room University of Illinois at Chicago, Chicago, IL Completion 2019 Project Cost $2,700,000 Services Project Management Architecture Mechanical Engineering Plumbing Engineering Fire Protection Engineering Electrical Engineering The objective of the project was to upgrade the existing mechanical, electrical and plumbing infrastructure serving the clean room facility, correct deficiencies and meet the clean room performance requirements. The clean room staff were not able to control the environmental conditions, including temperature, humidity, and pressurization between rooms, in the clean room due to years of deferred maintenance . The design team performed a field survey of the existing clean rooms and mechanical/electrical spaces to learn about the existing systems and spoke with clean room staff to understand the challenges that they were facing. The design team designed new air handling systems, electrical systems and controls so that clean room staff were able to be aware of environmental conditions at all times, and so they had requisite control, and could subsequently certify their clean rooms. The clean rooms could not be out of service for construction activities for extended lengths of time, so through use of laser scanning which helped in determining components that could be pre -fabricated, and careful coordination and planning of the construction activities, the clean room shut down was reduced to a two week period after classes ended for the school year. The scope of work included the following: Clean Room Flooring The existing flooring system is a roll-on epoxy paint that has deteriorated and delaminated in several locations throughout the third -floor clean rooms. This project called for the removal of the existing epoxy, preparation of the Personal Experience of Steve Ejnik and Michael Shrader 31 concrete substrate, and installation of a new resinous flooring system. New flooring was installed under elevated casework and under movable equipment. Demolition Removal and replacement of AHU-7 and AHU-8, upgrade of AHU-5 and AHU-6, replacement of scrubber exhaust fan and motor, associated ducts, piping, chilled water pumps P-14 and P-15, chiller CH3, condensers, and other constituents. Chiller CH4 was demolished and not replaced. An alternate was prepared for the full removal and replacement of AHU-5 and AHU-6. HVAC system/components New HVAC units AHU-7 and AHU-8 were provided; exhaust scrubber was entirely replaced with new FRP scrubber and exhaust fan and new pumps and motors; all associated ducts, piping, insulation, and appurtenances were replaced with new. Chiller CH3 and chilled water pump P-14 and associated air-cooled condensers ACC- 3A & ACC -3B were replaced with new. New steam humidifiers, steam and condensate piping specialties were provided. All pneumatic controls were replaced with electric/electronic controls tied to a new central Building Automation System (BAS) with new workstations. All new pressure/temperature/humidity sensors and controls were provided. Piping insulation which was torn or disintegrated was replaced with new insulation. BAS installation included a comprehensive and complete direct digital controls/BAS system. Replacement of HEPA filters and space humidification/temperature sensors/control was provided including replacement of reheat coils and control valves. BAS was BACNet compatible. AHU-5 and AHU-6 centrifugal fans were replaced with fanwall systems with variable frequency drives for efficiency and diversity. Chilled water coils in AHU-5 and AHU-6 were replaced with new coils and new drain pans were provided. Size: 7,300 s.f. including mechanical Cost: $3.01MM 32 RTC] AHU Replacement Sauk Valley Community College, Dixon, IL The existing Air Handling Units (AHU's) are original to the building and are well past their anticipated service life. These units have experienced operational/reliability issues, are noisy to operate and have suffered capacity reductions due to coil fouling, damper failure, etc. All AHU's are constant volume and operate with generous amounts of outside air, in some cases double the current code requirements. The new units will be much quieter, will operate as single -zone or multi -zone VAV with supply air temperature reset and will modulate the outside air based on required code minimum quantities. Free -cooling economizer controls will be much more reliable and will control based on comparative enthalpy to maintain space humidity set points. The occupants will experience higher levels of indoor environmental quality and the College will save on their utility costs. The cooling tower at SVCC is also beyond its useful life and is experiencing decay. The new unit will be a more efficient design utilizing half the motor horsepower. Client Sauk Valley Community College / Illinois Capital Development Board Completion 2022 Project Cost $2,400,000 Services Mechanical Engineering Plumbing/Fire Protection Electrical Engineering VALDES 34 Architecture & Engineering AHU Replacement Sauk Valley Community College, Dixon, IL VALDES Architecture & Engineering 35 HVAC System Replacement/Upgrade Olon Ricerca Biosciences, Concord, OH The HVAC system serving this HPAPI lab is a 100% Outside Air, once -through Client system to avoid any possibility of potent compounds migrating to other spaces. All y handling of active HPAPI's occurs within an Isolator. The Process Air Handling Unit consists of a Heated, Intake Louver, Heat Recovery Coil, Chilled Water Coil, Supply wMalwo :�, 7 z P rnw" was sized for N+1 redundancy and are included on the Emergency Power u✓ riiivioe rr✓✓rrer✓air II project Cost terminal, electric reheat for tempering air temperature to each zone. The Supply $1,600,000 Air is then delivered to each space via 99.99% Terminal HEPA Filters with room - side access for media replacement, challenge testing and air balancing. Services Project Management Exhaust air is collected via low wall, HEPA filter inlets with MERV 8 Pre -filters. Filter Architecture access was designed such that media could be removed without disturbing any Mechanical Engineering particulates. Exhaust Air ductwork is then routed to a roof mounted, Heat Plumbing/Fire Protection Recovery Air Handling Unit which includes integral High Plume Lab Exhaust Electrical Engineering fans. The Exhaust Fans were sized for N+1 redundancy and are included on the Cost Estimating Emergency Power distribution panel. Both Supply Air and Exhaust Air quantities are measured with NIST Certified Airflow Monitoring Stations. All spaces have minimum air change rates are air balanced with specific pressure relationships in mind to maintain cleanliness and maintain the safest working environment possible. The HVAC system is a hard -balanced system. Each ISO 8 space is monitored for both temperature and humidity to ensure the environment remains within specified limits. The HVAC system serving this HPAPI lab is a 100% Outside Air, once -through Client system to avoid any possibility of potent compounds migrating to other spaces. All Olon Ricerca Biosciences handling of active HPAPI's occurs within an Isolator. The Process Air Handling Unit consists of a Heated, Intake Louver, Heat Recovery Coil, Chilled Water Coil, Supply Completion Plenum Fans, Natural Gas Heating Section and MERV 14 Final Filter. The Fan Array 2023 was sized for N+1 redundancy and are included on the Emergency Power distribution panel. Air is delivered to Constant Air Volume Terminal Units with project Cost terminal, electric reheat for tempering air temperature to each zone. The Supply $1,600,000 Air is then delivered to each space via 99.99% Terminal HEPA Filters with room - side access for media replacement, challenge testing and air balancing. Services Project Management Exhaust air is collected via low wall, HEPA filter inlets with MERV 8 Pre -filters. Filter Architecture access was designed such that media could be removed without disturbing any Mechanical Engineering particulates. Exhaust Air ductwork is then routed to a roof mounted, Heat Plumbing/Fire Protection Recovery Air Handling Unit which includes integral High Plume Lab Exhaust Electrical Engineering fans. The Exhaust Fans were sized for N+1 redundancy and are included on the Cost Estimating Emergency Power distribution panel. Both Supply Air and Exhaust Air quantities are measured with NIST Certified Airflow Monitoring Stations. All spaces have minimum air change rates are air balanced with specific pressure relationships in mind to maintain cleanliness and maintain the safest working environment possible. The HVAC system is a hard -balanced system. Each ISO 8 space is monitored for both temperature and humidity to ensure the environment remains within specified limits. The Heat Recovery Loop includes a circulation pump and three-way mixing valve to optimize transfer of sensible energy between the Heat Recovery Air Handling Unit and main Process Air Handling Unit via a 30% Propylene media. This closed loop also includes means for Air Separation and addition of chemical treatment. All chemicals are planned to be added manually to this system. VALDES 36 Architecture & Engineering HVAC System Replacement/Upgrade Concord OH The Process Air Handling Unit chilled water coil is served by a dedicated, modular Chiller which circulates 30% Propylene media. The chiller includes a fully redundant circuit for N+1 operation and is not included on the Emergency Power distribution panel as air movement and pressurization were more important than temperature remaining within set point limits in the event of power failure. The Chilled Glycol Loop also includes means for Air Separation, Expansion and addition of chemical treatment with permanent fill valve for system start-up. All chemicals are planned to be added manually to this system. All systems were sized to accommodate Phase 1 and Phase 2 of this project, so special care was taken to maintain minimum coil face velocities, stable fan operation, etc. With system reliability being a project critical success factor, equipment was selected to maintain the most stable and reliable operation possible. Each phase of the project will include both Enhanced HVAC Commissioning and system validation for compliance with the facility's Environmental Monitoring System requirements. Both the Phase 1 and Phase 2 Suites will be Validated to meet FDA requirements associated with Aseptic cGMP manufacturing and SafeBridge manufacturing. VALDES Architecture & Engineering 37 MCC HVAC Replacements Cargill, Hammond, IN This project involved installation of new and/or modification of HVAC systems in six separate existing MCC rooms across the Cargill's plant. MCC HVAC system upgrades were needed to provide effective cool air distribution throughout the spaces and comply with Cargill's AEI standard. The projects were completed in two phases of three buildings each. Each space consisted of a single or multiple water-cooled HVAC units serving the main area as well as adjacent spaces and these existing HVAC units had reached end of life and required replacement. New water-cooled units were an option, but if water supply was lost, conditioning would also be lost. Therefore, air cooled units on the roof was the preferred and selected option. Scope of Work Mechanical - Perform heat load calculations for each room. - Size HVAC units with additional capacity. - Design supply and return ductwork. - Prepare Basis of Design Package. - Prepare Scope of Work Package (SOW). - Prepare HVAC General Arrangement (GA) drawing. Structural - Calculate roof loads for new HVAC units. - Verify existing roof structure for loads. - Supplement construction SOW with structural modifications, as required. Client Cargill Completion 2021 Project Cost $3,000,000 Services Project Management Architecture Mechanical Engineering Plumbing/Fire Protection Electrical Engineering Cost Estimating VALDES 38 Architecture & Engineering MCC HVAC Replacements Cargill, Hammond, IN Electrical - Update single -line drawing for the HVAC systems. - Update MCC elevation drawing per identified changes. - Supplement construction SOW with electrical modifications section. Laser Scanning 3D Laser scan of each area. Register scans and create Navisworks files for use in design coordination. VALDES Architecture & Engineering 39 HVAC Replacements Ingredion, Bedford Park, IL The Ingredion Argo Plant, located in Bedford Park, Illinois sought to evaluate Client several locations throughout the plant for HVAC replacement / upgrades. Existing Ingredion HVAC equipment serving these areas was in poor operating condition due to age and corrosion. Maintenance requirements for the existing equipment became very Completion costly and temporary equipment is repeatedly being rented to supply cooling. 2016 Several design options were presented which included the complete retrofit of Project Cost existing equipment or alternative piecemeal designs to improve efficiency. $4,400,000 Valdes performed the following tasks: Services - Perform heat load calculations using Trace 700 software for all areas. Project Management - Evaluation of existing HVAC equipment. Mechanical Engineering - Generate new HVAC design options: New HVAC designs were based upon Plumbing/Fire Protection Ingredion plant operating conditions and industry design practices and was Electrical Engineering presented as two options where applicable: Cost Estimating Option A included the combination of cooling equipment into a new plant chiller system. This option would use a high efficiency chiller powered by 150 psig steam. The new chiller would be centrally located within the plant at a location to be determined later. Purafil air filtration, updated system control and protective 1-12S and SO2 resistant equipment coating were included. Steam and/or electric heat was proposed to be used. VALDES 40 Architecture & Engineering MCC HVAC Replacements Cargill, Hammond, IN Option B would replace the existing equipment with similarly designed systems. This option utilized high efficiency equipment and included filtration, control and protective coating upgrades. Steam and/or electric heating was proposed to be used. - Size New Equipment: Trane Inc. HVAC equipment (Ingredion preferred manufacturer) was selected for E -Rooms, Offices, Control Room and Lab designs. Liebert brand equipment was selected for Computer Room and Analog Room 12 . New equipment was sized to handle the cooling and heating load requirements and meet the proposed new designs. - New equipment was selected based upon Valdes supplied heating and cooling loads. - Valdes developed budgetary cost estimates for the replacement of HVAC equipment. Estimates were based upon vendor supplied pricing and Valdes experience. VALDES Architecture & Engineering 41 Request for Proposals Village Hall HVAC Unit Replacements Village of Mount Prospect IPir cess Descirlipfloin PROJECT UNDERSTANDING The Village Hall was built in 2003 and is served by five Carrier roof top units (RTUs) that provide heating, cooling, and air conditioning to each floor of the Village Hall, including a Board Boom. Three of the RTUs, which serve the 1st, 2nd, and 3rd floors, were installed on the roof of the south building in a mechanical platform area. The mechanical platform area is set down in an eight -foot -deep pit, surrounded by solid walls on all four sides. The dimensions of the pit are approximately 75' x 19'. The walls surrounding the RTUs in this small, rooftop area prevent heat from the RTU cooling condensers from escaping the pit. This heat, combined with the heat from the sun absorbed by the black roof material, causes the pit area to get very hot. Per discussion with the building engineers, temperatures in the mechanical platform area can reach 115-120 deg F. These high temperatures have caused premature HVAC failures during the cooling season because of unit overheating. The RTUs in the north platform area, while not as hot as the south platform area since that are is open on the north side, still struggles to meet the required load due to hot roof temperatures there as well. PROJECT OBJECTIVES The project objectives include replacement of the existing 19 -year-old rooftop HVAC equipment which has reached the end of its service life, is under -performing, and is not meeting the needs of the building. More specifically, the new units must be able to perform well in the existing location or an alternative needs to be generated. A second objective is to update the building's BAS system to a new non-proprietary system to serve the new HVAC rooftop equipment and 55 interior VAV boxes. PROJ ECT APPROACH To resolve the rooftop unit (RTU) overheating issue, Burns & McDonnell advanced three potential solution options in their report dated 07/14/2022, including: • Replacement of the RTUs in the same locations with oversized RTUs capable of handling higher ambient temperatures. • Replacement of the RTUs with new units having chilled water coils and installation of an accompanying air-cooled chiller on the roof of the adjacent parking garage. • Replacement of the RTUs on the south mechanical platform with units having remote air-cooled condensing units, mounted on the roof of the adjacent parking garage. The RTUs in the north mechanical platform would be replaced with oversized RTUs capable of handling higher ambient temperatures. The B&M report goes on to say that their recommended factors for consideration in the evaluation of each of the three options includes RTU heat rejection, available power for the proposed HVAC equipment, structural capacity of the parking garage and Village Hall roof, and noise generated by the proposed HVAC equipment. The B&M recommended option was Option #1, which utilized the existing rooftop locations and curbs but increased their size to accommodate the higher-than-expected ambient air conditions around the equipment. Valdes' Approach from Here Though Valdes has already reviewed the Burns & McDonnell document, we will spend additional time to understand it in further detail. We also will want to gather additional information from the site and from maintenance personnel to get a complete understanding of the HVAC systems and the issues that the Village has been experiencing. Essentially, the approach will consist of the following steps: Discovery, Analysis and Design to be followed by the Bidding Phase and the Construction Phase. The Discovery Phase of the project will begin with a review of existing conditions. This includes visiting the site, interviewing staff, and reviewing as -built documents to understand the problems and concerns with the existing HVAC system. VAIADI�".'S Ar.lhitKlUre P.and Dngineeing> El 191 IPir c ss Descirlipfloin Once we understand the current issues in detail, Valdes will begin our analysis on the building and relevant factors that potentially could affect the proposed design solution. This analysis includes validating equipment sizing based on block load calculations, reviewing building structure for adequacy, and verifying electrical demands. As part of the analysis phase, Valdes will review the constructability of the recommended option, option 1, including working with equipment manufactures to verify that all clearances can be maintained to meet performance and equipment requirements. If the proposed solution does not meet the necessary requirements, Valdes will collaborate with Village staff to present alternatives to address potential clearance issues. The design phase will build upon the consensus solution by generating requisite drawings, details, and schedules to describe the desired solution and ultimately deliver a set of design documents suitable for permit and bidding. In the Bidding Phase, Valdes will support the efforts of the Village in contacting contractors to bid, reviewing received bids, helping the Village to validate those bids by reviewing submitted documentation and/or by way of bid reviews with the contractors. On a parallel track, Valdes will be working with the Village of Mount Prospect Building Department to address permit set comments and provide required documentation to obtain a building permit. When the Village has selected a contractor and construction commences, Valdes will further support the Village by: • Attending a pre -construction meeting • Review shop drawings/submittals • Address contractor RFIs • Provide clarifying sketches for the contractor • Review pay requests • Review change order requests • Attend construction meetings • Make site visits to observe construction progress • Prepare one punch list of items for the contractor to complete • Make one site visit to verify punch list completion Finally, a construction close-out package will be prepared and delivered to the Village of Mount Prospect. Project Management Projects at Valdes Architecture and Engineering (Valdes) follow a standardized, easily repeatable set of project execution procedures that support consistency and quality for every project, every time, whether it's a large project or a small study. WORK PLAN A key document in the project execution procedure is the project work plan. The project work plan sets the tone and direction for our projects, but it also acts as a communication tool to assist in keeping the project team on track, regarding scope, schedule, and budget. The project manager drives the generation of the work plan, but the design team is called upon to add content and make it their own. Once the plan is final, it will be the road map for getting from the beginning of the project to the end, including through construction. Valdes' Project Manager will be the primary project contact overseeing and coordinating all technical project activities. Spending enough time and effort at the identification of the scope of services and drafting a corresponding work plan to provide those services is, in our opinion, the only legitimate way to understand the effort required. The creation of a work plan, however, is only the beginning. As the project progresses and challenges ebb and flow, the work plan needs to be re -visited regularly by the PM and team members to re -confirm that deployed resources are on track or VAIADI�".'S Ar.lhitr.:r':lUre P.and Dngineeing> 44 IPir c ss Descirlipfloin not. Early identification of potential project issues is a key approach to minimizing project disruption. If an adjustment plan becomes necessary, this early identification will be a key to success in staying within the budgeted fee dollars and/or schedule. Valdes believes flexibility and creativity is required throughout the project execution process. Other components of the project work plan include the following: • Schedule Evaluation: development, evaluation, and adjustments to the project design, schedule, and budget where appropriate. • Cost Estimating: A cost estimate will be developed at key completion points. The estimate shall be approved by the Village and sets the benchmark as the design is finalized for bidding and construction. Changes to the documents will be evaluated to ensure that the project is staying on track in terms of the approved budget. If required, changes can be made to project scope, systems, and/or detailing to keep the project within budget. • Basis of Design Document: Development of a report that outlines the general design criteria to be used for the project. For example, applicable building codes, general room requirements, equipment listings, environmental conditions of a room, fire suppression requirements, light fixture types, etc. The document is used to support iterative discussion with users and to ensure buy -in by all users, that they understood and were involved in the decision-making process, and the upon move -in, the project meets their expectations. • Action Item List: Development of a live list of required actions that identifies what needs to be delivered, by whom, and by when, to keep the project on schedule. MEETINGS A kickoff meeting will be held internally with the project team to organize our activities including development of a project needs lists and gaining an understanding of the overall project scope, schedule, and budget. We will also hold a kick-off meeting with Village stakeholders. During the kick-off with Village staff, the primary Village contact will be identified and will serve as Valdes' contact for all project decisions. We will also discuss and identify communication channels, review the scope of work, confirm construction budget (if applicable), and confirm schedule and upcoming, immediate needs. We will also want to discuss the driving factors for the project, so that the Valdes team has a thorough understanding of the Village's needs and concerns. Project meetings may utilize electronic, internet-based solutions or on-site meetings as appropriate. CONSTRUCTION COST ESTIMATING The Concord Group was founded in 1996 and has provided professional cost estimating services for over 25 years to municipalities, governmental agencies, higher education institutions, healthcare organizations, and other institutional clients on high profile, complex projects. During this time, Concord's staff has grown to more than 40 professionals with expertise in construction cost estimating, project management and real estate advisory services. All of Concord's estimates are prepared "in-house" by their knowledgeable and experienced staff of cost estimators, engineers, quantity surveyors and project managers, who can help clients manage their construction costs. Concord provides cost estimates at all design stages and for all construction disciplines including architectural, structural, civil, mechanical, electrical, and plumbing. They work with the "state-of-the-art" technologies for project measurement and pricing along with the latest in Building Information Management (BIM) applications. Their process is collaborative in that they work closely with the design team to make sure that they understand design intent, as well as client goals. Working with the design team we can then provide realistic cost estimates that ultimately provide the client with the confidence needed to move forward with a project. VAIADI�".'S Arc.lhitr.:r':lUre P.and Dngineeing> 45 IPir c ss Il s iriilptii in Concord provides cost estimating services on approximately $3 Billion worth of construction projects on an annual basis and due to their relationship with several significant local institutional and governmental clients, we see many bids on a weekly basis. This very substantial volume of cost data provides Concord with "real time" information about the state of pricing in the local construction market. Their comprehensive database of construction cost information provides them with a basis for the financial control of our clients' projects. They create a total project budget from a project's conceptual parameters. They monitor compliance with the approved budget throughout the entire design and construction phases. During planning and design, they use their cost estimating expertise at appropriate milestones to confirm compliance with the targeted construction budget. Through change order evaluation and analysis, Concord maintains cost control from bid award through construction completion. HOURS PROJECTION PROJECT SCHEDULE A proposed project schedule is attached to this response. This schedule is a tentative, first cut draft. It does meet the timeline represented in the RFP, but we'd like to discuss with Village staff before we finalize. VAIADI--�".'S Arc.lhitKlUre P.and Dngineeing El D", Hours Design Project Manager 40 Mechanical Engineer 252 Electrical Engineer 120 Structural Engineer 16 Bidding/Permitting Project Manager 24 Mechanical Engineer 24 Electrical Engineer 16 Structural Engineer 0 Construction Administration Project Manager 36 Mechanical Engineer 120 Electrical Engineer 40 Structural Engineer 8 PROJECT SCHEDULE A proposed project schedule is attached to this response. This schedule is a tentative, first cut draft. It does meet the timeline represented in the RFP, but we'd like to discuss with Village staff before we finalize. VAIADI--�".'S Arc.lhitKlUre P.and Dngineeing El D", Request for Proposals Village Hall HVAC Unit Replacements Village of Mount Prospect IFe ASSUMPTIONS/CLARIFICATIONS 1. Valdes Deliverables will be in 2D PDF format. 2. This proposal does not include any permit fees. 3. Valdes assumes that the existing structure is adequate to support the new air handling units (as described in Option #1 of Burns & McDonnell Village Hall HVAC Study). Valdes will provide a structural review of the existing structure (Valdes has included 16 hours for the structural investigation) to make judgments about its structural strength to support the chosen AHU replacement solution. However, if any structural modifications are required to structurally support the chosen solution, Valdes will provide a proposal to the Village of Mount Prospect for structural engineering design services. 4. Floor plans in AutoCAD format and original construction drawings (if available) will be made available to Valdes. 5. Valdes assumes that required electrical engineering services will only include re -connection of electrical service to the new AHUs and existing power supply is adequate to serve the new AHUs. No electrical upgrades are necessary or included in this proposal. 6. No architecture services are necessary or included in this proposal. 7. No civil engineering services (site design) are included. FEE We propose to provide the professional services described herein for the Lump Sum amount of $79,300 invoiced on a monthly, percent complete basis and in accordance with mutually agreeable terms and conditions. Expenses are included in the lump sum fee. VAIADI--�".'S Arc.lhitKlUre P.and Dngineeing s s a a 'a r ii. uL" O O � - V n `F' V m u t Oil c d % W c " G , Z � m m —➢MG m m # BIW _ _ r r, Cn m LL W c n 0 � m � S . s E F � _ E 6 M m i m rn rn E m ry m m v v � y Valdes staff, Steve Ejnik and Michael Shrader have worked with public clients similar to the Village of Mount Prospect over their 30+ year history in the architecture and engineering industry. Projects have included a variety of municipal buildings including fire stations, public works facilities, village halls and vehicle maintenance facilities. A list of some of those projects are noted below: Lake County Permit Facility Libertyville, IL Shorewood Village Hall Shorewood, IL Shorewood Public Works Facility Shorewood, IL (Programming & Conceptual Design) Plainfield Village Hall Plainfield, IL Plainfield Public Works Plainfield, IL Village Hall Renovations Oak Brook, IL (Programming & Conceptual Design) Satellite Fire Station Bannockburn, IL Central Fire Station Deerfield, IL i � rw foi Public Works Facility Niles, IL Public Works Facility Naperville, IL (Programming & F/a/eM, Conceptual Design) Public Works Facility Park Ridge, IL (Programming & Conceptual Design) Public Works Facility Skokie, IL Public Works Facility Vernon Hills, IL 50 Public Works Facility Lake Zurich, IL Public Works Facility Downers Grove, IL Police Department Renovation Shorewood, IL Public Works Facility Orland Park, IL 51 U @ t JJFK�, N ai 51 11 Village Hall HVAC Study Village of Mount Prospect Village Hall HVAC Study Project No. 144766 Revision: Final 7/14/2022 52 Village Hall HVAC Study prepared for Village of Mount Prospect Village Hall HVAC Study Mount Prospect, Illinois Project No. 144766 Revision: Final 7/14/2022 prepared by Burns & McDonnell Engineering Company, Inc. Downers Grove, Illinois COPYRIGHT © 2022 BURNS & McDONNELL ENGINEERING COMPANY, INC. 53 Villaqe Hall HVAC Study Revision: Final Table of Contents TABLE OF CONTENTS Page No. 1.0 INTRODUCTION...............................................................................................1-1 1.1 Purpose.................................................................................................................1-1 1.2 Scope....................................................................................................................1-1 2.0 BACKGROUND INFORMATION......................................................................2-1 2.1 Existing Conditions.............................................................................................. 2-1 2.2 Village Sound Limits........................................................................................... 2-2 3.0 EXISTING CONDITIONS EVALUATION..........................................................3-1 3.1 Existing Rooftop Units........................................................................................ 3-1 3.2 VAV's and controls............................................................................................. 3-3 3.3 HVAC Related Electrical System........................................................................ 3-3 3.4 Adjacent Parking Garage..................................................................................... 3-3 4.0 EVALUATION OF OPTIONS AND RECOMMENDATIONS.............................4-4 4.1 Option 1 — New Dx RTUs Rated for Higher Ambient Temperature ................... 4-4 4.1.1 Mechanical Evaluation.......................................................................... 4-4 4.1.2 Electrical Evaluation............................................................................. 4-5 4.1.3 Structural Evaluation............................................................................ 4-5 4.1.4 Sound Evaluation.................................................................................. 4-5 4.2 Option 2 — New CHW RTUs and Remote Chiller ............................................... 4-6 4.2.1 Mechanical Evaluation.......................................................................... 4-7 4.2.2 Electrical Evaluation............................................................................. 4-7 4.2.3 Structural Evaluation............................................................................ 4-7 4.2.4 Sound Evaluation.................................................................................. 4-8 4.3 Option 3 — New Dx RTUs with Remote Condensing Units ................................ 4-9 4.3.1 Mechanical Evaluation........................................................................ 4-10 4.3.2 Electrical Evaluation........................................................................... 4-10 4.3.3 Structural Evaluation.......................................................................... 4-11 4.3.4 Sound Evaluation................................................................................ 4-11 4.4 Engineers Opinion of Probable Construction Costs .......................................... 4-12 4.5 Summary............................................................................................................ 4-12 4.6 Recommendation ............................................................................................... 4-15 APPENDIX A — PRELIMINARY SKETCHES APPENDIX B — ENGINEER'S OPPINION OF PROBABLE CONSTRUCTION COST APPENDIX C — PRELIMINARY EQUIPMENT CUT SHEETS Village of Mount Prospect TOC -1 Burns & McDonnell 54 Villaqe Hall HVAC Stu Revision: Final LIST OF TABLES Table of Contents Page No. Table 2-1: Village Sound Level Limits for Limited Industrial District ................................... 2-2 Table 3-1: Existing Rooftop Unit Nameplate Information...................................................... 3-1 Table 3-2: Existing Rooftop Unit Data.................................................................................... 3-1 Table 4-1: Option 1 Equipment Data....................................................................................... 4-4 Table 4-2: Option 2 Equipment Data....................................................................................... 4-6 Table 4-3: Sound Pressure Levels at Residential Receivers for Option 2 ............................... 4-8 Table 4-4: Option 3 Equipment Data....................................................................................... 4-9 Table 4-5: Sound Pressure Levels at Residential Receivers for Option 3 ............................. 4-12 Table 4-5: Engineer's Opinion of Probable Construction Cost ............................................. 4-12 Village of Mount Prospect TOC -2 Burns & McDonnell 55 Villaqe Hall HVAC Study Revision: Final Table of Contents LIST OF EXHIBITS Exhibit 1: SK -1 — Option 1 HVAC Equipment Plan Exhibit 2: SK -2 — Option 2 HVAC Equipment Plan Exhibit 3: SK -3 — Option 3 HVAC Equipment Plan Exhibit 4: SK -4 — Site Satellite View Village of Mount Prospect TOC -3 Burns & McDonnell W CSB -01 Flood Studv Revision: Final LIST OF ABBREVIATIONS Abbreviation Term/Phrase/Name Village Village of Mount Prospect Burns & McDonnell Burns & McDonnell Engineering Company, Inc. AHU Air Handling Unit BAS Building Automation System CH Chiller CHW Chilled Water Cu Condensing Unit Dx Direct Expansion Refrigeration RTU Rooftop Unit VAV Variable Air Volume List of Abbreviations Village of Mount Prospect i Burns & McDonnell 57 CSB -01 Flood Study Revision: Final Introduction 1.0 INTRODUCTION 1.1 Purpose The Village of Mount Prospect's (Village) Village Hall is currently heated, cooled, and ventilated by five (5) underperforming, 19 -year old rooftop air conditioning units (RTUs) that are in need of upgrade and replacement. The Village has requested Burns & McDonnell to evaluate options to determine a path forward for replacing the existing rooftop units (RTUs). 1.2 Scope The scope of this study includes the following: 1. Meet with the Village to review the project goals, objectives, and HVAC system requirements. 2. Survey existing area around rooftop units and proposed remote equipment, and review existing building drawings provided by the Village. 3. Prepare and submit a draft report presenting three (3) options for RTU replacement. RTU replacement options to consider unit heat rejection, power requirements of proposed HVAC equipment and available power, unit weights and structural capacity of existing buildings, and unit noise and estimated impact to surrounding area. Report to include an estimated design fee and an order of magnitude construction cost estimate for each of the three options. 4. Review the draft report with the Village, incorporate appropriate Village comments, provide a recommendation, and submit a final report to the Village. Village of Mount Prospect 1-1 Burns & McDonnell Village Hall HVAC 2.0 2.1 Existing Conditions Revision: Final BACKGROUND INFORMATION nd Information The Village Hall was built in 2003 and is served by five (5) Carrier roof top units (RTUs) that provide heating, cooling, and air conditioning to each floor of the Village Hall, including a Board Boom. Three (3) of the RTUs, which serve the 1", 2nd, and 3' floors, were installed on the roof of the south building, in a mechanical platform area. The mechanical platform area is set down in an eight foot (8') deep pit, surrounded by solid walls on all four sides; the dimensions of the pit are approximately 75' x 19'. The walls surrounding the RTUs in this small, rooftop area prevent heat from the RTU cooling condensers from escaping the pit. This heat from the RTUs, combined with the heat from the sun absorbed by the black roof material, causes the pit area to get very hot; per discussions with building engineers, temperatures in the mechanical platform area can reach 115-120 deg F. These high temperatures have caused premature HVAC failures during the cooling season because of the units overheating. The RTUs in the north platform area, while not as hot as the south platform area since it is open on the north side, still struggle to meet load due to hot roof temperatures. To resolve this RTU overheating issue, several options were discussed at the walk-through with the Village, including: • Replacement of the RTUs in the same locations with oversized RTUs capable of handling higher ambient temperatures, • Replacing the RTUs with new units having chilled water coils and installing an accompanying air-cooled chiller on the roof of the adjacent parking garage, and • Replacing the RTUs in the south mechanical platform with units having remote air-cooled condensing units, mounted on the roof of the adjacent parging garage. The RTUs in the north mechanical platform to be replaced with oversized RTUs capable of handling higher ambient temperatures. Factors to be considered in the evaluation of each of the three (3) options are to include RTU heat rejection, available power for the proposed HVAC equipment, structural capacity of the parking garage and Village Hall roof, and noise generated by the proposed HVAC equipment. Village of Mount Prospect 2-1 Burns & McDonnell Village Hall HVAC Revision: Final Background Information In addition to the replacement of the RTUs, the Village would like to replace the roof in each of the two (2) RTU areas with a white membrane roof and replace the controls for the five (5) RTUs and associated fifty-five (55) variable air volume (VAV) boxes. It is expected that the unit replacements will need to be phased, to allow Village Hall to remain occupied. 2.2 Village Sound Limits The Village does not have a sound limit for properties within the Core Central Commercial District (Zone B -5C) where the Village Hall and surrounding properties are located. The Village does limit sound levels for Limited Industrial Districts (Zone I-1) impacting residential or business zoning districts. The daytime and nighttime limits are provided by frequency band and are applicable at the receiving property line. For this analysis the impacts at nearby residential receivers will be compared to the limits for Limited Industrial Zones. The limits are summarized in Table 2-1. Table 2-1: Village Sound Level Limits for Limited Industrial District Octave Band Center Frequency (Hertz) Daytime (8:00 am to 10:00 pm) Sound Level (dB) Nighttime (10:00 pm to 8:00 am) Sound Level (dB) 31.5 72 67 63 67 66 125 66 65 250 59 52 500 52 46 1,000 46 40 2,000 40 35 4,000 38 35 8,000 38 32 Above 8,000 1 38 1 32 Source: Section 14.2104 of the Village Code of Mount Prospect, Illinois Village of Mount Prospect 2-2 Burns & McDonnell 60 Village Hall HVAC Revision: Final Existing Conditions Evaluation 3.0 EXISTING CONDITIONS EVALUATION 3.1 Existing Rooftop Units There are five (5) existing rooftop units serving the Village Hall. Three (3) are located in the center of the south side building, in a depressed pit area at the peak of the roof, the tags for these units are RTU -1, RTU -2, and RTU -3. Two (2) are located at the north end of the building, adjacent to the parking structure; the tags for these units are RTU -4 and RTU -B. Table 3-1 and Table 3-2 below include pertinent data for the existing RTUs. Table 3-1: Existing Rooftop Unit Nameplate Information Tag Manufacturer Model Number Serial Number Nominal Capacity (Tons) Date Manufactured RTU -1 Carrier 48AKD035-FQ611HH 5003F68977 35 2003 RTU -2 Carrier 48AKD027-EQ611HH 5003F68981 27 2003 RTU -3 Carrier 48AKD020-DQ611HH 5003F68976 20 2003 RTU -4 Carrier 48AKD025-DQ611HH 5003F68978 25 2003 RTU -13 Carrier 48AKD025-DQ611HH 5003F68980 25 2003 Table 3-2: Existing Rooftop Unit Data Tag Unit Configuration Cooling Type Nominal Capacity (tons) Actual Capacity (MBH) Design Ambient (deg F)* Electrical MCA Weight (lbs.) RTU -1 Packaged Dx 35 431 95 115 5434 RTU -2 Packaged Dx 27 331 95 96 4993 RTU -3 Packaged Dx 20 248 95 78 4697 RTU -4 Packaged Dx 25 290 95 86 4770 RTU -13 Packaged Dx 25 302 95 86 4770 • Design Ambient is equivalent to maximum outdoor air temperature assumed for RTU selection. All RTUs are original to the building and struggle to maintain space cooling in the summer, due to the elevated temperature of the rooftop locations. Three of the existing RTUs (RTU -1, RTU -2, and RTU -3) are located in the center of the south side building, in a mechanical platfonn at the peak of the roof, that is depressed 8 feet below the surrounding roof, creating a pit area (see photos below). The roof membrane in this area is black, thereby absorbing Village of Mount Prospect 3-1 Burns & McDonnell 61 Village Hall HVAC Revision: Final Existing Conditions Evaluation heat from the sun. According to the building engineer, the temperature of the area frequently reaches 115-120 deg F. The other two units (RTU -4 and RTU -B) are located on the north side of the building, in a mechanical platform built into the side of the sloped roof, which is partially closed on three sides, and mostly open to the north (see photos below). Although these units do not have the severity of the problems experienced by the south units, they too see elevated rooftop temperatures and are at the end of their expected service life. South Platform Photos North Platform Photos Village of Mount Prospect 3-2 Burns & McDonnell 62 Villaqe Hall HVAC Revision: Final Existinq Conditions Evaluation 3.2 VAV's and controls Per discussions with the building engineer, the existing VAV box controls are in need of replacement. Additionally, the existing building automation system is obsolete and proprietary. The Village seeks replace the VAV box controls and to have the control system replaced with a new, non-proprietary control system to serve the new RTUs, VAV boxes, and supplemental cooling equipment (depending on which RTU replacement option is implemented). 3.3 HVAC Related Electrical System The electrical distribution for the HVAC system is connected to a 480 VAC 800A GE Spectra Series Panelboard labeled EMDP2, located in the Lower Level Switchgear Room (L120). This panelboard is sub fed from the main switchboard (SWPB1) by an 800A breaker through the normal connection of a transfer switch. The emergency power source for this system is a 500 KW CAT generator connected through a 600A breaker; this breaker size must be verified during detailed engineering. As constructed, nameplate power requirements for the five affected RTUs is 461A. The existing GE Spectra Series breakers are currently discontinued and ABB's TMax breakers are a replacement solution with the correctly applied retrofit kits. The panel has 3X and 4X double wide spaces available as well as one single wide 3X space. Retrofit breakers are available up to 400A that fit in single wide 4X spaces. Single wide 3X spaces can accommodate up to 250A. It is unknown if replacement trip units are available new for the existing breakers. 3.4 Adjacent Parking Garage Adjacent to the Village Hall is an existing Village Parking Garage. The top level of the parking garage abuts the north edge of the Village Hall, and the deck elevation is approximately 10' below the level of the mechanical platforin serving the north RTUs. This location makes the top level of the parking garage very accessible from the north side of the Village Hall, and to the north RTUs. Village of Mount Prospect 3-3 Burns & McDonnell 63 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.0 EVALUATION OF OPTIONS AND RECOMMENDATIONS 4.1 Option 1 — New Dx RTUs Rated for Higher Ambient Temperature Replace the existing five (5) packaged RTUs with new packaged Dx RTUs of similar style, however sized for a higher ambient temperature to compensate for the expected roof temperatures. Preliminary equipment performance is listed in Table 4-1 below. Table 4-1: Option 1 Equipment Data Tag Unit Configuration Cooling Type Nominal Capacity (tons) Actual Capacity (MBH) Design Ambient (deg F) Electrical MCA Weight (lbs.) RTU -1 Packaged Dx 50 469 115 132 5700 RTU -2 Packaged Dx 35 369 115 104 5400 RTU -3 Packaged Dx 25 1 266 115 84 4900 RTU -4 Packaged Dx 30 308 105 90 5000 RTU -13 Packaged Dx 30 319 105 90 5000 • RTU data based on Carrier 48 Series rooftop units. The new RTUs will be located in the same rooftop mechanical platfonn locations as the existing, slightly shifting if necessary to meet manufacturer's recommended clearances. In conjunction with the RTU replacement, the existing roof will be replaced in each of the two mechanical platform areas. The new roof will be a white membrane roof, thereby reducing the heat in the pit area. White membrane roofs, when compared to black colored roofs (existing), can reduce surface temperature of the roof by 40 deg F or more. During the RTU replacement, the existing building VAV box controls will be replaced, as well as the building automation system (BAS) for control of the new RTUs and new VAV box controllers. 4.1.1 Mechanical Evaluation The new RTUs located in the south mechanical platform will be sized for an ambient temperature of 115 deg F, and the new RTUs located in the north mechanical platform will be sized for an ambient temperature of 105 deg F. Ambient temperatures listed above to be the basis for both the condenser selection and the temperature of the outside air intake. During extreme conditions, new RTUs must be capable of operating in an environment having a surrounding temperature of 120 deg F. Village of Mount Prospect 4-4 Burns & McDonnell 64 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations The new RTUs will be furnished with variable speed supply fans, Dx cooling coils, gas furnaces, filters, air side economizers, packaged controls, and new roof curbs with sufficient height (minimum 18" high) to raise the top of the south RTUs to 6" above the adjacent roof peak, thereby discharging condenser fan heat away from the mechanical platform area. Numerous manufacturers were evaluated (Carrier, Dakin, Trane), however only the Carrier units would reasonably fit into the existing platform area; the other manufacturers were too long or too heavy. During detailed engineering, additional manufacturers can be investigated. Additionally, the Carrier units offer the advantage of matching the existing configuration of the existing Carrier RTUs, thereby saving costs on potential re -ducting of the supply and return ducts through the roof, any other unit would require a transition curb, to match the existing duct connection locations with the RTU duct connection locations. During the RTU replacement, the existing building VAV box controllers and temperature sensors will be replaced, as well as the building automation system (BAS) for control of the new RTUs and VAV boxes. 4.1.2 Electrical Evaluation Total system MCA of the proposed Option 1 equipment is 500A, exceeding the existing system power requirements (461A). Existing RTU breakers and conduit may be reused with the exception of the feed to RTU -1; this feed requires a 150A breaker, and the conduit and feeder need to be upsized to accommodate higher than standard ambient temperatures. The RTU -1 breaker will have to be swapped for a new breaker in the same space as the existing breaker. Due to the increased equipment MCA, it is recommended that the HVAC system be limited while running off generator power. This can be done via the proposed new BAS. 4.1.3 Structural Evaluation Based on RISA modeling of the existing steel in the area of the RTU mechanical platforms, the maximum allowed RTU weight is 6,100 lbs. New RTU equipment weight must be below this limit, or structural modifications will be required. The Carrier RTUs proposed in this report are within this weight limit. Additionally, any modification to the size of the roof curbs will require new steel framing of the roof area below the RTUs. 4.1.4 Sound Evaluation Sound evaluation of the RTUs was not performed; and will be part of detailed engineering. Typically, standard rooftop units will meet area sound ordinance requirements. Village of Mount Prospect 4-5 Burns & McDonnell 65 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.2 Option 2 — New CHW RTUs and Remote Chiller Replace the existing five (5) packaged RTUs (which have cooling condensers attached to unit) with new chilled water (CHW) type RTUs (which have chilled water cooling coils and do not have attached cooling condensers), and provide a remote chiller. Preliminary equipment performance is listed in Table 4-2 below. This option moves the cooling condensers out of the pit area, so that there is no heat generated by the RTUs in the mechanical platform areas. Preliminary equipment performance is listed in Table 4-2 below. Table 4-2: Option 2 Equipment Data Tag Unit Configuration Cooling Type Nominal Capacity (tons) Actual Capacity (MBH) Design Ambient (deg F) Electrical MCA Weight (lbs.) RTU -1 Packaged CHW 40 469 105 38 5800 RTU -2 Packaged CHW 30 369 105 38 5400 RTU -3 Packaged CHW 20 1 266 105 31 4100 RTU -4 Packaged CHW 27 308 105 20 4100 RTU -13 Packaged CHW 27 319 105 25 5000 Chiller Air -Cooled CHW 160 1,731 95 1 348 11,000 RTU data based on Trane Model CSAA rooftop units. Chiller data based on Trane Model ACSA. The new RTUs will be located in the same rooftop mechanical platfonn locations as the existing (however, no cooling condensers are located on the roof). The chiller will be located on the top level of the adjacent parking garage. It will occupy the four (4) parking spots to the north of the existing handicapped parking spot (parking spot numbers 901-904). Power for the new chiller will be fed from spare breakers in the Village Hall. The new chiller will be supported and leveled by a steel frame or a new concrete pad, although new concrete pad will add significant weight; see structural evaluation below. Pipe bollards and a security fence will be provided around the new chiller for protection. In conjunction with the RTU replacement, the existing roof will be replaced in each of the two mechanical platform areas. The new roof will be a white membrane roof, thereby reducing the heat in the pit area. White membrane roofs, when compared to black colored roofs (existing), can reduce surface temperature of the roof by 40 deg F or more. During the RTU replacement, the existing building VAV box controls will be replaced, as well as the building automation system for control of the new RTUs and new VAV box controllers. Village of Mount Prospect 4-6 Burns & McDonnell Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.2.1 Mechanical Evaluation The new RTUs will be furnished with variable speed supply fans, chilled water coils, gas furnaces, filters, air side economizers, packaged controls, and roof curb adapters to transition supply/return air connections on new RTUs to the existing roof penetrations. The curb adapters will be approximately 48" high and will raise the top of the RTUs to approximately 24" above the existing roof edge. Additionally, preliminary equipment selections of the RTUs with chilled water coils from multiple manufacturer's indicate that the footprint of the RTUs is somewhat larger than the existing units; this will result in reduced clearance in the mechanical platform area, and additional roof framing will be required to accommodate the new curb size. The new chiller will be air-cooled, with dual screw compressors, variable speed condenser fans, dual factory installed chilled water pumps, packaged controls, and a premium sound attenuation package. During the RTU replacement, the existing building VAV box controllers and temperature sensors will be replaced, as well as the building automation system for control of the new RTUs, new chillers, and VAV boxes. 4.2.2 Electrical Evaluation Total system MCA of the proposed Option 2 equipment is 500A, exceeding the existing system power requirements (461A). For the new RTUs, existing conduit may be reused, and existing cable can be reused once RTU cable terminations are verified, due to the oversized existing feeds. The existing RTU breakers will need to be replaced with lower rated units. For the new chiller, a new breaker is required for the feed to the chiller, and new feeder and conduit is required from panel EMDP2 in the Switchgear room to the chiller location on the parking garage top level. There is available space in the panelboard for the new breaker. Due to the increased equipment MCA, it is recommended that the HVAC system be limited while running off generator power. This can be done via the proposed new BAS. 4.2.3 Structural Evaluation The chiller weight of 11,000 pounds spread over an area of roughly 8' x 24' is around 57 lbs./sq. ft. The typical parking structure design live load is 40 psf. Within the fenced area around the chiller, roof live loading within the protected area can be reduced to 20 psf which helps offset the weight of the chiller. Although structural drawings for the precast double tee members were not reviewed at this stage of the project, it appears that the proposal to put the chiller on the parking garage is feasible. The shear in the TT member for DL + LL is slightly larger than the shear for the original design condition of a 40 psf uniform live load. However, the International Existing Building Code allows an increase of 5 percent in Village of Mount Prospect 4-7 Burns & McDonnell Village Hall HVAC Revision: Final Evaluation of Options and Recommendations gravity load on existing structural elements without replacement or alteration. This 5% limit may be exceeded if a concrete pad is placed under the chiller in which case some reinforcement (likely using carbon fiber applied to the existing beams) may be required. Based on RISA modeling of the existing steel in the area of the RTU mechanical platforms, the maximum allowed RTU weight is 6,100 lbs. New RTU equipment weight must be below this limit, or structural modifications will be required. The Carrier RTU's proposed in this report are within this weight limit. Additionally, any modification to the size of the roof curbs will require new steel framing of the roof area below the RTU's. Weight of new RTUs to be within 10% of existing RTUs. Existing roof framing to be modified as required during detailed engineering to accommodate different unit size. 4.2.4 Sound Evaluation The sound levels emitted by the new remote chiller, located on the top level of the adjacent parking garage, was evaluated at the residential properties located immediately to the east and west of the parking garage. The sound levels for the remote chiller were provided by Trane for RTAC and ACSA models. The units have an overall sound power level of 101 A -weighted decibels (dBA) for the RTAC and 96 dBA for the ACSA unit operating at 100% load. Nighttime loads are expected to be lower and will result in slightly lower sound levels. Without further mitigation both units exceed the sound limits provided in Section 2.2 at various frequencies. The sound levels at 50% and 75% loads are also expected to exceed Village sound limits at various frequencies but does meet the overall dBA sound level equivalent. Additional mitigation in the form of low noise fans, vendor provided noise mitigation, or acoustical barriers would be required to reduce individual frequencies to at or below the Village sound limits for each individual frequency band. A comparison of the unmitigated sound levels, utilizing the ACSA unit, at the residential properties and the more restrictive nighttime limit are provided in Table 4-3. Table 4-3: Sound Pressure Levels at Residential Receivers for Option 2 a) Sound pressure levels are based on a remote chiller with a sound power level of 96 dBA and independent of existing sound sources. b)Sound level limits are defined for Zone I-1 and are not appliable to Zone 13-5C, per the Village Code. c) Sound levels in excess of the nighttime sound level limits are in bold. Village of Mount Prospect 4-8 Burns & McDonnell Sound Pressure Levels',' (dB) Total per Octave Band Frequency (Hz) Sound Limit / Receiver Level Location 31.5 63 125 250 500 1000 2000 4000 8000 (dBA) Nighttime Sound Limitb 67 66 65 52 46 40 35 35 32 51.7 Residential Property to East (Top Floor) 44.9 45.0 51.1 46.2 45.6 43.4 40.3 32.8 22.9 48.1 Residential Property to West (Top Floor 45.2 49.5 56.4 51.3 50.3 47.1 41.6 32.6 20.3 51.9 a) Sound pressure levels are based on a remote chiller with a sound power level of 96 dBA and independent of existing sound sources. b)Sound level limits are defined for Zone I-1 and are not appliable to Zone 13-5C, per the Village Code. c) Sound levels in excess of the nighttime sound level limits are in bold. Village of Mount Prospect 4-8 Burns & McDonnell Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.3 Option 3 — New Dx RTUs with Remote Condensing Units Replace the existing five (5) packaged RTUs with new RTUs; the three (3) units in the south mechanical platform area will be split type units with remote condensing units (with no cooling condensers in the pit area), and the two (2) units in the north mechanical platform area will be packaged RTUs (similar to Option 1). The south units proposed with this option move the cooling condensers out of the pit area, so that there is no heat generated by the RTUs in the south mechanical platform area. Preliminary equipment performance is listed in Table 4-4 below. Table 4-4: Option 3 Equipment Data Tag Unit Configuration Cooling Type Nominal Capacity (tons) Actual Capacity (MBH) Design Ambient (deg F) Electrical MCA Weight (lbs.) RTU -1 Remote CU Dx 40 469 105 38 5800 CU -1 Air -Cooled Dx 40 469 95 87 2700 RTU -2 Remote CU Dx 25 1 369 105 38 5400 CU -2 Air -Cooled Dx 25 369 95 52 2000 RTU -3 Remote CU Dx 20 266 105 31 4100 CU -3 Air -Cooled Dx 20 266 95 45 1 1700 RTU -4 Packaged Dx 30 308 105 90 5000 RTU -13 Packaged Dx 30 319 105 90 5000 • RTU -I, 2 & 3 data based on Trane CSAA Series rooftop units and matching condensing units. • RTU -4 & 5 data based on Carrier 48 Series rooftop units. The new RTUs will be located in the same rooftop mechanical platform locations as the existing (however, for the south platform area, no cooling condensers will be located in the pit). The three (3) new remote condensing units will be located on the top level of the adjacent parking garage. They will occupy the four (4) parking spots to the north of the existing handicapped parking spot (parking spot numbers 901-904). The new condensing units will be supported and leveled by a steel frame or a new concrete pad, although new concrete pad will add significant weight; see structural evaluation below. Pipe bollards and a security fence will be provided around the new chiller for protection. In conjunction with the RTU replacement, the existing roof will be replaced in each of the two mechanical platform areas. The new roof will be a white membrane roof, thereby reducing the heat in the pit area. White membrane roofs, when compared to black colored roofs (existing), can reduce surface temperature of the roof by 40 deg F or more. Village of Mount Prospect 4-9 Burns & McDonnell 19 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations During the RTU replacement, the existing building VAV box controls will be replaced, as well as the building automation system for control of the new RTUs, associated new condensing units, and new VAV box controllers. 4.3.1 Mechanical Evaluation The three new RTUs located in the south mechanical platform area (RTU -1, 2, & 3) will be furnished with variable speed supply fans, Dx cooling coils with remote condensing units, gas furnaces, filters, air side economizers, packaged controls, and roof curb adapters to transition supply/return air connections on new RTUs to the existing roof penetrations. The curb adapters will be approximately 48" high and will raise the top of the RTUs to approximately 24" above the existing roof edge. Preliminary equipment selections of the RTUs with Dx coils from multiple manufacturer's indicate that the footprint of the RTUs is somewhat larger than the existing units; this will result in reduced clearance in the mechanical platform area, and additional roof framing will be required to accommodate the new curb size. The new condensing units for the south platform RTUs will be air-cooled, with screw compressors, variable speed condenser fans, packaged controls with the associated RTU, and a sound attenuation package. The two new RTUs located in the north mechanical platform area (RTU -4, & B) will be packaged Dx type, similar to existing and the same as Option 1; see Option 1 description for additional information. During the RTU replacement, the existing building (VAV box controllers and temperature sensors will be replaced, as well as the building automation system for control of the new RTUs, new condensing units, and VAV boxes. 4.3.2 Electrical Evaluation Total system MCA of the proposed Option 3 equipment is 471 A, which is in line with the existing system power load (461A). For the new RTUs, existing conduit may be reused, and existing cable can be reused once RTU cable terminations are verified, due to the oversized existing feeds. For the three RTUs utilizing remote condensing units (RTU -1, 2, and 3), the existing RTU breakers will need to be replaced with lower rated units. For the two (2) RTUs being replaced with packaged equipment (RTU -4 & B), the existing breakers can be reused. For each new condensing unit (3), a new breaker is required in existing panel EMDP2, and new feeder and conduit is required from panel EMDP2 in the switchgear room to the condensing unit locations on the parking garage top level. There is available space in the panelboard for the new breakers. No special considerations are required for system loading while running off generator power. Village of Mount Prospect 4-10 Burns & McDonnell 70 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.3.3 Structural Evaluation The combined weight of the three remote condensing units is 8,000 lbs. spread over an area of roughly 8' x 24' is around 42 lbs./sq. ft. The typical parking structure design live load is 40 psf. However, if these units are located such that the load is spread between multiple precast TT's, this scenario still appears to work within the 5% increase in allowable load on an existing member. Within the fenced area around the condensing units, roof live loading within the protected area can be reduced to 20 psf which helps offset the weight of the units. Although structural drawings for the precast double tee members were not reviewed at this stage of the project, it appears that the proposal to put these condensing units on the parking garage is feasible. The 5% limit may be exceeded if a concrete pad is placed under the chiller in which case some reinforcement (likely using carbon fiber applied to the existing beams) may be required. Based on RISA modeling of the existing steel in the area of the RTU mechanical platforms, the maximum allowed RTU weight is 6,100 lbs. New RTU equipment weight must be below this limit, or structural modifications will be required. The RTUs proposed in this report are within this weight limit. Additionally, any modification to the size of the roof curbs will require new steel framing of the roof area below the RTUs. 4.3.4 Sound Evaluation The sound levels emitted by the three new remote condensing unists, located on the top level of the adjacent parking garage, and the five new RTUs, located on mechanical platforms, were evaluated at the residential properties located immediately to the east and west of the parking garage. The sound levels for the equipment were provided by Daikin. The condensers have an overall sound power levels ranging from 90 to 95 dBA and the RTUs have overall sound power levels ranging from 81 to 90 dBA. Without further mitigation both units exceed the sound limits provided in Section 2.2 at various frequencies. Additional mitigation in the form of low noise fans, vendor provided noise mitigation, or acoustical barriers would be required to reduce individual frequencies to at or below the Village sound limits for each individual frequency band. A comparison of the unmitigated sound levels at the residential properties and the more restrictive nighttime limit are provided in Table 4-5. Village of Mount Prospect 4-11 Burns & McDonnell 71 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations Table 4-5: Sound Pressure Levels at Residential Receivers for Option 3 a) Sound pressure levels are based on new remote condensing units RTUs and independent of existing sound sources. b)Sound level limits are defined for Zone I-1 and are not appliable to Zone B -5C, per the Village Code. c) Sound levels in excess of the nighttime sound level limits are in bold. 4.4 Engineers Opinion of Probable Construction Costs A summary of the Engineer's Opinion of Probable Construction Cost for each option is presented in Table 4-5. Table 4-6: Engineer's Opinion of Probable Construction Cost Sound Pressure Levels',' (dB) Total per Octave Band Frequency (Hz) Sound Limit / Receiver Level Equipment Unknown Fee Option Description Life Span Location 31.5 63 125 250 500 1000 2000 4000 8000 (dBA) Nighttime Sound Limit 67 66 65 52 46 40 35 35 32 51.7 Residential Property to East (Top Floor 51.8 51.3 50.6 45.9 43.4 42.4 38.3 34.3 28.6 46.9 Residential Property to West (Top Floor) 52.0 54.5 55.6 51.5 49.7 49.0 44.8 40.1 31.1 53.2 a) Sound pressure levels are based on new remote condensing units RTUs and independent of existing sound sources. b)Sound level limits are defined for Zone I-1 and are not appliable to Zone B -5C, per the Village Code. c) Sound levels in excess of the nighttime sound level limits are in bold. 4.4 Engineers Opinion of Probable Construction Costs A summary of the Engineer's Opinion of Probable Construction Cost for each option is presented in Table 4-5. Table 4-6: Engineer's Opinion of Probable Construction Cost 4.5 Summary Pros and Cons of each of the three options presented can be summarized as follows: Option 91: Up sized Packaged Dx RTUs: • Pros: o This option has the lowest cost. o Down time of the Village Hall HVAC will be minimized, since the new RTUs physical sizes and ductwork configuration will be nearly the same as the existing units. Village of Mount Prospect 4-12 Burns & McDonnell 72 Estimated Design Equipment Unknown Fee Option Description Life Span EOPCC Contingency Estimate Total Option 1 Upsized 20 years $933 k $280 k $93 k $1,306 k Packaged RTU CHW RTU 25 years $1,514 k $454 k $152 k $2,120 k Option 2 with Remote Chiller Split Dx RTU 20 years $1,202 k $361 k $120 k $1,683 k Option 3 with Remote Condenser 4.5 Summary Pros and Cons of each of the three options presented can be summarized as follows: Option 91: Up sized Packaged Dx RTUs: • Pros: o This option has the lowest cost. o Down time of the Village Hall HVAC will be minimized, since the new RTUs physical sizes and ductwork configuration will be nearly the same as the existing units. Village of Mount Prospect 4-12 Burns & McDonnell 72 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations o The area of work for the RTU replacement will be limited to the mechanical platform areas. o This option does not require the use the parking garage, and therefore will not consume any parking spaces. o With no new equipment on the parking structure, there are no new sound concerns. Noise levels of the new RTUs will be comparable to the existing. • Cons: o The RTU air conditioning systems are to remain on the roof, in the hot operating environment; this results in oversized units and greater energy consumption. A roof area temperature over 120-125 deg F could result in unit shut -down. o The oversized RTUs require more power, exceeding the requirements of the existing equipment. This may result is some load reduction when operating on the back-up generator (load reduction can be done by the proposed new BAS). 0 Option #2: Chilled Water RTUs and Remote Chiller: • Pros: o With the RTU air conditioning components moved out of the mechanical platform areas (replaced by the chiller), there is no risk of operational issues due to the roof area overheating. o With the chiller located in the cooler environment of the parking structure, it will operate more efficiently than the packaged RTUs. Additionally, use of chillers historically will be more energy efficient than packaged RTUs. Therefore, there will be some energy savings. o Typical service life of AHUs with chilled water coils and chillers is longer than packaged Dx equipment. • Cons: o This option has the highest cost and is significantly more expensive than Option 1. o Due to the different configuration of the RTUs, a roof curb adapter will be required, raising the top of the units to approximately 24" above the edge of the roof peak, making the RTUs visible from the street level. o This option results in a more complex HVAC system, including the addition of the chiller, chilled water pumps, and piping to/from the RTUs. This will most likely increase maintenance costs. o Maintenance of this option will be greater than Option 1, due to the additional equipment required. o The chiller is the sole source of air conditioning for the building (although it will be equipped with two separate refrigeration circuits); if the chiller faults, the entire Village Hall will lose air conditioning. o The chiller will occupy four (4) parking spaces in the parking garage. o The chiller will result in additional noise generation (although will be designed to meet sound ordinance). Village of Mount Prospect 4-13 Burns & McDonnell 73 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations o The electrical requirements of this option exceed the requirements of the existing equipment. This may result is some load reduction when operating on the back-up generator (load reduction can be done by the proposed new BAS). o The chiller option will result int the longest construction period, since currently chiller lead time is running approximately 32 weeks. o The chilled water system will require a glycol -water solution, to prevent freezing. Option #3: Split Dx RTUs with Remote Condensing Uni: • Pros: o With the condensing units for the three south RTUs being moved out of the hottest operating environment (south mechanical platform), there is no risk of operational issues due to the roof area overheating. o More efficient than Option 2 (less efficient than option 2). o The total HVAC electrical requirements are equivalent to the existing system, therefore no special loading considerations of the emergency generator are required. • Cons: o This option is significantly more costly than Option 1 (although less costly than Option 2). o Due to the different configuration of the RTUs, a roof curb adapter will be required, raising the top of the units to approximately 24" above the edge of the roof peak, making the RTUs visible from the street level. o Less efficient than Option 2 (more efficient than Option 1). o This option results in a more complex HVAC system, including the addition of the condensing units and refrigerant piping to/from the RTUs. o Maintenance of this option will be greater than Option 1, due to the additional equipment required and long runs of refrigerant piping needed, leading to greater chances of refrigerant leaks and potential quantity of refrigerant lost o Long refrigerant runs may result in possible trapping of oil. o The condensing units will four (4) parking spaces in the parking garage. o The condensing units will result in additional noise generation (although will be designed to meet sound ordinance). Village of Mount Prospect 4-14 Burns & McDonnell 74 Village Hall HVAC Revision: Final Evaluation of Options and Recommendations 4.6 Recommendation Based on the analysis of options presented in this Study, Burns & McDonnell recommends that the Village consider replacing the rooftop air conditioning units at the Village Hall with larger units having higher operating temperatures as detailed in Option 1. The Engineer's Opinion of Probable Construction Cost with a 30 percent contingency is $1.31 million. This is substantially less than either Option 2 (new AHUs and a new chiller) or Option 3 (new AHUs with remote condensing units). It is also important to note that the installation of either Option 2 or 3 will result in significantly more disruption to existing building operations, due to the required modifications to the roof curb footprint. Village of Mount Prospect 4-15 Burns & McDonnell 75 APPENDIX A PRELIMINARY SKETCHES FI LL OL s J � m 1� 5 a Naw io. U w z D L. w m UWQ W � 3 i � I w y mOU Fwd Frr� Opc~i 0 o � i a>ia way { r s J � m 1� 5 a Naw io. <z o�_M awa �LLo J UipFF 'Oz www OFA w y mOU Fwd Frr� Opc~i 0 o � i a>ia way { $W II a i a w � J t w S3 /Li .a, 2 O z i I R a ol aU' w s a 111 o LL� 1! ! I U rn0 W FX a r H W O Ei QZU� yyy � 3 ! I U _ =1. w� �r �I o I I 5 z a I ° w � 15� a Naw ioo � w S3 w LLz az z NLL �,o� »o �w oz .._. �� i�a o� mw _ z w wo ao woLL oz o >_ > OOp a 0o ao ax 0 oz a ¢ a p � I, �_ - - _._ �.++. �,.. ,� •;. L ._ ._...''dam ....,—. _ _.. � _.'_- _ A_ 1i -�.n �.: /Li .a, 2 O z i I R a ol aU' w s a 111 o LL� 1! ! I U rn0 W FX a r H W O Ei QZU� yyy � 3 ! I U _ =1. w� �r �I o I I 5 z a I ° w � J � w S3 os APPENDIX B - ENGINEER'S OPPINION OF PROBABLE CONSTRUCTION COST 81 Engineer's Opinion of Probable Construction Cost - VOMP Village Hall HVAC Study Project: VOMP Village Hall HVAC Study Owner: Village of Mt. Prospect Public Works Contact: Scott Moe Engineer: Burns & McDonnell Engineering Date: lune 1, 2022 Option 1: Upsized Packaged dx RTU's Demolition Demolition (RTU, curb, gas pipe, power) 5 EA $ 3,000.00 $ 15,000.00 Remove old RTU's (see hoist line item below) HVAC RTU -1 (including unit and curb) 1 EA $ 81,000.00 $ 81,000.00 RTU -2 (including unit and curb) 1 EA $ 57,000.00 $ S7,000.00 RTU -3 (including unit and curb) 1 EA $ 49,000.00 $ 49,000.00 RTU -4 (including unit and curb) 1 EA $ 54,000.00 $ S4,000.00 RTU -B (including unit and curb) 1 EA $ 54,000.00 $ 54,000.00 Hoist of RTU to existing roof (Crane & rigging; 4 trips due to phasing, demo & new) 4 EA $ S,000.00 $ 20,000.00 RTU Installation (including setting unit/curb, and connections to ductwork & gas pipe) 5 EA $ 10,000.00 $ 50,000.00 VAV Box controls upgrade (VAV to remain; replace controller, sensors, control valve) 55 EA $ 3,500.00 $ 192,500.00 Controls Allowance (New BAS, integrate RTU's and VAV's) 1 EA $ 70,000.00 $ 70,000.00 Test and Balance (TAB) of RTU's 5 EA $ 3,000.00 $ 15,000.00 Test and Balance (TAB) of VAV's 55 EA $ 500.00 $ 27,500.00 Electrical Power hook-up for new RTU's 5 EA $ 2,000.00 $ 10,000.00 RTU -1 new breaker and feeder/conduit 1 EA $ 10,000.00 $ 10,000.00 Structural Modify RTU framing to accommodate new unit (RTU -1 only) 1 EA $ 4,000.00 $ 4,000.00 Roofing Replace roofing at two RTU locations 2280 SF $ 30.00 $ 68,400.00 Replace wall membrane at two RTU locations 1686 SF $ 20.00 $ 33,720.00 Sound Reduction Included with RTU $ - Subtotal Overhead and Profit 15% $ $ 811,120 121,668 EOPCC Contingency (30%) Engineering Fee 10% $ $ $ 932,788 279,836 93,279 TOTAL $ 1,305,903 82 Engineer's Opinion of Probable Construction Cost - VOMP Village Hall HVAC Study Project: VOMP Village Hall HVAC Study Owner: Village of Mt. Prospect Public Works Contact: Scott Moe Engineer: Burns & McDonnell Engineering Date: lune 1, 2022 Option 2: CHW RTU's and Chiller Demolition Demolition (RTU, curb, gas pipe, power) 5 EA $ 3,000.00 $ 15,000.00 Remove old RTU's (see hoist line item below) HVAC RTU -1 (including unit and curb) 1 EA $ 90,000.00 $ 90,000.00 RTU -2 (including unit and curb) 1 EA $ 7S,000.00 $ 75,000.00 RTU -3 (including unit and curb) 1 EA $ 60,000.00 $ 60,000.00 RTUA (including unit and curb) 1 EA $ 6S,000.00 $ 65,000.00 RTU -B (including unit and curb) 1 EA $ 65,000.00 $ 65,000.00 Hoist of RTU to existing roof (Crane & rigging, 4 trips due to phasing, demo & new) 4 EA $ S,000.00 $ 20,000.00 RTU Installation (including setting unit/curb, and duct/pipe (CHW,gas) connections) 5 EA $ 15,000.00 $ 75,000.00 Chiller (including packaged pumps and controls) 1 EA $ 190,000.00 $ 190,000.00 Hoist of Chiller to top level of parking structure 1 EA $ 8,000.00 $ 8,000.00 Chiller Installation (including setting chiller, pipe connections) 1 EA $ 25,000.00 $ 25,000.00 CHW main piping (4"/6", including pipe, insulation, and supports) 400 LF $ 175.00 $ 70,000.00 CHW branch piping (3", including pipe, insulation, and supports) 100 LF 1 $ 150.00 $ 15,000.00 VAV Box controls upgrade (VAV to remain; replace controller, sensors, control valve) 55 EA $ 3,500.00 $ 192,500.00 Controls Allowance (New BAS, integrate RTU's and VAV's) 1 EA $ 50,000.00 $ 50,000.00 Test and Balance (TAB) of RTU's 5 EA $ 3,000.00 $ 15,000.00 Test and Balance (TAB) of chiller 1 EA $ 5,000.00 $ 5,000.00 Test and Balance (TAB) of VAV's 55 EA $ 500.00 $ 27,500.00 Controls (New BAS, integrate RTU's, chiller, and VAV's) 1 EA $ 70,000.00 $ 70,000.00 Electrical Power hook-up for new RTU's 5 EA $ 2,000.00 $ 10,000.00 RTU circuit breaker (reduced size to protect new RTU) 5 EA $ 1,500.00 $ 7,500.00 Chiller circuit breaker 1 EA $ 2,000.00 $ 2,000.00 Conduit/cable to chiller 200 LF $ 100.00 $ 20,000.00 Structural Modify RTU framing to accommodate new unit 5 EA $ 4,000.00 $ 20,000.00 Chiller framing/pad on top level of parking structure 1 EA $ 5,000.00 $ 5,000.00 Pipe Bollards 12 EA $ 800.00 $ 9,600.00 Roofing/Fencing Replace roofing at two RTU locations 2280 SF $ 30.00 $ 68,400.00 Replace wall membrane at two RTU locations 1686 SF $ 20.00 $ 33,720.00 Fence surrounding new condensing units on parking gargae roof 100 LF $ 75.00 $ 7,500.00 Sound Reduction Included with RTU and chiller $ - Subtotal Overhead and Profit 15% $ 1,316,720 $ 197,508 EOPCC Contingency (30%) Engineering Fee (10%) $ 1,514,228 $ 454,268 $ 151,423 TOTAL $ 2,119,919 83 Engineer's Opinion of Probable Construction Cost - VOMP Village Hall HVAC Study Project: VOMP Village Hall HVAC Study Owner: Village of Mt. Prospect Public Works Contact: Scott Moe Engineer: Burns & McDonnell Engineering Date: lune 1, 2022 Option 2: Dx RTU's and Remote Condensing units Demolition Demolition (RTU, curb, gas pipe, power) 5 EA $ 3,000.00 $ 15,000.00 Remove old RTU's (see hoist line item below) HVAC RTU-1/CU-1 (including unit and curb) 1 EA $ 95,000.00 $ 95,000.00 RTU-2/CU-1 (including unit and curb) 1 EA $ 8S,000.00 $ 85,000.00 RTU-3/CU-1 (including unit and curb) 1 EA $ 80,000.00 $ 80,000.00 RTUA (including unit and curb) 1 EA $ 54,000.00 $ S4,000.00 RTU -B (including unit and curb) 1 EA $ 54,000.00 $ 54,000.00 Hoist of RTU & CU to existing roof (Crane & rigging, 4 trips due to phasing, demo & new) 4 EA $ S,000.00 $ 20,000.00 RTU/CU Installation (including setting unit/curb, and duct/pipe (refrig,gas) connections) 3 EA $ 20,000.00 $ 60,000.00 RTU Installation (including setting unit/curb, and duct/pipe (gas) connections) 2 EA $ 10,000.00 $ 20,000.00 Refrigerant piping (including pipe, insulation, and supports) 900 LF $ 75.00 $ 67,500.00 VAV Box controls upgrade (VAV to remain; replace controller, sensors, control valve) 55 EA $ 3,500.00 $ 192,500.00 Test and Balance (TAB) of RTU/CU 3 EA $ 4,000.00 $ 12,000.00 Test and Balance (TAB) of RTU's 2 EA $ 3,000.00 $ 6,000.00 Test and Balance (TAB) of VAV's 55 EA $ 500.00 $ 27,500.00 Controls Allowance (New BAS, integrate RTU's and VAV's) 1 EA $ 70,000.00 $ 70,000.00 Electrical Power hook-up for new RTU's 5 EA $ 2,000.00 $ 10,000.00 RTU circuit breaker (reduced size to protect new RTU) 3 EA $ 1,500.00 $ 4,500.00 Circuit Breakers for new condensing units 3 EA $ 2,000.00 $ 6,000.00 Conduit/cable to condensing units 600 LF $ 50.00 $ 30,000.00 Structural Modify RTU framing to accommodate new unit (north platform units only) 3 EA $ 4,000.00 $ 12,000.00 Condensing unit framing/pad on top level of parking structure 1 EA $ S,000.00 $ 5,000.00 Pipe Bollards 12 EA $ 800.00 $ 9,600.00 Roofing/Fencing Replace roofing at two RTU locations 2280 SF $ 30.00 $ 68,400.00 Replace wall membrane at two RTU locations 1686 SF $ 20.00 $ 33,720.00 Fence surrounding new condensing units on parking gargae roof 100 LF $ 75.00 $ 7,500.00 Sound Reduction Included with RTU's and condensing units $ - Subtotal Overhead and Profit 15% $ 1,045,220 $ 156,783 EOPCC Contingency (30%) Engineering Fee 10% $ 1,202,003 $ 360,601 $ 120,200 TOTAL $ 1,682,804 84 Engineer's Opinion of Probable Construction Cost - VOMP Village Hall HVAC Study Project: VOMP Village Hall HVAC Study Owner: Village of Mt. Prospect Public Warks Contact: Scott Moe Engineer: Burns & McDonnell Engineering Date: June 1, 2022 Estimates, schedules, forecasts, and projections prepared by BMcD relating to pricing and other financial analysis parameters, construction costs and schedules, operations and maintenance costs, equipment characteristics and performance, and operating results are opinions based on BMcD's experience, qualifications, and judgement as a professional. Since Wel) has no control over weather, cost and availability of labor, cost and availability of material and equipment, cost of fael or other utilities, labor productivity, construction contractor's procedures and methods, unavoidable delays, construction contractor's method of determining prices, economic conditions, government regulations and laws (including interpretation thereof), competitive bidding or market conditions, and other factors affecting such estimates or projections, Wet) does not guarantee that actual rates, costs, quantities, performance, schedules, etc., will not vary significantly from estimates and projections prepared by BMcD. 85 APPENDIX C - PRELIMINARY EQUIPMENT CUT SHEETS :r OPTION 1 PRELIMINARY EQUIPMENT CUT SHEETS 87 Carrier SUBMITTAL Project Mt Prospect Village Hall HVAC Repl Date Tuesday, May 3, 2022 Marshall M Sayles Temperature Equipment Corporation R Table Of Contents Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -1 50 -Ton REV2 3 Unit Report 4 Certified Drawing - - - - - - --6 Corner Weight Report - - - - - - - - 13 RTU -2 REV214 --------------------------------------------------- - ----------------------------------------------------------------------------------------------- - ------------- ---------------------------------------------------------------------------------------- Unit Report 15 Certified Drawing --- ---- - 17 Corner Weight Report 24 RTU -3 REV2 25 Unit Report 26 Certified Drawing 28 Corner Weight Report 35 RTU -4 REV2 36 Unit Report-- --- -- --- -- --- -- --- -- --- - -- -----37 Certified Drawing 39 Corner Weight Report 46 RTU -5 REV2 47 UnitReport ------------------------------------------------------------------------------------------------------------------------------------- 48 Certified Drawing 50 Corner Weight Report 57 Applied Rooftop Builder 3.29s Page 2 of 57 99 RTU -1 (OPTION 1) G RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -1 50 -Ton REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 3 of 57 90 Unit Report For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: --- Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 050 (50 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 17' 11„ Unit Width: ------ 7. 10.. Unit Height: 6-11" Unit Operating Weight: 5680 Ib Unit Shipping Weight: _______________________5721 Ib —Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve 25 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D050LRG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 25 HP Applied Rooftop Builder 3.29s Page 4 of 57 91 Unit Report For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB006A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 5 of 57 92 �o �m � � o ` o 0 (� o A zzo oQ zwo 22 o zo Mo of o 00 0 oa o �o� 00 0��0� Qo ISo O z w Iq o 3 S CO o o� m� �o o wU y o 0 o H z0 ^ JO � w � w o Iq Performance Summary For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D050LRG64AGQ Unit Refrigerant: R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 14.4 Unit Dimensions Unit Length. 17' 11" Unit Width: 7,10" Unit Height: 6-1" Unit Operating Weight: 5680 Ib Unit Shipping Weight: 5721 Ib *Unit operating weight does not include accessories weight. BHP Unit 2.50 in wg Heating Type: Gas Heat in wg Supply/Return: Vertical/Vertical * Application Type: Staged Air Volume BHP Voltage: 460-3-60 Cooling Airflow: 14200 CFM Altitude: 0 ft Cond. Ent. Air Temp: 115.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 57.3 F Lvg. Air Wet Bulb: ---- ---- - 56.2 F Lvg. Air Enthalpy 23.87 BTU/Ib Gross Cooling Capacity: 483.56 MBH Gross Sensible Clg. Cap: 348.48 MBH Compressor Power. 50.9 kW Coil Bypass Factor. 0.05 Refrigerant Charge, Circuit A: 27.0 Ib Refrigerant Charge, Circuit B: 28.0 Ib Part Load(%) Operation Cooling Capacity Steps: 25,50,75,100 Gas Heating Data: Heating Airflow: 14200 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 300/ 400 MBH Number of Heating Steps: 2 Gas Input (Min): 300 MBH Gas Input (Max): 400 MBH Gas Output: 324 MBH Heating Lvg. Air Temp: 76.1 F Steady State Eff: 81 Temp.Rise: 21.1 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 1130 * Supply Fan BHP: 18.21 BHP Supply Fan Motor HP: 25 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 11000 CFM Applied Rooftop Builder 3.29s Page 8 of 57 95 Performance Summary For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.11 in wg Page 9 of 57 96 Performance Summary For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 16 Compressor #A1 LRA: 140 Compressor#A2 RLA: ---- --- 16 Compressor #A2 LRA: 140 Compressor #B1 RLA: 16 Compressor#B1 LRA: ---- --- 140 Compressor #132 RLA: 16 Compressor #132 LRA: 140 Indoor Fan Motor HP: 25 Indoor Fan Motor FLA: 34 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 132 Power Supply MOCP (Fuse or HACR): 150 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 4/3.3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 10 of 57 97 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 89.8 90.4 64.2 125 Hz 83.1 83.2 73.9 250 Hz 92.0 80.3 80.9 500 Hz 77.5 76.4 84.3 1000 Hz 77.0 77.1 86.7 2000 Hz 74.8 74.4 81.3 4000 Hz 71.4 73.1 74.8 8000 Hz 63.8 68.2 66.4 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 10 of 57 97 Performance Summary For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 64.2 73.9 80.9 84.3 86.7 81.3 74.8 66.4 90.2 Lw B 38.0 57.8 72.3 81.1 86.7 82.5 75.8 65.3 89.2 LwA C 30.9 40.6 47.6 51.0 53.4 48.0 41.5 33.1 56.9 Lp D 4.7 24.5 39.0 47.8 53.4 49.2 42.5 32.0 55.9 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 11 of 57 98 Performance Summary For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve 4 1000 1100RPM M3 -z ZOOM 1300 900RPM 3 70ORPM 35. BHP 60ORPM \ .00BH \2500 50ORPM 20. HP 1 400RPM 30ORPM 0 2 4 6 8 10 12 14 16 18 M 72 Aidow(CFM-thousands) RPM= 1130BHP=18.21 MaximumRPM=1300MaximumHP=30.00 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 12 of 57 99 Corner Weight / Center of Gravity Report For RTU -1 50 -Ton REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 9' 10" CG Dimension (B): 3' 5" Unit Length: 17'11" Unit Width: 7' 10„ Unit Height: 6' 1„ Unit Weight: 5679.7 Ib Unit Shipping Weight: 5720.6 Ib Corner Weight (1): 1357.0 Ib Corner Weight (2): 1208.0 Ib Corner Weight (3): 1456.0 Ib Corner Weight (4): 1658.7 Ib Total Corner Weight: 5679.7 Ib Applied Rooftop Builder 3.29s 3 4 48A6D050LRG64AGQ Page 13 of 57 100 R TU % (OPTION RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -2 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 14 of 57 101 Unit Report For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: --- Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 035 (35 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6-11" Unit Operating Weight: 4961 Ib Unit Shipping Weight: _______________________5002 Ib —Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve 20 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D035LQG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 20 HP Applied Rooftop Builder 3.29s Page 15 of 57 102 Unit Report For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONVO06A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 16 of 57 103 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d Q U Q 2 CU U) Co C� U L Q Co O 2i c m G U ca N O � � d Ln 0 T Performance Summary For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D035LQG64AGQ Unit Refrigerant: R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 13.5 Unit Dimensions Unit Length. 13' 9" Unit Width: 7' 10" Unit Height: 6' 1" Unit Operating Weight: 4961 Ib Unit Shipping Weight: 5002 Ib *Unit operating weight does not include accessories weight. Unit Heating Type: Gas Heat Supply/Return: Vertical/Vertical Application Type: Staged Air Volume Voltage: 460-3-60 Cooling Airflow: 13500 CFM Altitude: 0 ft Cond. Ent. Air Temp: 115.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 58.4 F Lvg. Air Wet Bulb: ---- ---- - 58.4 F Lvg. Air Enthalpy 25.36 BTU/Ib Gross Cooling Capacity: 369.39 MBH Gross Sensible Clg. Cap: 314.39 MBH Compressor Power. 39.5 kW Coil Bypass Factor. 0.027 Refrigerant Charge, Circuit A: 17.9 Ib Refrigerant Charge, Circuit B: 26.0 Ib Part Load(%) Operation Cooling Capacity Steps: 20,50,80,100 Gas Heating Data: Heating Airflow: 13500 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 262.5/ 350 MBH Number of Heating Steps: 2 Gas Input (Min): 262.5 MBH Gas Input (Max): 350 MBH Gas Output: 283.5 MBH Heating Lvg. Air Temp: 74.4 F Steady State Eff: 81 Temp.Rise: 19.4 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 1144 * Supply Fan BHP: 14.80 BHP Supply Fan Motor HP: 20 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 11000 CFM Applied Rooftop Builder 3.29s Page 19 of 57 106 Performance Summary For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.11 in wg Page 20 of 57 107 Performance Summary For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 10.6 Compressor #A1 LRA: 75 Compressor#A2 RLA: ---- --- 10.6 Compressor #A2 LRA: 75 Compressor #B1 RLA: 14.8 Compressor#B1 LRA: ---- --- 130 Compressor #132 RLA: 14.8 Compressor #132 LRA: 130 Indoor Fan Motor HP: 20 Indoor Fan Motor FLA: 27 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 104 Power Supply MOCP (Fuse or HACR): 125 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3.3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 21 of 57 108 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 96.0 91.1 63.9 125 Hz 92.0 80.6 72.2 250 Hz 92.4 76.1 79.0 500 Hz 90.2 72.3 82.0 1000 Hz 91.3 73.3 84.1 2000 Hz 88.4 69.5 79.0 4000 Hz 84.9 68.1 73.3 8000 Hz 78.5 63.3 65.1 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 21 of 57 108 Performance Summary For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.9 72.2 79.0 82.0 84.1 79.0 73.3 65.1 87.9 Lw B 37.7 56.1 70.4 78.8 84.1 80.2 74.3 64.0 86.8 LwA C 30.6 38.9 45.7 48.7 50.8 45.7 40.0 31.8 54.6 Lp D 4.4 22.8 37.1 45.5 50.8 46.9 41.0 30.7 53.5 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 22 of 57 109 Performance Summary For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve 4 I I I I I UEE,_\ \ \ 3 30. BHP - 2 -dl RPM 1 25 HP 20.00 HP 173 OOBH 15.00 R )\M HP q00 " /M BHP 3. P B 5B 1. BH PkPP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 23 Aidow(CFM-thousands) RPM= 1144 B1HP=14.80 MaxlmumRPM=1300 MaximumHP=30.00 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 23 of 57 110 Corner Weight / Center of Gravity Report For RTU -2 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 7' 11" CG Dimension (B): 3' 5" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1" Unit Weight: 4960.7 Ib Unit Shipping Weight: 5001.6 Ib Corner Weight (1): 1126.0 Ib Corner Weight (2): 986.0 Ib Corner Weight (3): 1328.0 Ib Corner Weight (4): 1520.7 Ib Total Corner Weight: 4960.7 Ib Applied Rooftop Builder 3.29s 3 4 48A6D035LQG64AGQ Page 24 of 57 111 RTIJ-3 (OPTION 1) RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -3 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 25 of 57 112 Unit Report For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: --- Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 025 (25 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6-11" Unit Operating Weight: 4548 Ib Unit Shipping Weight: _______________________4586 Ib —Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve 15 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D025LPG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 15 HP Applied Rooftop Builder 3.29s Page 26 of 57 113 Unit Report For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 27 of 57 114 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d Ln r T Q U Q 2 CU U) Co C� U L Q O 2i c m G U ca N O � � d Performance Summary For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D025LPG64AGQ Unit Refrigerant: - - - - - - - R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 13.2 Unit Dimensions Unit Length. 13' 9" Unit Width: 7' 10" Unit Height: 6' 1" Unit Operating Weight: 4548 Ib Unit Shipping Weight: 4586 Ib *Unit operating weight does not include accessories weight. BHP Unit 2.50 in wg Heating Type: Gas Heat in wg Supply/Return: Vertical/Vertical * Application Type: Staged Air Volume BHP Voltage: 460-3-60 Cooling Airflow: 7500 CFM Altitude: 0 ft Cond. Ent. Air Temp: 115.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 56.7 F Lvg. Air Wet Bulb: 55.8 F Lvg. Air Enthalpy:23.62 - - ---------------------------------------------------------------------------------------------- - - - - - BTU/Ib Gross Cooling Capacity: 264.00 MBH Gross Sensible Clg. Cap: 188.40 MBH Compressor Power. 28.9 kW Coil Bypass Factor. 0.15 Refrigerant Charge, Circuit A: 16.5 Ib Refrigerant Charge, Circuit B: 11.0 Ib Part Load(%) Operation Cooling Capacity Steps: 33,67,100 Gas Heating Data: Heating Airflow: 7500 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 262.5/ 350 MBH Number of Heating Steps: 2 Gas Input (Min): 262.5 MBH Gas Input (Max): 350 MBH Gas Output. 283.5 MBH Heating Lvg. Air Temp: 90.0 F Steady State Eff: 81 Temp.Rise: ---- - --- 35.0 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 948 * Supply Fan BHP: 5.80 BHP Supply Fan Motor HP: 15 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 6500 CFM Applied Rooftop Builder 3.29s Page 30 of 57 117 Performance Summary For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.90 in wg Page 31 of 57 118 Performance Summary For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 12.8 Compressor #A1 LRA: 100 Compressor#A2 RLA: ---- --- 12.8 Compressor #A2 LRA: 100 Compressor#B1 RLA: ---- --- 12.8 Compressor#B1 LRA: ---- --- 100 Indoor Fan Motor HP: 15 Indoor Fan Motor FLA: 21 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 84 Power Supply MOCP (Fuse or HACR): 100 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3.3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 32 of 57 119 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 92.7 88.7 63.7 125 Hz 81.8 77.1 72.2 250 Hz 80.3 75.7 78.9 500 Hz 82.6 71.5 81.9 1000 Hz 82.1 73.2 83.9 2000 Hz 77.9 68.9 78.8 4000 Hz 75.5 67.5 72.8 8000 Hz 70.2 63.0 64.6 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 32 of 57 119 Performance Summary For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.7 72.2 78.9 81.9 83.9 78.8 72.8 64.6 87.7 Lw B 37.5 56.1 70.3 78.7 83.9 80.0 73.8 63.5 86.6 LwA C 30.4 38.9 45.6 48.6 50.6 45.5 39.5 31.3 54.4 L D 4.2 22.8 37.0 45.4 50.6 46.7 40.5 30.2 53.3 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 33 of 57 120 Performance Summary For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve Aidow(CFM-thousands) RPM=948 BHP=5.80MaximwnRPM=1200 MaximumHP=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 34 of 57 121 � �7zpm 11UE 3 70DF PM soo \ \ I I 1 7.5025. 10.00B 1 15. BHP I HP 1. P 2.00 P 5 B HP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 2 Aidow(CFM-thousands) RPM=948 BHP=5.80MaximwnRPM=1200 MaximumHP=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 34 of 57 121 Corner Weight / Center of Gravity Report For RTU -3 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 8' 0" CG Dimension (B): 3' 8" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1" Unit Weight: 4548.4 Ib Unit Shipping Weight: 4586.0 Ib Corner Weight (1): 928.0 Ib Corner Weight (2): 951.0 Ib Corner Weight (3): 1325.0 Ib Corner Weight (4): 1344.4 Ib Total Corner Weight: 4548.4 Ib Applied Rooftop Builder 3.29s 3 4 48A6D025LPG64AGQ Page 35 of 57 122 �1[`:b O /% % [ 1 RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -4 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 36 of 57 123 Unit Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 030 (30 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6, 1„ Unit Operating Weight: 4652 Ib Unit Shipping Weight: _______________________4690 Ib ***Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve ---------------------------- 15 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D030LPG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 15 HP Applied Rooftop Builder 3.29s Page 37 of 57 124 Unit Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 38 of 57 125 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d w N T Q U Q 2 CU U) Co C� U L Q Co O 2i c m G U ca N O � � d r -- C14 T Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D030LPG64AGQ Unit Refrigerant: R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 14.0 Unit Dimensions Unit Length. 13' 9" Unit Width: 7' 10" Unit Height: 6' 1" Unit Operating Weight: 4652 Ib Unit Shipping Weight: 4690 Ib *Unit operating weight does not include accessories weight. Unit Heating Type: Gas Heat Supply/Return: Vertical/Vertical Application Type: Staged Air Volume Voltage: 460-3-60 Cooling Airflow: 7800 CFM Altitude: 0 ft Cond. Ent. Air Temp: 105.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 54.7 F Lvg. Air Wet Bulb: ---- ---- - 54.1 F Lvg. Air Enthalpy 22.64 BTU/Ib Gross Cooling Capacity: 308.94 MBH Gross Sensible Clg. Cap: 212.84 MBH Compressor Power. 29.3 kW Coil Bypass Factor. 0.112 Refrigerant Charge, Circuit A: 15.1 Ib Refrigerant Charge, Circuit B: 15.3 Ib Part Load(%) Operation Cooling Capacity Steps: 25,50,75,100 Gas Heating Data: Heating Airflow: 7800 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 262.5/ 350 MBH Number of Heating Steps: 2 Gas Input (Min): 262.5 MBH Gas Input (Max): 350 MBH Gas Output: 283.5 MBH Heating Lvg. Air Temp: 88.7 F Steady State Eff: 81 Temp.Rise: 33.7 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 956 * Supply Fan BHP: 6.07 BHP Supply Fan Motor HP: 15 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 6800 CFM Applied Rooftop Builder 3.29s Page 41 of 57 128 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.84 in wg Page 42 of 57 129 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 11.2 Compressor #A1 LRA: 75 Compressor#A2 RLA: ---- --- 11.2 Compressor #A2 LRA: 75 Compressor #B1 RLA: 11.2 Compressor#B1 LRA: ---- --- 75 Compressor #132 RLA: 11.2 Compressor #132 LRA: 75 Indoor Fan Motor HP: 15 Indoor Fan Motor FLA: 21 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 90 Power Supply MOCP (Fuse or HACR): 110 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3-3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 43 of 57 `KTt1 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 92.9 88.8 63.9 125 Hz 82.3 77.2 72.2 250 Hz 80.6 75.7 78.9 500 Hz 83.1 71.5 82.1 1000 Hz 82.8 73.2 84.1 2000 Hz 78.6 68.9 78.8 4000 Hz 76.1 67.5 72.5 8000 Hz 70.6 63.0 64.6 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 43 of 57 `KTt1 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.9 72.2 78.9 82.1 84.1 78.8 72.5 64.6 87.9 Lw B 37.7 56.1 70.3 78.9 84.1 80.0 73.5 63.5 86.7 LwA C 30.6 38.9 45.6 48.8 50.8 45.5 39.2 31.3 54.5 Lp D 4.4 22.8 37.0 45.6 50.8 46.7 40.2 30.2 53.4 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 44 of 57 131 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve Aidow(CFM-thousands) RPM=956BHP=6.07MaximumRPM=1200Maximumf]P=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 45 of 57 132 � �7zpm x7\--, 11UE 3 70DF PM 6DOR -M \ \ I I 1 7'� 10.00B 1 15. BHP I HP 1. P 2.00 P 5 B 25. HP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 2 Aidow(CFM-thousands) RPM=956BHP=6.07MaximumRPM=1200Maximumf]P=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 45 of 57 132 Corner Weight / Center of Gravity Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 7' 10" CG Dimension (B): 3' 8" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1„ Unit Weight: 4652.3 Ib Unit Shipping Weight: 4690.0 Ib Corner Weight (1): 1001.0 Ib Corner Weight (2): 1001.0 Ib Corner Weight (3): 1325.0 Ib Corner Weight (4): 1325.3 Ib Total Corner Weight: 4652.3 Ib Applied Rooftop Builder 3.29s 3 4 48A6D030LPG64AGQ Page 46 of 57 133 RTU � J1>17 (OPTION o "' RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -5 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 47 of 57 134 Unit Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: --- Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 030 (30 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6-11" Unit Operating Weight: 4652 Ib Unit Shipping Weight: _______________________4690 Ib —Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve 15 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D030LPG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 15 HP Applied Rooftop Builder 3.29s Page 48 of 57 135 Unit Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 49 of 57 136 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d Q U Q 2 CU U) Co C� U L Q O 2i c m G U ca N O � � d co M T Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D030LPG64AGQ Unit Refrigerant: R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 14.0 Unit Dimensions Unit Length. 13' 9" Unit Width: 7' 10" Unit Height: 6' 1" Unit Operating Weight: 4652 Ib Unit Shipping Weight: 4690 Ib *Unit operating weight does not include accessories weight. Unit Heating Type: Gas Heat Supply/Return: Vertical/Vertical Application Type: Staged Air Volume Voltage: 460-3-60 Cooling Airflow: 10500 CFM Altitude: 0 ft Cond. Ent. Air Temp: 105.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 58.4 F Lvg. Air Wet Bulb: ---- ---- - 57.3 F Lvg. Air Enthalpy 24.58 BTU/Ib Gross Cooling Capacity: 323.90 MBH Gross Sensible Clg. Cap: 245.50 MBH Compressor Power. 29.5 kW Coil Bypass Factor. 0.14 Refrigerant Charge, Circuit A: 15.1 Ib Refrigerant Charge, Circuit B: 15.3 Ib Part Load(%) Operation Cooling Capacity Steps: 25,50,75,100 Gas Heating Data: Heating Airflow: 10500 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 262.5/ 350 MBH Number of Heating Steps: 2 Gas Input (Min): 262.5 MBH Gas Input (Max): 350 MBH Gas Output: 283.5 MBH Heating Lvg. Air Temp: 80.0 F Steady State Eff: 81 Temp.Rise: 25.0 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 1037 * Supply Fan BHP: 8.99 BHP Supply Fan Motor HP: 15 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 9000 CFM Applied Rooftop Builder 3.29s Page 52 of 57 139 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.45 in wg Page 53 of 57 140 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 11.2 Compressor #A1 LRA: 75 Compressor#A2 RLA: ---- --- 11.2 Compressor #A2 LRA: 75 Compressor #B1 RLA: 11.2 Compressor#B1 LRA: ---- --- 75 Compressor #132 RLA: 11.2 Compressor #132 LRA: 75 Indoor Fan Motor HP: 15 Indoor Fan Motor FLA: 21 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 90 Power Supply MOCP (Fuse or HACR): 110 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3-3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 54 of 57 141 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 94.3 89.5 63.9 125 Hz 86.8 78.2 72.2 250 Hz 84.2 75.7 78.9 500 Hz 87.2 71.7 82.1 1000 Hz 87.9 73.3 84.1 2000 Hz 84.4 69.1 78.8 4000 Hz 80.9 67.6 72.5 8000 Hz 74.5 63.0 64.6 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 54 of 57 141 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.9 72.2 78.9 82.1 84.1 78.8 72.5 64.6 87.9 Lw B 37.7 56.1 70.3 78.9 84.1 80.0 73.5 63.5 86.7 LwA C 30.6 38.9 45.6 48.8 50.8 45.5 39.2 31.3 54.5 Lp D 4.4 22.8 37.0 45.6 50.8 46.7 40.2 30.2 53.4 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 55 of 57 142 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve 4 11 � �7zpm 3 700FPM IM \ \ I I 1 1 I 10.00B 15. BHP 00 HP 1. P 2.00 P `' B �'� 25. HP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 23 Aidow(CFM-thousands) RPM= 1037 BHP=8.99 MaximumRPM=1200 MaximumHP=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 56 of 57 143 Corner Weight / Center of Gravity Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 7' 10" CG Dimension (B): 3' 8" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1" Unit Weight: 4652.3 Ib Unit Shipping Weight: 4690.0 Ib Corner Weight (1): 1001.0 Ib Corner Weight (2): 1001.0 Ib Corner Weight (3): 1325.0 Ib Corner Weight (4): 1325.3 Ib Total Corner Weight: 4652.3 Ib Applied Rooftop Builder 3.29s 3 4 48A6D030LPG64AGQ Page 57 of 57 144 OPTION 2 PRELIMINARY EQUIPMENT CUT SHEETS 145 ��' „�',y I ( P Aman ,k dmmi IA41 I'i,4)n,AA/i[hq,� I h 1l I VV6A( IliutI,iq AC'A...IrCHILLER (OPTION 2)] �M�'�'r6N" i1ilYlkmw itri<<I I'rn CJi iri7lilp 1 Evaporator Application��fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff 0.000100 hr -sq ft -deg F/ Btu Fluid Type Propylene Glycol Flow Switch Set Point 45 Fluid Concentration 30.00 % 298.58 gpm Flui,d'Freeze Point i 9.19 F 10.46 ft Entering Temoorature56.00 F 6.00 ft Leaving Temperature, 44.00 F 247.70 gpm Standard Ambient Aluminum Micro Channel Ambient Air Urnp 95.00 F 8 Satw,rated Cond - ckt 1.' 122.08 F Saturated Cond - ckt 2 122.08 F 460V/6OHz/3 phase TotalPower177.13 kW Compl'essor 1A' 69.00 A Compressor -Starter Across -The -Line -Starter Compressor1R'�69.00A Ineon ling'L,ine Connection Single Point Unit Power Connection Compressor2A 69.00 A Incoinin'g Line Connection Type Circuit Breaker Compressor2ff; 69.00 A Short Circuit Current Rating Default Short Circuit Rating FLA - Condenser,FAn (each) 2.70 A f� resrsor 1A L LRA 344.00 A Compressor 1 B X L LRA 344.00 A Single Point Power Connpressor�ZA X -L LRA' 344.00 A �,�1y3�41)))))8)))))))))A)))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))) Compressor ZB X -L LRA' 344.00 A Single Point Power 400 A 229 in 88 in 98 in Dual Pump High Pressure with Dual Available Head; 130.58 ft VFD Net Positive Suction Head 25.000 hp required 11.92 ft 34.00 A 10865 lb Refrigerant; 65.0 lb 10724 Ib Oii. 3.10 gal 65.0 Ib 3.10 gal 2022/05/0211:11:19 OPTION,,., 146 dmmv4It1'i,,,)ndv/i[hq,�Ih11IVVA IhiitI3iq A `A I ri I it 1 mwd I'oi. C1i..iaiflk(y 1 �mtl�tJ� Superior Sound Level 100" 94 dB 100 dB 95 dB 94 dB 91 dB 86 dB 79 dB 74 dB 96 dBA 75 " ':" 99 dB 93 dB 92 dB 90 dB 84 dB 78 dB 74 dB 94 dBA 50 89 dB 96 dB 91 dB 89 dB 87 dB 82 dB 75 dB 73 dB 91 dBA 25 87 dB 91 dB 86 dB 86 dB 83 dB 79 dB 73 dB 70 dB 88 dBA Standard full and part -load rating conditions per AHRI 550/590 100 67 dB 73 dB 68 dB 67 dB 64 dB 59 dB 52 dB 47 dB 69 dBA 75 " 64 dB 72 dB 66 dB 65 dB 63 dB 57 dB 51 dB 47 dB 67 dBA 00 62 dB 69 dB 64 dB 62 dB 60 dB 55 dB 48 dB 46 dB 64 dBA 25, 60 dB 64 dB 59 dB 59 dB 56 dB 52 dB 46 dB 43 dB 61 dBA Standard full and part -load rating conditions per AHRI 550/590 Refrigerant Charge,- ckt 11 65.0 Ib Refrigerant Charge,- akt 2 65.0 Ib Rated Refrigerating" Capacity; 146.58 tons Rated,,Cooling Efficiency9.886 EER (Btu/W-h) Rated IPLV 16.243 EER (Btu/W-h) Refrigerating Capacity 144.34 tons Cooling Efficiency 9.779 EER (Btu/W-h) Coflnpress& Power 168.26 kW Fan motorPower 8.84 kW Certified in accordance with the AHRI Air -Cooled Water -Chilling Packages Certification Program, which is based on AHRI Standard 550/590 (I -P) and AHRI Standard 551/591 (SI). Certified units may be found in the AHRI Directory at www.ahridirectory.org. Unit contains freeze protection liquids in the evaporator and is certified when rated per the Standard with water. ..................................................................................................................................................................................................................................................................... Trane Select Assist 258 Version Number: Data Generation Date: 5/2/2022 2022/05/02 11:11:19 This product meets the minimum efficiency requirements of ASHRAE Standard 90.1 and CANS/CSA C743 for all versions (which are based on AHRI standard rating conditions) and, therefore, also meets the LEED "Minimum Energy Performance" prerequisite in the Energy and Atmohphere section. The LEED Green Building Rating System TM, developed by the U.S. Green Building Council, provides indepenent, third -party verification that a building project meets green building and performance measures Page 2 of 147 . . ... .. .... "Mai ,Irl Ik, IT I, � 1\41 111 (,4)nd Vi[k I, 7,� I I a I I I IVA C Hiii( kiq AC'A I I iml,mmd I (,I cr 0 E Z Z CL z U)0 0 T Z (f 0 LU I z C) w < C) Llj (!) u. (f) z Z Z I Z 0 0 �-, z LLJ 0 > o z X ff E 0 W w w U) 11 - I-.. 2k 0 00 Z Z() OliniflOy I 2022/05/02 11:11:19 Page 3 of 148 k dmmIV 1, 4)n,Av/i[hq,�IkillIVVA IhiitI�iq A 'A I I iml,mmd I'oi. OliiaiflOy 1 "Mai 1 2022/05/02 11:11:19 Page 4 o1 149 k dmmIV 1, 4)n,Av/i[hq,�IkillIVVA IhiitI�iq A 'A I I iml,mmd I'oi. OliiaiflOy 1 "Mai 1 2022/05/02 11:11:19 Page 5 of 150 k dmmIV 1, 4)n,Av/i[hq,�IkillIVVA IhiitI�iq A 'A I I iml,mmd I'oi. OliiaiflOy 1 "Mai 1 2022/05/02 11:11:19 Page 6 of 151 . . ... .. .... 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"Mai ,Irl Ik, IT I, � 1\41 111 (,4)nd Vi[k I, 7,� I I a I I I IVA C Hili( kiq AC'A I I iml,mmd I (,I w 1.1 Ci— w w 0 CL 10. z w 0a To w -, 0 TO TO I Ty -5 cy OliniflOy I —_ D 8 cc F— Lij U) � 0 z 0 Gr x 0 z 0 90 2022/05/02 11:11:19 Page 10 ol 155 . . ... .. .... "Mai ,Irl Ik, IT I, � 1\41 111 (,4)nd Vi[k I, 7,� I I a I I I IVA C Hili( kiq AC'A I I iml,mmd I (,I OliniflOy I 2022/05/02 11:11:19 Page 11 o,156 . . ... .. .... , �g� I I "Mai 1 ,J,,I, Nmm� 1\41'i(,4)n,A\/ilhq,� I kill I IVAC Hiii( I ,lq AC'A I I iml,mmd I (,I OliniflOy I an m N 0N3 TINVd 1081.N00 LO CY) 2022/05/02 11:11:19 Page 12 ol 157 . . ... .. .... 'J"l, Nmm� VW1,,4)n,A\/i[hq,� I kill I IVAC Hiii( I �iq AC'A I I iml,mmd I (,I Olinilk(y 1 "Mai 1 NEOPRENE ISOLATOR DIMENSIONS r, 6 1/4" .................................................................................. 1 5/8" 2 3/4" 3/8" 1 .............................................................................................. [ 2022/05/02 11:11:19 Page 13 ol 158 I . ... .. .... "Mai ,Irl N I, I U, � 1\41 1 '1 (,L4), d \/I I hq, � I h I I I IVAC )m( klq AC'A I 111pmwd I (,I Ommk(y I GLA"IF DE I 111p ISO ,111 C(i ----------- ------ RIC I 1 11 a ISE .101 I B�CIW ENS TPUIOP "OISE REMIC1REL- HEAT R -P EN DUAL-1-011 SSLT�lf "I ARY LIPUT CLASS I FIELD VVIRMG RE JJOW —,TOR /J iMPERS .11 -IS - IF HE 'I LEE AAE PRESEfJT 111 LOT EXTERNALALITOSTOP VVI ......... �1_1 JLI 1111 A 11 AL ITS P 1,111 14 OF VIC EMERGENCYSTOP > E 'If I— STOP -------- ----- ---- DZ_ IN A C _ I M VTLTAGf. S[Ij APY HPUT SPH OR 220— , 5011Z 10H 12 20A —il� USE SIZE CONTROL EUBPAINE L GND E IAPOFAF OfF ISIFIER 'TEMPE'RAT'URE. CONTROL .`:'-VV ITCH AND LN LiERS10 11 11 CIE AS G0111 NOT PA EL SLID H 11 G 1 1EV6oHZ I PA ER 22`V FFLI 6 'PH f)MAYFUSE SIM MITI Pil IHI OPTIONA _X FUTET'ISE V�LTHOLIT PUMP OPTION�_p _ .................... CLASS 1 FIELD WIRNfG CLASS 1 FIELD `R'S CUSTOMER SUPPLIED INC6PVOLTAGE C17KE] SHE UNIT HALEPLAFTE 2022/05/02 11:11:19 Page 14 of 159 10 MODELS OR SACNET E,l If LD ITITEFFACE CONTROL R15PANEL SHIP COED TI I OPI EI R LE RDS SPH OR 220— , 5011Z 10H 12 20A —il� USE SIZE CONTROL EUBPAINE L GND E IAPOFAF OfF ISIFIER 'TEMPE'RAT'URE. CONTROL .`:'-VV ITCH AND LN LiERS10 11 11 CIE AS G0111 NOT PA EL SLID H 11 G 1 1EV6oHZ I PA ER 22`V FFLI 6 'PH f)MAYFUSE SIM MITI Pil IHI OPTIONA _X FUTET'ISE V�LTHOLIT PUMP OPTION�_p _ .................... CLASS 1 FIELD WIRNfG CLASS 1 FIELD `R'S CUSTOMER SUPPLIED INC6PVOLTAGE C17KE] SHE UNIT HALEPLAFTE 2022/05/02 11:11:19 Page 14 of 159 . . ... .. .... 'J"l, Nmm� \l1111,,4)n,A\/iLhq,� I kill I IVAC I)iii( I �iq AC',A I I iml,mmd I (,I Olinink(y 1 "Mai 1 TO NEXT JNH [=To> SHIELD CONTROL SUBPANEL. GND I I CLASS FIELD WIRING L------------------------------------------ SHIELDED TWISTED PAIR LEADS ------------ u A 2022/05/02 11:11:19 Page 15 ol 160 f f 1 [7- + 6 + + G + G 24 �24 DC VDC L Pi LINK._____) P,L - -----J L- I m c ----j ............ (BACK ET ....... M ODBU s ............. MACHINEBUS --------------------------------- l PC 1 SY M BI 0 900 U fq CON TROT L E R SERVICE I (N.A. -- u SB ETHERNET L...1..........._2 I 3 I 4 L...'..... 1 I 2 2022/05/02 11:11:19 Page 15 ol 160 k dmm,, v411'i, )ndv/i[hq,� I kill FIVEv( Ihiit I,iq A `A I I it 1 mmd I'oi. C1i..iaifl Oy 1 "Mai 1 GENERAL NOTES: 1. WIRE REPRESENTED BY DASHED LINES INDICATE RECOMMENDED FIELD WIRING BY OTHERS. 2. ALL STANDARD AND OPTIONAL COMPONENTS SHOWN. \J SINGLE SOURCE POWER IS PROVIDED AS STANDARD ON THIS PRODUCT. FIELD CONNECTIONS ARE MADE TO DEVICES 1Q1 OR 1X1. 4. ALL MOTORSARE PROTECTED FROM PRIMARY SINGLE PHASE FAILURES, 5. CAUTION - TRANE PUMP CONTROL MUST BE USED TO PROVIDE PUMP CONTROL, EVAPORATOR CHILLED WATER PUMP MUST BE CONTROLLED BY THE CHILLER OUTPUT. FAILURE TO COMPLY WITH THIS REQUIREMENT MAY RESULT IN DAMAGE TO THE UNIT. 6. CAUTION - DO NOT ENERGIZE THE UNIT UNTIL CHECK OUT AND STARTUP PROCEDURES HAVE BEEN COMPLETED. WIRING REQUIREMENTS: 7. ALL FIELD WIRING MUST BE IN ACCORDANCE WITH THE NATIONAL ELECTRIC CODE (NEC), STATE AND LOCAL CODES. 8. DO NOT RUN LOW VOLTAGE CONTROL WIRING (30V OR LESS) IN CONDUIT WITH 110V OR HIGHER WIRING. DO NOT EXCEED THE FOLLOWING MAXIMUM RUN LENGTH FOR A GIVEN SIZE: 14 AWG OF 5000 FT, 16 AWG OF 2000 FT OR 18 AWG OF 1000 FT. ALL UNIT POWER WIRING MUST BE 600V COPPER CONDUCTORS ONLY AND HAVE A MINIMUM TEMPERATURE INSULATION RATING OF 90 C. REFER TO UNIT NAMEPLATE FOR MINIMUM CIRCUIT AMPACITY AND MAXIMUM OVERCURRENT PROTECTION DEVICE. PROVIDE AN EQUIPMENT GROUNDING IN ACCORDANCE WITH APPLICABLE ELECTRIC CODES. REFER TO WIRE RANGE TABLE FOR LUG SIZES. 10 SHIELDED, TWISTED PAIR LEADS ARE REQUIRED FOR CONNECTIONS TO THE COMMUNICATIONS INTERFACE MODULES (1K1 OR OPTIONAL 1K6). THE SHIELD SHOULD BE GROUNDED AT THE UNIT CONTROL PANEL END. C11 22 AWG SHIELDED COMMUNICATION WIRE EQUIVALENT TO HELIX LF22PO014216 IS RECOMMENDED FOR WIRING TO NEXT UNIT. THE SUM TOTAL OF ALL INTERCONNECTED CABLE SEGMENTS ARE NOT TO EXCEED 4500 FT. CONNECTION TOPOLOGY SHOULD BE DAISY CHAIN. REFER TO BUILDING AUTOMATION SYSTEM (BAS) COMMUNICATION INSTALLATION LITERATURE FOR END OF LINE TERMINATION RESISTOR REQUIREMENTS. 12 ALL CUSTOMER SUPPLIED CONTROL CIRCUIT WIRING MUST BE COPPER CONDUCTORS ONLY AND HAVE A MINIMUM INSULATION RATING OF 300V. EXCEPT AS NOTED, ALL CUSTOMER WIRING CONNECTIONS ARE MADE TO CIRCUIT BOARD MOUNTED BOX LUGS WITH A WIRE RANGE OF 14 TO 18 AWG OR TO DIN RAIL MOUNTED SPRING FORCE TERMINALS. CONTACT RATINGS AND REQUIREMENTS: 13 UNIT PROVIDED DRY CONTACTS FOR THE CONDENSER/ CHILLED WATER PUMP CONTROL. RELAY CONTACT RATINGS AT 120VAC: 7.2A RESISTIVE, 2.88A PILOT DUTY, OR 113 HP, 7.2 FLA. CONTACTS ARE RATED FOR 240VAC, 5A GENERAL PURPOSE DUTY. 1K16 IS NOT PRESENT WITH PUMP PACKAGE OPTION. 14 CUSTOMER SUPPUED CONTACTS FOR ALL LOW VOLTAGE CONNECTIONS MUST BE COMPATABLE WITH DRY CIRCUIT 24VDC FOR A 12mA RESISTIVE LOAD. SILVER OR GOLD PLATED CONTACTS ARE RECOMMENDED. 18 WHEN ICE MAKING OPTION SELECTED, DEFAULT RELAY SETTING WILL BE REPLACED WITH "ICE MAKING COMPLETE" OUTPUT FUNCTION. 2022/05/02 11:11:19 Page 16 01 161 k dmmim v411'�4)n Vi[hq,�Ih11IVVA IhiitI�iq A 'A I ri I it 1 mwd I'(,I C1iinilk(y 1 "Mai 1 Foundation Provide rigid, non -warping mounting pads or a concrete foundation of sufficient strength and mass to support the applicable operating weight (i.e. including completed piping, and full operating charges of refrigerant, oil and water). The expectation of Trane equipment is that piping is fully supported by an independent structure/system, without being connected to the waterbox. Once in place, the unit must be level within 1/2" across the length and width of the unit. The Trane Company is not responsible for equipment problems resulting from an improperly designed or constructed foundation. Center of Gravity Different unit configurations and options may cause a variation in the center of gravity from what is listed in the submittal. Refer to the Installation, Operating and Maintenance manual for specific lifting instructions. General Units are leak and pressure tested at 650 psig high side, 495 psig low side, then evacuated and charged. All Air-cooled chillers are factory tested to confirm operation prior to shipment. Standard power connections include main three phase power to the compressors, condenser fans and control power transformer. Note: A separate field supplied low voltage power source is required to power the evaporator freeze protection. Unit panels, structural elements and control boxes are constructed of galvanized steel and mounted on a bolted galvanized steel base. Unit panels, control boxes and the structural base are finished with a baked on powder paint. Anytime water only is present in the evaporator, the Trane Symbio (TM) 800 controller must have flow control of the chilled water system. Flow control can be done either directly or through an input to a building automation system to conduct an action resulting in minimum flow through the chiller evaporator barrel to avoid potentially catastrophic damage to the evaporator due to freezing. If the system has sufficient glycol to protect down to the lowest expected ambient, flow control is optional. Factory Refrigerant Charge (R410A) Packaged units ship with a full operating charge of oil and R41 OA refrigerant. Compressor and Motor The unit is equipped with two hermetic, direct -drive, 3600 rpm 60 Hz suction gas-cooled scroll compressors per circuit. The simple design has only three major moving parts and a completely enclosed compression chamber which leads to increased efficiency. Overload protection is internal to the compressors. The compressor includes: centrifugal oil pump, oil level sight glass and oil charging valve. Each compressor will have compressor heaters installed and properly sized to minimize the amount of liquid refrigerant present in the oil sump during off cycles. Unit -Mounted Starter The control panel is designed per UL 1995. The starter is an across -the -line configuration, factory - mounted and fully pre -wired to the compressor motor and control panel. A factory -installed, factory - wired control power transformer provides all unit power. A molded case standard interrupting capacity circuit breaker, factory pre -wired with terminal block power connections and equipped with a lockable external operator handle, is available to disconnect the chiller from main power. Short Circuit Current Rating (SCCR) A short circuit current rating offers a measure of safety for what the starter panel enclosure is able to withstand in the event of an explosion caused by a short circuit. Short circuit current rating of 10kA is provided. 2022/05/02 11:11:19 Page 17 01 162 kl dmmim Iv41l'�4)n;tVi[hq,�Ih1lINA IhiitI�iq A 'A I ri I it mmd I'(,I C1iinilk(y 1 "Mai 1 Evaporator Braze plate heat exchanger is made of stainless steel with copper as the braze material. It is designed to withstand a refrigerant side working pressure of 430 psig (29.6 bars) and a waterside working pressure of 150 psig (10.5 bars). Evaporator is tested at 1.1 times maximum allowable refrigerant side working pressure and 1.5 times maximum allowable water side working pressure. It has one water pass. A water strainer and a flow switch are factory installed. Immersion heaters protect the evaporator to an ambient of -4.0 F. All evaporators have grooved pipe connections. The evaporator is covered with factory -installed 0.75 inch (19.05 mm) Armaflex II or equal (k=0.28) insulation. Foam insulation is used on the suction line. Unit is designed for operation in standard leaving evaporator temperature greater than or equal to 40.0 F. Condenser Air-cooled microchannel condenser coils use all Long Life Alloy aluminum brazed fin constructions. Each slab is split horizontally into separate condensing and sub -cooling coils that are connected by either a copper tube or received tank. The maximum allowable working pressure of the condenser is 650 psig (44.8 bars). Condensers are factory proof and leak tested at 650 psig (44.8 bars). Direct -drive vertical discharge condenser fans are balanced and individually protected. Three-phase condenser fan motors with permanently lubricated ball bearings and external thermal overload protection are provided. Units start and operate from 32.0 F to 115.0 F. Refrigerant Circuits and Capacity Modulation The unit has dual refrigerant circuits. Each refrigerant circuit has Trane scroll compressors piped in parallel with a passive oil management system. A passive oil management system maintains proper oil levels within compressors and has no moving parts. Each refrigerant circuit includes filter drier, electronic expansion valve, liquid line and discharge service valves. Capacity modulation is achieved by turning compressors on and off. The unit has four capacity stages. Unit Controls All unit controls are housed in an outdoor rated weather tight enclosure with removable plates to allow for customer connection of power wiring and remote interlocks. All controls, including sensors, are factory mounted and tested prior to shipment. Microcomputer controls provide all control functions including startup and shut down, leaving chilled/hot water temperature control, evaporator flow proving, compressor staging and speed control, electronic expansion valve modulation, condenser fan sequencing and speed control, anti -recycle logic, automatic lead/lag compressor starting and load limiting. The Symbio (TM) 800 unit control module, utilizing Adaptive Control microprocessor, automatically takes action to avoid unit shut -down due to abnormal operating conditions associated with low refrigerant pressure, high condensing pressure, Should the abnormal operating condition continue until a protective limit is violated, the unit will be shut down. Unit protective functions of the Symbio (TM) 800, include loss of chilled water flow, evaporator freezing, loss of refrigerant, low refrigerant pressure, high refrigerant pressure, high compressor motor temperature, and loss of oil to the compressor. The display is outdoor capable including an UV resistant touchscreen with removable cover. 2022/05/02 11:11:19 Page 18 o1 163 kl dmmim Iv41l'�4)n;tVi[hq,�Ih1lINA IhiitI�iq A 'A I ri I it mmd I'(,I C1iinilk(y 1 "Mai 1 Communications BACNet Interface allows the user to easily interface using BACNet MS/TP via a single twisted -pair wiring to a factory -installed and tested communication board. The pump offering can be for applications that have short water loops, de -coupled systems or for applications where the integrated chiller pump could serve the entire loop volume. Pump Package Performance: Because the fluid distribution system beyond the chiller is unknown, Trane Select Assist reports Available Head as the head leaving the brazed platee evaporator. Head leaving the evaporator includes the evaporator head loss, pump package piping frictional effects head loss, valve head loss, and strainer head loss summation. The pump package should not be operated at NPSHR. Operation a this suction head will cause cavitation. NPSHA should be at least 1.5 and 2.5 times NPSHR. Pump Pump package includes: two pumps, drainage valve, shut-off valve at entering and leaving connections. The pump package is single point power integrated into the chiller unit power with a separate factory wired control panel and separate power for freeze protection. The control of the pump is integrated into the chiller controller. The CH530 displays evaporator pump starts and run-times. Freeze protection down to an ambient of -29°C (-20°F) is included as standard. The cold parts of the pump package will be insulated. Designed with one redundant pump, it is controlled to operate both pumps through a lead/lag and failure/recovery functionality. Architectural Louvered Panels Louvered panels cover the complete condensing coil and service area beneath the condenser. Isolators Molded elastomeric isolators, sized to reduce vibration transmission to the supporting structure when the unit is installed, ship with the chiller. 2022/05/02 11:11:19 Page 19 01 164 7J Available Head (ft) = Total Pump Head - jEvap Head Loss+PlpJnq Head Losses+Valve Head LosswStraliner Head Loss) 165 Rm 06"flO1401, Item O"Crip6o" I 01"CIAP"Oft • Pump package performance. .. ... ............. ..... ... ... ... ... ... P p W "Oe "W' E W ... ... 6 PrOv11,,IIIPW,.rVI4. f " 'p P'Saf To""p swm Because the fluid distribnfion system .......... .................... beyond ffie ch iNer is unknown, I cane 'I WAIII SO&I'le, 7 WIHE' uale To,np Se,w Select Assist repods 3 D— U- ff AM P1111,10 N,,Oct AvaHable Head as the head leaving the 4 VaN* for PIftT'ur* N"": wV.Ne brazed plate evaporator. Head leaving V pwv, u,71"', k 0 r4all"I(A" Weed the evapmator Ocludes, the evaporator head loss, pump package piping frictiorW effects head losses, valve head losses, and strainer head loss surnmation. The pump pat"ge shoWd not be oporaled at NPSHrq. Operadlon at this suction head MH cause cavitation. Nd SHA shrAkld be at West 1.5 to 2.5 finies NFISHa 165 iRTU-1 (OPTION 2) Y.iWliitity I �i,js fVVl.l 101,,1 ,k dmne:A�It I'i�,�x, rt V/ifln�7E Vall FiVIVf) Trane Performance Climate Changer Air Handler Outdoor unit CSAA030 67.7 in 93.5 in 215.7 in 5786 Ib 5280 Ib 1 piece(s) 67.7 in 93.5 in 215.4 in 5402 Ib Airflow 14200 cfm Total,Siati�6 Pressure ; 5.113 in H2O Note: Height includes air handler sloped roof panel and standing seam. IIIIIIIII VIII ud�Vl uiuudul I�Illlulll IIII IIII I uul�ul�uu'8° °'" uiil ui�l uuuulou II IIII IIII Panel 2in. foam injected R-13 with thermal break Panel, All unit inneranels - j p >rr,w Material galvanized Integral, 6in. integral base frame�� tiv Rase Frame PaintSlate gray loss$ A �r Short' Circuit 5 kA " ^w Current Rating 'gym„,�n Agency UL listed unit Approval l Raof Curb' Standard roof curb Type. 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 27.22 A 33.97 A 60.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu ii uu li uu IIIIII Vu U UU IIIIII IIIII1III IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 14200 cfm 1179 ft/min 12.04 sq ft 0.240 in H2O Yes damper Bottom Return Parallel blade 14200 cfm 1179 ft/min 12.04 sq ft 0.110 in H2O N/A damper Pleated media - MERV 8 2” MERV 8 18.00 16in.x20in. 6.00 16in.x25in. Pressure Drop/,/,/"/,/,/"/,, Condition, Fadevolocity Airflow Area 0.556 Mid-life 251 ft/min 14200 cfm 56.67 sq ft I I Ii1 i1 I1 1 11 Il 1 I IJ 1 Door Location Right 166 2022/05/09 13:58:39 Page 1 of 28 Product Version: 1 i'ANS« `�u;0+� � � ,k I I dein¢!: IA1l I'i� �,Ixyi;tV/ifln�iE� I Vall FiV6��AC; Chilled water - 3U 6 3/8in. tube diameter (9.5 mm) Standard .012" (0.305 mm) copper tubes 84 Per Foot l:ivai dilly I T�3(Is lV Ill I 01,t1 Total 527.52 MBh $erisiblo 372.81 MBh Air Fluty 14200 cfm 80.00 F Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I i 1 1! 1 ! 1 1J J 1 J J 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ill �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I �'l �l �'�llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ill Wheel Diatfietef/TypeJ,O) $ 27in. dd plenum, full width, H press PowerA Fan 20 hp FonQuantity�, 1 Voltage 460/3 Discharge Location Front top SRp r 1800 Motor Location Right side drive glass NEMA premium compliant ODP Blades i Higher eff.(some bands lower,more Efficiency's 93.18% spike) Part Load Efficiency, 88.82% Drivo Service�UJFF�a�JJJctor � Direct drive Fan � Fan electrical pou)rgi�„(FEt�, 13.01 kW f�ilRilllll��l��lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll�� AHRLVFD,HP 20.000 hp A4116wi 14200 cfm Wire to air,, static efficiency 65.50% Total Static Pre sure 5.113 in H2O Total Brake Dower 15.751 hp Operating Spp 1792 rpm Total Brake HP 15.751 hp AMCA FEG FEG85 Bane fan peak total efficiency 76.70% Unit Static Efficiency; 72.67% IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYI"��II'��1��r Selection Type, VFD w/ bypass Voltage, 460/3 Mounting Location Internal mounting VFD Frerttaenov 61.00 Hz Note: VFD driven motor fan electrical power calculated in accordance with AHRI 430. fan IAIreel Blnce Inverter balance with shaft grounding DoorLocationRight Door Guard Yes Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 13:58:39 Product Version: 1 Page 2 of 28 167 e\umln WINE i,js ia' illy f ,k k'ITvr. A41 I'I( 4)nd V/I[hq'� I h I I I NAC Air mixing section 0.99 Coil section 0.55 Fan section 0.03 Diffuser section 0.08 Gas heat 0.97 Internal Static Pressure 2.61 Air Pressue Drop 0.080 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 14200 cfm 45.00 F 68.05 F 450.00 MBh 360.00 MBh ilmum Gas Inlet Maximum 4as Inlet Min temp rise at, Max temp 6§6 ee at �� ABH Pres ure Pressure selected airflow selectedialrflw4 7.000 in H2O 14.000 in H2O 3.39 F 23.05 F 53.00 MBh 2022/05/09 13:58:39 Page 3 of 28 168 Product Version: 1 ui - T J \ J uj y y ✓r N 15 'oSco o m T t�t� o t. (. t. LU 111 U"1 4d� U) p q y O 1] NS! sc W.�n� X X X X p'M�� 3 d aN4'1 aqi GN N v'O ;O 'O ;4 ui ma=�oo via �mmwmmc6s a-� $mroo�I-z 4) 0 wmUa cOUM 0:55 0.oL LU LC �` K Ci uj cn7 m oo .....................pq m---=-------------------------------------------------------- m a v w c E g ui vLL M c m m ri m W '4 = C LL � 'L C 5 O L /J CL LO <V Q L N ¢ P M LL U O _cLU r O p coo) 01 0- LU U �> r d r r N C3 __� _ m O 9 Z m w e U� Q r G E v w s LL N *y N C C ^mA O .— LO C p GO O m >, Q co O 'n N iJ o N N uj w �O RTU 2 (OPTION 2) ,/\A iauaiitity I .k dmne:A�It I'i�,�,r, rt V/ifln�7E Vall FiV/Vf) Trane Performance Climate Changer Air Handler Outdoor unit � CSAA025 67.7 in 80.0 in 214.5 in 5373 Ib �HeIght Wi'dthl Length 1 piece(s) 67.7 in 80.0 in 214.3 in 5025 Ib Airflow '' 13500 cfm Total,Siati�6 Pressure ; 5.373 in H2O Note: Height includes air handler sloped roof panel and standing seam. VIII � III ul uul ud�Vl uiuudui I�Illlmll uil' ui I uiu�ul�uuuu liiii Vial uiiuulou a uif uu Panel 2in. foam injected R-13 f with thermal break Panel All unit inner panels - Material galvanized Integral, 6m. integral base frame Base Frame Palnt; Slate gray a r t t; Short' Circuit Current 5 kA Rafing Agency UL listed unit Approval R61of Curt5 Standard roof curb TyP 4948 Ib 110, 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 27.22 A 33.97 A 60.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu ii uu li uu IIIIII Vu U UU IIIIII IIIII1III IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 13500 cfm 1303 ft/min 10.36 sq ft 0.297 in H2O Yes damper Bottom Return Parallel blade 13500 cfm 1303 ft/min 10.36 sq ft 0.142 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 18.00 Pressure Drop Condition Face Velocity Airflow 0.563 Mid-life 270 ft/min! 13500 cfm 1 11 I I III I�I�9111111110M Door Location = Right 2022/05/09 13:58:39 Product Version: 1 16in.x25in. Area 50.00 so ft 170 Page 1 of 28 WNE« `�u;0+� � � ,k I I dein¢!: IA1l I'i� �,Ixyi;tV/ifln�iE� I Vall FiV6��AC; Chilled water - 3U 4 3/8in. tube diameter (9.5 mm) Standard .012" (0.305 mm) copper tubes 120 Per Foot l:ivai dilly I T�3(Is lV Ki Y Ol,G1 Total 331.00 MBh Sensible 285.46 MBh Air Flow 13500 cfm 80.00 F Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I i 1 1! 1 ! 1 1J J 1 J J 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ill �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I �'l �l �'�llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ill Wheel Gliafneter/Type/Class 27in. dd plenum, 80% width, H Powlil Fan 20 hp press Voltage, 460/3 Fan Qwantity 1 Spoe�l1800 Discharge Location Front topiass C NEMA premium compliant ODP Motor Location Right side drive Effici6ncy93.17% Blades; Higher eff.(some bands lower,more Part Load Ef licikcy 89.02% spike) Driv6 ServiceyyFa))CtJJor' Direct dr))i))))))v))))))))))e)))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))) Fan electrical pou)rgi�„(FEI�;; 13.60 kW � � ��llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ° l IRllll� l Wire to aiStaticff c a cy 62.60%p we Airflow 13500 cfm Note: VFD driven motor fan electrical powercalculated in accordance with AHRI 430. Total Static w5.373 in H2O Power Po Total.. Brake Powec 16.466 hp Operating Speedy 1976 rpm Fan Wheel Balance Inverter balance with shaft Total Brake,HP 16.466 hp grounding Boar Location Right AMCA FEG FEG85 Door Guard Yes Bare fan peak,tota� etiFlclgfry; 76.70% Unit Staltic Efficiecv 69.45% VFD w/ bypass 460/3 Internal mounting 67.00 Hz Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 13:58:39 Page 2 of 28 171 Product Version: 1 e\umln WINE i,js ia' illy f ,k k'ITvr. A41 I'I( 4)nd V/I[hq'� I h I I I NAC Air mixing section 1.16 Coil section 0.56 Fan section 0.03 Diffuser section 0.08 Gas heat 1.04 Internal Static Pressure 2.87 Air Pressue Drop 0.083 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 13500 cfm 45.00 F 66.55 F 400.00 MBh 320.00 MBh ilmum Gas Inlet Maximum 4as Inlet Min temp rise at, Max temp 6§6 ee at �� ABH Pres ure Pressure selected airflow selectedialrflw4 7.000 in H2O 14.000 in H2O 2.15 F 21.55 F 32.00 MBh 2022/05/09 13:58:39 Page 3 of 28 172 Product Version: 1 ui - T uj 15 J �\ J N _ a G ro ..� 'd LLLL 1�yy EE LLLL LUj E -d r•E-d tinZmxm33>p m C9 u�iwwx�a UMC�1 .-ro6 u�'ida�S:-O��Oa'Q p�woM LL p�� ^fid LC �` K Ci uj 7 �^-+aa -------------------- 47 ________ aJ N co M lfY III,.---------- m t n F M � � p y C a 0 0 a 3 p5 ❑ U p LL Q O RtlOLU LU LU U _ > C N O }*w N ......' plpyy > Q O / � d o N �ya 5E O U E c O 1111 pb®q Z m w BE ti� a c � � v w m `o LL *y N C C LO C p GO N O Upi N L51 cl, (6 N U) uj Q. D a — a ti m RTU-3 (OPTION 2) ait ty t i],js ,k d"�iner.A�11 I'i�,�xc;l V/ill�u7E Vrll FVV{Vf:, T�3��s A[ VCJ'f (lp(" T Trane Performance Climate Changer Air Handler Outdoor unit CSAA014 47.7 in 72.0 in 198.8 in 4050 Ib 3690 Ib 1 piece(s) 47.7 in 72.0 in 198.5 in 3731 Ib Airflow '' 7500 cfm Total,Siati�6 Pressure ; 5.442 in H2O Note: Height includes air handler sloped roof panel and standing seam. I ul uiu ud�Vl uiuudui I�Illluill uil ui I uiu�ul�u a lilil ui�l uiiuulou a uif ilii I 2in foam injected R-13 Panel with thermal break Panel All unit inner panels - O Material galvanized) Integral, 6in. integral base frame Rase Frame Paint Slate gray Short Circuit 5 kA Current��>��^^ Rating; Agency UL listed unit Allproval R61of Curt5 Standard roof curb TyP 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 21.22 A 26.47 A 45.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu ii uu li uu IIIIII Vu U UU IIIIII IIIII1III IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 7500 cfm 1325 ft/min 5.66 sq ft 0.342 in H2O Yes damper Bottom Return Parallel blade 7500 cfm 1325 ft/min 5.66 sq ft 0.226 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 4.00 20in.x20in. 2.00 20in.x25in. Pressure Drop/,/,/"/,/,/"/,, Condition; Facevolocity Airflow Area 0.616 Mid-life 415 ft/min 7500 cfm 18.06 sq ft i I1 1 11 Il 1 I IJ 1 Door Location Right 174 2022/05/09 13:58:40 Page 1 of 28 Product Version: 1 i'ANS« `�u;4+� � � ,k I I dein¢!: IA1l I'i� �,Ixyi;tV/ifln�iE� I Vall FiV6��AC; Chilled water - 3U 4 3/8in. tube diameter (9.5 mm) Standard .012" (0.305 mm) copper tubes 114 Per Foot l:ivai dilly I T�3(Is lV Ill "f 01,G1 Total 238.00 MBh $erisiblo 177.92 MBh Air Fluty 7500 cfm 80.00 F Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I i 1 1! 1 ! 1 1J J 1 J J 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ill �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I �'l �l �'�llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ill Wheel DlaliteteC/TypeJ,OJaej$ 20in. dd plenum, full width, M press Power,1 Fan 15 hp FonQuantity�, 1 Voltage 460/3 Discharge Location Front top Ae 1800 Motor Location Right side drive glass NEMA premium compliant ODP Blades i Higher eff.(some bands lower,more Efficiency93.45% spike) Part Load Efficikrrcy, 88.46% Drivo Service�UJFF�a�JJJctor � Direct drive Fan � Fan electrical pou)r��„(FEt�, 8.54 kW f�ilRilllll��l��lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll�� AHRLVFD,HP 15.000 hp A4116wi 7500 cfm Wire to air,, static efficiency 56.10% Total Static Pre sure 5.442 in H2O Total Brake Dower 10.271 hp Operating Spe 2491 rpm Total Brake HP 10.271 hp AMCA FEG FEG85 Bane fan peak total efficiency 75.40% Unit Static Efficiency; 62.65% IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIYI"��II'��1��r Selection Type, VFD w/ bypass Voltage, 460/3 Mounting Location Internal mounting VFD Frerttaenov 84.00 Hz Note: VFD driven motor fan electrical power calculated in accordance with AHRI 430. fan IAIreel Blnce Inverter balance with shaft grounding DoorLocationRight Door Guard Yes Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 13:58:40 Product Version: 1 Page 2 of 28 175 m An WINE T: i,j ' /\[lly t A� �� ,k k'ITvr V41 I'I( 4)nd V/I[hq'� I h I I I NAC T�3��s lVf T Air mixing section 1.25 Coil section 0.60 Fan section 0.03 Diffuser section 0.14 Gas heat 0.92 Internal Static Pressure 2.94 Air Pressue Drop 0.139 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 7500 cfm 45.00 F 83.79 F 400.00 MBh 320.00 MBh ilmum Gas Inlet Maximum 4as Inlet Min temp rise at, Max temp 6§6 ee at �� ABH Pres ure Pressure selected airflow selectedialrflw4 7.000 in H2O 14.000 in H2O 3.88 F 38.79 F 32.00 MBh 2022/05/09 13:58:40 Page 3 of 28 176 Product Version: 1 ui r h4 J uj y w a wx M }. y X1p5i5 i5 � t .... GLaU O. m010101 '*i 'p°pBm��tl� x M M � W x sG '"at��aGiG a$ E•o u�Enr-$Z a� v, $3333 19u�,wcoDa aiOUr=i �.—�a r°'i©acNv2rO d ©�a7 C'ch LL LU LC K Ci uj cn7 O LO ___._._ _._._._._.__ _._._._._._._._._._.____ M ____ M q C) ---- --- ' cpn cLL c 7 y � o � N 0 c ZCU = .3 p5 U O Q O CL N ^A.i 'e, � M x v ,.,.,., o„o f�+ o0- 9 co m O Z 7 N p ---- - --- ------------------ - q co 0 ^ggpp W 4 M LL ~ .L Q r G C N LLL *y a) C C Q p (O0 O Co >, �i a a 0co a N U) uj Q. mo a — a OPTION RTU -4 ,AA 7rit,,xuvv.:,` .1uaiif ty I T�3��c A[ M 'I (llrt' .k k,ITI,> Alt 1'i( 4) not V/i[kI,7,� I Vall I iVI��AC Trane Performance Climate Changer Air Handler Outdoor unit CSAA017 55.2 in 72.0 in 194.4 in 4089 Ib 3720 Ib 1 piece(s) 55.2 in 72.0 in 194.2 in 3773 Ib Airflow 7800 cfm Total,SiatiT6 Pressure ; 5.024 in H2O Note: Height includes air handler sloped roof panel and standing seam. IIIIIIIII VIII ud�Vl uiuudul I�Illlulll IIII IIII I uul�ul�uu'8° °'" uiil ui�l uuuulou II IIII IIII Pone'l 2in. foam injected with thermal R-13 beak Panel All unit inner panels - heL galvanized 9 r;y4�ltA� Material Integral Base Framebin. integral base frame Palnt; Slate gray Short Circuit 5 kA Current Rat7ng. Agency UL listed unit Allproval R61of Curt5 Standard roof curb Tyle 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 14.22 A 17.72 A 30.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu 11 uu 11 uu IIIIII Vu U UU IIIIII IIIIIIIII IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 7800 cfm 1116 ft/min 6.99 sq ft 0.236 in H2O Yes damper Bottom Return Parallel blade 7800 cfm 1116 ft/min 6.99 sq ft 0.146 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 8.00 16in.x20in. 4.00 16in.x25in. Pressure Drop,_,",-,"_ Condition; Fadevolocity Airflow Area 0.563 Mid-life 270 ft/min 7800 cfm 28.89 sq ft i I1 1 11 Il 1 I IJ 1 Door Location Right 178 2022/05/09 13:58:41 Page 1 of 28 Product Version: 1 WNE« `�u;4+� � � ,k I I dein¢!: IA1l I'i� �,Ixyi;tV/ifln�iE� I Vall FiV6��AC; Chilled water - 3U 4 3/8in. tube diameter (9.5 mm) Standard .012" (0.305 mm) copper tubes 137 Per Foot l:ivai dilly I T�3(Is lV Ill /I Opt% Total 290.00 MBh Sensible 207.82 MBh Air Flow 7800 cfm 80.00 F Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I i 1 1! 1 ! 1 1J J 1 J J 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ill �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I �'l �l �'�llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ill Wheel Gliafneter/Type/Class 22.25in. dd plenum, full width, H Powlil Fan 10 hp press Voltage, 460/3 Fan Qwantity 1 Spoe�l1800 Discharge Location Front top Aass NEMA premium compliant ODP C Motor Location Right side drive Efficiency's 92.03% Blades; Higher eff.(some bands lower,more Part Load Ef licikcy 88.65% spike) Driv6 ServiceyyFa))CtJJor' Direct dr))i))))))v))))))))))e)))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))) Fan electrical pou)rgi�„(FEI�;; 7.78 kW � � ��llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll 0 hp l IRllll� l Wire to aiStaticff c a cy 59.12/° p we Airflow 7800 cfm Note: VFD driven motor fan electrical powercalculated in accordance with AHRI 430. Total Static w5.024 in H2O Po Power Total. Brake Powec 9.195 hp Operating Speedy 2006 rpm Fan Wheel Balance Inverter balance with shaft Total Brake,HP 9.195 hp grounding ©oar Location Right AMCA FEG FEG80 Door Guard Yes Bare fan peak,tota� e�Flcgfry; 71.10% Unit Static Efficiecv 67.19% VFD w/ bypass 460/3 Internal mounting 68.00 Hz Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 13:58:41 Page 2 of 28 179 Product Version: 1 e\umln WINE i,js ia' illy f Air mixing section 1.02 Coil section 0.54 Fan section 0.02 Diffuser section 0.08 Gas heat 0.86 Internal Static Pressure 2.52 Air Pressue Drop 0.076 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 7800 cfm 45.00 F 82.30 F 400.00 MBh 320.00 MBh ilmum Gas Inlet Maximum 4as Inlet Min temp rise at, Max temp 6§6 ee at �� ABH Pres ure Pressure selected airflow selectedialrflw4 7.000 in H2O 14.000 in H2O 3.73 F 37.30 F 32.00 MBh 2022/05/09 13:58:41 Page 3 of 28 180 Product Version: 1 I ui c h4 uj J y h -N NN LU pad �m v % —nmu�o-ar m a'cx �x m aci 8S m m-mm-,qnzw x- 83 3 C1 C7 inWmOaacn0M6.nvon"TV -4vd OrC°v�tlOcn LL L' N Met U") 4p Y•- W 6A O •— g�� r ^fid LC �` K Ci uj 7 N E vJ 00 p�qq Q - - o C7 a) a) z c M LL ppqq _ h m V Z M A pp .. 'N-' co p5 MO Q O Rtl w r E Q � o a H Of ........................................................ LU L) M — __ .,., M•, ___ d nod ai V d cD r E 0 Z m w Q) r E tt o. r c E v w a In m `o LL *y N LU C C ^nl O .— LO C p GO 0 Co >, uj OPTION ��pp ry� RTU -13 ,AA 14111� � rm 7rit,,,,x .:," ".1uaiitity I " a �� r A�'"6��`��4'n� T�3��c fVI VL1 � (llrt' , ,k k'ITI,> Alt 111 (�4)n,rt V/ifln,7'� I Vall IiVI��AC Trane Performance Climate Changer Air Handler Outdoor unit � CSAA021 59.0 in 80.0 in 201.9 in 4958 Ib �HeIght Wl'dthl Length 1 piece(s) 59.0 in 80.0 in 201.6 in 4616 Ib Airflow '' 10500 cfm Total, iatid Pressure ; 5.109 in H2O Note: Height includes air handler sloped roof panel and standing seam. I ul uiu ud�Vl uiuudui I�Illlmll uil ui I uiu�ul�u a lilil ui�l uiiuulou a uif ilii y Panel 2in foam injected R-13 with thermal break / ➢y' ri Panel All unit inner panels - Material galvanized Integral, 6in. integral base frame Base Frame r Palm; Slate gray Short' Circuit 5 kA Current Rafin�f�� Agency UL listed unit AI�Kgroval R61of Curt5 Standard roof curb TyP 4533 Ib 1101 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 21.22 A 26.47 A 45.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu 11 uu 11 uu IIIIII Vu U UU IIIIII IIIII1III IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 10500 cfm 1215 ft/min 8.64 sq ft 0.275 in H2O Yes damper Bottom Return Parallel blade 10500 cfm 1215 ft/min 8.64 sq ft 0.160 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 12.00 Pressure Drop Condition Face Velocity Airflow 0.579 Mid-life 315 ft/min! 10500 cfm 1 11 I I III I�I�9111111110M Door Location = Right 2022/05/09 13:58:41 Product Version: 1 16in.x25in. Area 33.33 so ft 182 Page 1 of 28 WNE« `�u;4+� � � ,k I I dein¢!: IA1l I'i� �,Ixyi;tV/ifln�iE� I Vall FiV6��AC; Chilled water- UW 4 1/2in. tube diameter (12.7 mm) Standard .016" (0.406 mm) copper tubes 105 Per Foot l:ivai dilly I T�3(Is lV Kir 01,G1 Total 302.00 MBh Sensible 237.93 MBh Air Flow 10500 cfm 80.00 F Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I i 1 1! 1 ! 1 1J J 1 J J 1 I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ill �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I �'l �l �'�llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll ill Wheel Gliafneter/Type/Class 24.5in. dd plenum, full width, H Powlil Fan 15 hp press Voltage, 460/3 Fan Qwantity 1 Spoe�l1800 Discharge Location Front top Aass NEMA premium compliant ODP C Motor Location Right side drive Effici6ncy93.32% Blades; Higher eff.(some bands lower,more Part Load EfficiOncy, 90.69% spike) Driv6 ServiceyyFa))CtJJor' Direct dr))i))))))v))))))))))e)))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))) Fan electrical pou)rgi�„(FEI�;; 10.74 kW � � ��llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll l IRllll� l Wire to aiStaticff c a cy 58.62%p we A:Hlow 10500 cfm Note: VFD driven motor fan electrical powercalculated in accordance with AHRI 430. Total Static w5.109 in H2O Power Po Total.. Brake Powec 12.937 hp Operating Speedy 1890 rpm Fan Wheel Balance Inverter balance with shaft Total Brake,HP 12.937 hp grounding Boar Location Right AMCA FEG FEG85 Door Guard Yes Bare fan peak,tota� etiFlclgfry; 76.70% Unit Staltic Efficiecv 65.37% VFD w/ bypass 460/3 Internal mounting 64.00 Hz Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 13:58:41 Page 2 of 28 183 Product Version: 1 e\umln WINE i,js ia' illy f Air mixing section 1.11 Coil section 0.46 Fan section 0.03 Diffuser section 0.07 Gas heat 0.94 Internal Static Pressure 2.61 Air Pressue Drop 0.075 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 10500 cfm 45.00 F 72.71 F 400.00 MBh 320.00 MBh ilmum Gas Inlet Maximum 4as Inlet Min temp rise at, Max temp 6§6 ee at �� ABH Pres ure Pressure selected airflow selectedialrflw4 7.000 in H2O 14.000 in H2O 2.77 F 27.71 F 32.00 MBh 2022/05/09 13:58:41 Page 3 of 28 184 Product Version: 1 ui - T J \ J uj y y U' 9Y � d w rTi L ,b; w d lU US 41 N 4? (p V W LU 9 V D ui w mm,�mmN zw Xrn $3 3 0aWmOaacn0 0.r5cpfmn�NS:-4vd ONCtlON L' N Met U") 40 h- W 6A O •- LL g�� r ^fid LC �` K 01 uj cn7 --------------------------- �..-------------------------- E co LO m N 0 LO / / W jj N o C7 3 E m m w O LL p� � N N N P � Z5 cooM A N Q i:b Z3 Ln a� e 'S z = 3 ppp5. U c .. o CO Q N E: p N O_1 0 rr d H NLUU m j � C, M:'S. o O O O i co 9 Z co 10 E N Qy N °Qco N o U1 LIL N N d r G p C In N LL N *y N C C ^mA LO C p GO O Co >, �i a N -Up p N cm N N t U) uj 2 co a —la- Y0 X) OPTION 3 PRELIMINARY EQUIPMENT CUT SHEETS 186 RTU -1 (OPTION 3) i.iumiitity I ,k k,ITvf Aat 1'i( 4)n,rt V/I[hq,� I h I I FiVAC Trane Performance Climate Changer Air Handler Outdoor unit CSAA030 67.7 in 93.5 in 215.8 in 5646 Ib 5261 Ib 1 piece(s) 67.7 in 93.5 in 215.6 in 5261 Ib Airflow 14200 cfm Total,Siati�6 Pressure ; 5.119 in H2O Note: Height includes air handler sloped roof panel and standing seam. IIIIIIIII VIII ud�Vl uiuudul I�Illlulll IIII IIII I uullul�uu'8° °'" uiil ui�l uuuulou II IIII IIII Panel 2in. foam injected R-13 r� with thermal break Panel, All unit inner panels - Material galvanized Integral, ral '�oHatirrt �Q��/ Base Feanmie bin. integral base frame Paint Slate gray 41r , i ro m W Short' Circuit 5 kA " ^w Current Rating Agency UL listed unit Approval l Raof Curb1 Standard roof curb Typa, Circuit number 1 Supply fan motor(s) 460/3/60 Circuit number 2 Gas heat 460/1/60 IIII III I T. UUUIUIUlu1u1u1u!u!u!wwwww..^- �� Controller Type No controller Warranty section Std. warranty only 0.00 ft 27.22 A 33.97 A 60.00 A 3.26 A 4.08 A 15.00 A Back Outside Parallel blade 14200 cfm 1179 ft/min 12.04 sq ft 0.240 in H2O Yes damper Bottom Return Parallel blade 14200 cfm 1179 ft/min 12.04 sq ft 0.110 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 18.00 16in.x20in. 6.00 16in.x25in. Pressure Drop Condition; Fade Volocity Airflow Area 0.556 Mid-life 251 ft/min 14200 cfm 56.67 sq ft 1 1 111 11 I1 1 11 Il 1 I IJ 1 Door Location Right 187 2022/05/09 12:01:52 Page 1 of 28 Product Version: 1 iaumel\n illy f WINE i,jsf\IV1 1 (llrt3 ,J, k,ITvr. A4111'1( 4)n,;i V/I[hq,� I {a11 I IVAC Refrigerant - 3F Capacity 6 Total 490.60 MBh 3/8in. tube diameter (9.5 mm) $elisibie" 329.70 MBh 3/8" Internally enhanced copper tubes Air 84 Per Foot Flow 14200 cfm Fin.MaterialAluminum fins Entering Dry Bulb 80.00 F Fin Type, Omega flo H (Hi efficient) Entering WetBul4, 67.00 F Fade Area 29.61 sq ft Leaving Dry Bulb, 58.85 F Grail (tep/single) H x L 52 in. (1321 mm) X 82" (2083 mm) finned length Leaving Wet Bulb 56.00 F Pressure Drop 0.555 in H2O Casing, Galvanized (Face Vefocityi 480 ft/min Rigging Weight 312.4 lb �lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll Type, R-41 OA Drain Pant Galvanized LiauidTemoerature 115.00 F Medium Suction Temperature 45.00 F Right Circuiting Type( Intertwined circuits 7.357 in Capacity Circuits Full circuiting 4.238 in IN6m4er of'Distribultors; 4 2.119 in AHRI 4 10 Classification' - Left AHRI 410 das ilffeation AHRI ACHC Certified Data Generation', Date 5/9/2022 Trane Select Assist update 2590 Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I i I I I. I I 1 I 1 IJ I 1 ! 1 J f IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII� Illllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll��>�>�1111111111111111111111111111111111111111111111111111111111111111111111111111111�1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111�16�rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr� Wheel Dlamr3ter/Type/Class, 27in. dd plenum, full width, H press Power Fan' 20 hp �FanQuantity 1 Voltage; 460/3 Discharge Location Front top Sneed 1800 Motor Location Right side drive Blades Higher eff.(some bands lower,more spike) Drive Service Factor ll Direct drive Airflow 14200 cfm Total Static Pressure, 5.119 in H2O Total Brake Power 15.788 hp Operating Speed, 1794 rpm Total,Braka,'HP, 15.788 hp AMCA FEG FEG85 Bare fair peeir,tS?te( efficirrey 76.70 Unit Static Efficiency; 72.58% VFD w/ bypass 460/3 Internal mounting 61.00 Hz NEMA premium compliant ODP 93.18% 88.83% 13.04 kW 20.000 hp 65.43% Note: VFD driven motor fan electrical power calculated in accordance with AHRI 430. Fan YUheel Balance' Inverter balance with shaft grounding Door Location Right Door Guard Yes Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 12:01:52 Page 2 of 28 188 Product Version: 1 iaumel\n illy f WINS i,jsf\IV1 1 (llrt3 ,k k'ITvr V4111'1( 4)nd V/I[hq'� I h I I I NAC Air mixing section 0.99 Coil section 0.56 Fan section 0.03 Diffuser section 0.08 Gas heat 0.97 Internal Static Pressure 2.62 Air Pressue Drop 0.080 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 14200 cfm 45.00 F 68.05 F 450.00 MBh 360.00 MBh iimurni Gas Inlet ' Maximum. Gas Inlet Min temp rise at Max terrip rise at Min MBH Pressure Pressure, selected airflow elected,alfflow_:� 7.000 in H2O 14.000 in H2O 3.39 F 23.05 F 53.00 MBh 2022/05/09 12:01:52 Page 3 of 28 189 Product Version: 1 ui - T J \ J uj y y ✓r N 15 'oSLo p m T t�t� o 47 U"1 47 Ln pqy O 1] NS! sc W.�n� X X X X p'M�� 3 d a N 47 a Q'O ;O 'O ;4 ui �owa�i �'wm m�mmro 0 wmUa cOUM 0:55 0.a L LU LC �` K Ci uj cn7 N cq y� Lo in 0 co L(7 m co co L m ------"' ..- ---"` 10 � 'ill v ((w v co o 7t 7t w LL of co c M L� N Q � a i$m z P ZT z 3 C2 U o d i 'E O N o D a H Of m WA m gguuy° _ cm Cd °r N mg N f M f N U _ Q O O CS 7 N� C C co ----- --- -Y�-. _ .....1 --- ------ --------- -' 9 m O co w N C -a 7 N m ° 0 (n LL Q r G E v w L LL N *y N C C ^mA Q C p GO is O m >, �i ii O N M N coo N uj Job f kim, MiiTnio CM 0113 1 19r pF'ir d I" (n CJ,i.i misty I CU -1 (OPTION 3) Condensing unit -Air cooled 40 ton 2482.0 Ib 3120.0 Ib 46.69 kW 0.00 ft 460/60/3 Unit disconnect switch (nonfused) 1.80 A 4.00 Each 3.53 kW Suction service valve R41 Da 95.00 F Standard ambient control 11.7 EER 87.00 A 100.00 A 100.00 A 18.60 A 4.00 Each 0.00 A 0.00 Each 43.16 kW Standalone RAUJ Condenser 545.43 MBh 45.00 F 124.84 F 105.07 F Liquid, Line Size 5/8 in. Refrlgeriant/Char',g (ho ovap) -,10p ft 37.0 Ib Line Opilons . Pressure gauges & piping Refrigerant -Charge -(no evap) - 150 ft 50.0 Ib 2022/05/04 12:14:47 Page 1 o 191 'All t' Job Nk I I I I, � W I I I os,'!( f V I I[ I loll I IA/AC; I Mit Tnm CU 1 0 t:'% Z TI nva, lllwpelwd I m Owmilty I NOTES: FAN GRILLE 1 SEE CONNECTION DRAWING FOR CONNECTION LOCATION AND SIZES 3/4" X 6 2 LOWAMBIENT DAMPER ONLY COMES WITH SELECTED UNIT MTG HOLES 3 FRONT& BACK OF UNIT CLEARANCE 72 LEFT & RIGHT SIDE OF UNIT CLEARANCE 42" CONTROLPANEL 1/2" X 4 KO (11 5V 1/2" X 2 KO (I 15V) 2 5/8" 5 3/8" CONTROL PANEL fr 5/16" 3 3/8" 88 5/16" A 4 112. ,.FRONT (SEE NOTE --" 3 FOR CLEARANCE3 318 S) 29 1/4"-1 CONDUIT 1 3/4" KO LOW 31 1/4 - MAIN POWER VOLTAGE (30V MAX. -35 13il6"- -----------37 11/16 ----------- DETAILA ............................................................................................................................................. BOTTOM OF CONTROL BOX 161, 79 1 1/4" x , SLOT FOR 115 VOLT CONTROL LOW AMBIENT DAMPER (SEE NOTE 2) 40 TON UNIT DIMENSIONAL DRAWING m 15/16" 61, 2022/05/04 12:14:47 Page 2 of 12 192 'All t, Job Nk I I I I, � W I I I os,'!( f V I L I I [ I I VAC I Mit Tnm CU 1 0 t:'% Z lllwp,lwd I m Owmilty I 12 7/8" 0 D 7/8" 0 D 1•s . .......................................................................... ............. ---SERVICE VALVE (OPTIONAL) o. �l 5/8" O.D. 7— SUCTION LINE CONNECTION HOT GAS BYPASS L.IQU ID LINE CONNEC DON CONNECTION -7 11/16 (OPTIONAL) 2 7/8" .... . . ......... T. 7 114" 16 1/4' COMPRESSORS 13 3/4" 10 1/4" 1 4 3/4' V8" O.D. HOT GAS BYPASS 711/10" --- CONNECTION� 12" (OPTIONAL) Ft CONTROL PANEL SIDE PLAN VIEW OF UNIT CONNECTION DRAWING NOTES 1, VERIFY WEIGHTS, CONNECT IONS,ANDALL DIMENSIONS WITH TRANS INSTALLATION OPERATION MAINTENANCE (IOM) DOCUMENTS BEFORE INSTALLATION CONT PANEI ORIENTATION VIEW OF UNIT .................................................................................................................................. ISOMETRIC DRAWING --11 ACCESS CONTROL PANEL (LEFT) SIDE VIEW OFUNIT BACK VIEW OF UNIT ....................................................................................................................................................................................................... ............................................................................................................................................. CONNECTION DRAWING CONNECTION DRAWING 40 TON UNIT DIMENSIONAL CONNECTION DRAWING 5 13/16" 2022/05/04 12:14:47 Page 3 o 193 Alpkt, �1"!0VIIH,o,MdHINAC HiriT�io(-M101,13�1 'J"bNkIIII, NAH'i", I lwp,i nd I (,I Owmilty I GENERAL ELECTRICAL DATA GENERAL OUTDOOR MOTOR Tonnage / kW 40 Q140()IkW Number 4 Unut Operating Voltage Range 414-506 Horsepower. 1.0 Unit PnmaryVoltage 460 r0otor Speed (rpm) 1,140 Lunt Hertz 60 Outdoor lJotor Full Load amps 1 8 th"t Phase 3 Outdoor Motor Locked Rotor amps 90 Minimum CuuntAmpacity. (3) 87 OOA Maxoduld Oveicurrent Protection Device (2) 100.00 A Recommended Dual Element Fuse (4) 100.00 A COMPRESSOR REFRIGERANT OPERATING CHARGRE (Gond Only, per Circuit) Cu-CLWAVA2 GnrcmtBl/B2 Tons (ea) 10.0 / 10.0 10.0 / 10.0 Type R410A Compressor Rated Load Amps (ea) 186/186 186/186 Number of Circuits 2 Locked RoforAmps (ea) 142,0 / 142.0 - 142.0 / 142.0 Condenser Storage Capacity 23.5 lb Refrigerant Operating Charge (Condenser Only) 22.7 Its Notes 1 Electrical data is for each indiv6dual motor. 2. Maximum ovencurnent protection permitted by nec 440-22 is 225 percent of largest compressor rnotor RLAPILIS the nemenning motor RLA and FLAvakies 3 f0ininnurri circud ampacity is 125 percent of the largest compressor motor RLA plus the remaining motoq RLA and FL.A values 4 Recommended dual element fuse size is 150 percent of the largest compressor motor RLA Plus the remaining motor RLA and FLAVakle.S 5 Local codes may take precedence 6 Electrical data 6 pulled frorn TOPSS (pe6foinnance erignue) If data is missing please check TOPSS 2022/05/04 12:14:47 Page 4 a 194 M n "Gk ()uml V t f m � T�3ri,js�s 6Af VCJ J Clpf3 TSN � ,k I I d��ine: IA�It I'i� �,�,r, rt V/ifln�7E� I Vall FiVIAf) Trane Performance Climate Changer Air Handler Outdoor unit �IICISAA025 67.7 in 80.0 in 214.4 in 528 lb Heigh in » Width Length IBM% 1 piece(s) 67.7 in 80.0 in 214.1 in 4909 Ib Airflow 13500 cfm Total, Static Pressure 5.301 in H2O Note: Height includes air handler sloped roof panel and standing seam. luuul u��udVl uiui�ui I�uul� uil' udiu uiu ul�u a uul 'Vial uiiuulou a liu iii Panel tin. foam injected R-13 with thermal break �� Panel. All unit inner panels - j �a Material galvanized Integral Base Frame 6in. integral base frame � PaintSlate gray Short' Circuit Curren5 kA t dx�,ry Rating Agency Approval UL listed unit Roof Curb; Standard roof curb Type 4909 Ib 11011 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 27.22 A 33.97 A 60.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A IIII II IIIIIIII II IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 13500 cfm 1303 ft/min 10.36 sq ft 0.297 in H2O Yes damper Bottom Return Parallel blade 13500 cfm 1303 ft/min 10.36 sq ft 0.142 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 18.00 Pressure Drop Condition Face Velocity Ali low 0. 563 Mid-life 270 ft/min 13500 cfm lililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililililw �»°>>��rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr� DoorLocation, Right 16in.x25in. Area 50.00 so ft 195 2022/05/09 12:01:52 Page 1 of 28 Product Version: 1 e\umln WINE i,js ia' illy f ,J, k,ITvr. A4111'1( 4)n,;i V/I[hq,� I {a11 I IVAC Refrigerant - 3F Capacity 4 Total 331.00 MBh 3/8in. tube diameter (9.5 mm) $erisible" 236.50 MBh 3/8" Internally enhanced copper tubes Air 90 Per Foot Fluw 13500 cfm Ffb,MaterlalAluminum fins EnteAring Dry Bulb 80.00 F Fin Type, Omega flo H (Hi efficient) Entering WetBul4, 67.00 F Fade Area 24.74 sq ft Lsaving Dry Bulb, 64.07 F Gail (tep/single) H x L 52 in. (1321 mm) X 69" (1753 mm) finned length Leavini; Wet Bulb 59.45 F Pressure Drop 0.485 in H2O Casing, Galvanized Fate Vill,flly 546 ft/min Rjbging Wei jht 202.9 Ib ��lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll Type, R-41 OA Drain Pant Galvanized LiauidTemoerature 115.00 F Small $uctidn Temperature 45.00 F Right Circuiting Type( Intertwined circuits 7.503 in Capacity Circuits Half circuiting 4.335 in IN6m4er of'Distrlbultors; 4 2.168 in AHRI 4 10 Classification' - Left AHRI 410 das ilffeation AHRI ACHC Certified Data Generation', Date 5/9/2022 Trane Select Assist update 2590 Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I. I I 1 I 1 IJ I 1 ! 1 J f IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII� Illllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll��>�>�1111111111111111111111111111111111111111111111111111111111111111111111111111111�1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111�16�rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr� Wheel Dfametar7Type/Glassy 27in. dd plenum, 80% width, H PaWerI Fan 20 hp press Voltage, 460/3 Fan Quantity; 1 Snead 1800 Front top Right side drive Higher eff.(some bands lower,more spike) Direct drive 13500 cfm 5.301 in H2O 16.276 hp 1969 rpm 16.276 hp FEG85 76.70% 69.31 % VFD w/ bypass 460/3 Internal mounting 67.00 Hz NEMA premium compliant ODP 93.17% 88.97% 13.44 kW 20.000 hp 62.49% Note: VFD driven motor fan electrical power calculated in accordance with AHRI 430. ' Inverter balance with shaft Fan YUheel Balance grounding Door Location Right Door Guard Yes Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 4301431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may he found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 12:01:52 Page 2 of 28 196 Product Version: 1 e\umln WINS i,js ia' illy f ,k k'ITvr V4111'1( 4)nd V/I[hq'� I h I I I NAC Air mixing section 1.16 Coil section 0.48 Fan section 0.03 Diffuser section 0.08 Gas heat 1.04 Internal Static Pressure 2.84 Air Pressue Drop 0.083 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 13500 cfm 45.00 F 66.55 F 400.00 MBh 320.00 MBh iimurni Gas Inlet ' Maximum. Gas Inlet Min temp rise at Max terrip rise at Min MBH Pressure Pressure, selected airflow elected,alfflow_:� 7.000 in H2O 14.000 in H2O 2.15 F 21.55 F 32.00 MBh 2022/05/09 12:01:52 Page 3 of 28 197 Product Version: 1 ui - T uj 15 J J N � y a G ro ..� 'd LLLL 1�yy EE LLLL LUj E -o r•Ev�nZmxo,33>p m C9 u�iwwx�a o.UMC�1 .-ro6 u�'ida�S:-O��Oa'Q p�woM LL p�� ^fid LC �` K Ci uj 7 ��+yy W_________ __ 4') -------------------- co ______ wJ N�, ----------�---------= p `-----------------M.----------------- ----" -------'r'1. M `- $ u7 j r L cn c 2 co LL w m > D > \ V Vv G N 7 N O7 O qcn I ?i p5 U Ocu co 'n Q O FT Rtl in q D d HLU LU U c m Q x CL c / .... d o �q p E co m-0 9 z co w LL ti� a r c E v w m `o LL N *y N C C Q C p GO :2 O m > �i a 2 N O Q) N L51 cl, (6 NU) Q.uj 2 D a — 0 - IMiiTnio(`''UJ) 01,13 C1i.r�iiLly I CU -2 (OPTION 3) Condensing unit -Air cooled 25 ton 1598.0 Ib 1921.0 Ib 26.96 kW 0.00 ft 460/60/3 Unit disconnect switch (nonfused) 1.80 A 3.00 Each 2.60 kW Suction service valve R41 Da 95.00 F Standard ambient control 12.1 EER 52.00 A 70.00 A 60.00 A 22.20 A 1.00 Each 18.60 A 1.00 Each 24.36 kW Standalone RAUJ Condenser 324.90 MBh 45.00 F 121.36 F 105.22 F Liquid, Line Size 7/8 in. Refrlgeriant'Char',g (ho ovap) -,10p ft 37.0 Ib Line Opilons . Pressure gauges & piping Refrigerant-Charge,(no evap) - 150 ft 50.0 Ib 2022/05/04 12:14:47 Page 1 o 199 'All t,Job Nkiiii, W I I i os,n( f ViIPrr Mr loll I I VAC I Mit Tnm CM J 0 13 Z it nva, lllwp�,lwd I m Owmilty I NOTES: 1 SEE CONNECTION DRAWING FOR CONNECTION LOCATION AND SIZES 2 LOW AM BIEN I DAMPER ONLY COMES WITH SELECTED UNIT , 3 FRONT & BACK OF UNIT CLEARANCE 72" LEFT & RIGHT SIDE OF UNIT CLEARANCE 42" 112" X 4 KO (1 15V)---� FAN GRILLE 3/4" X:4 MTG HOLES 1/2"X2K (115V�� —CONTROL PANEL 2 5/8" 5 3/8" / ... 5/16" 3 3/8- . ......................................................... 11 ...................... ...„,".:--t ---- ------------ 4 ,, ---------- FRONT (SEE NOTE 3 FOR CLEARANCES) 3 3/8" —4" CONDUIT 1 3/4" KO LOW 29 1/4"— VOLTAGE (30V MAX.) 31 1/4— MAIN POWER —35 13/16"- 72 12" 661/2" —37 11/16--1 DETAIL C . 0 N . T . R - 0 .- L .- BOX B - 0 .- T . T .- 0 M ----------------------------------------------------------------- FJ 1 2 ..................... I DOOR 43 1/4" W1 180 DEG SWING 1 1/4 DETAIL 'LINE Ot..TA(.',E 1 114 SLO VOL 4' TROQ BC (SEE DETAIL 60 1/8— 25 TON UNIT LOW AMEN ENT TOTE 2) DIMENSIONAL DRAWING 1� mm 2022/05/04 12:14:47 Page 2 of 12 200 'All t'Job Nkiiii, W I I i os,n( f Vi H I I �d I I VAC I Mit Tnm C'U �) 0 13 , A 1 1, Z VEINY lllwp�'lwd I m Owmilty I CONTROL PANEL SIDE f.� T9' O. D HO I GAS BYPASS CONNECTION (OPTIONAL) 15/8"0D. CON TR 01. PAN E.L. SUCTION LINE CONNECTION —7/8" O.D. (VERTCAL) LIQUID LINE 2 1/8" 0 1) CONNECTION SUCTION LINE CONNECTION (HORIZONTAL) 34 lf2" 16 9/16" 7 9/16" ."---231/2"---z 5 1 ,—SERVICE VALVE (OPTIONAL) PLAN VIEW OF UNIT CONNECTION DRAWING CONNECTION DRAWING [A DIIJENSIONALCONNEcrION DRAWING NOTES 1, VERIFY WEIGHTS, CONNECT [ON S, AND ALL DIM TENSIONS WITH TRANS INSTALLATION OPERxrlON MAINTENANCE (IOTA) DOCUMENTS BEFORE INSTALLATION ORIENTATION VIEW OF UNIT . ................................................................................................ ISDIJEJRIC DRAWING FSS BACK VIEW OF UNIT ............................................................................................................................................. CONNECTION DRAWING 16" 2022/05/04 12:14:47 Page 3 o 201 �jpnd Vill�,o, I l�,11 I VAC )i i T ( ',' 01, J,, 1) N 1\4 ( I 'i I � i i �i U �) 13 I lwp,i nd I (,I Owmilty I GENERAL ELECTRICAL DATA GENERAL OUTDOOR MOTOR Tonnage/kW: 25 (88.0 kW) Number 3 Unut Operating Voltage Range 414-506 Horsepower. 1.0 Unit PnmaryVoltage 460 r0otor Speed (rpm) 1,140 Unut Hertz 60 Outdoor lJotor Full Load amps:. 1 8 th"t Phase 3 Outdoor Motor Locked Rotor amps 90 Minimum CuuntAmpacity (3) 52 OOA Maxoduld Ovencurrent Protection Device (2) TO OOA Recommended Dual Element Fuse (4) 70 OOA COMPRESSOR REFRIGERANT OPERATING CHARGRE (Gond Only, per Circuit) Cu-CLWAVA2 GircuitBl/B2 Tons (ea) 100/135 Type R -410A Compressor Rated Load Amps (ea) 10.0 / 222 Number of Circuits 187 Ib Locked RoforAmps (ea) 142,0/1580 Condenser Storage Capacity 11.8 Ib Refrigerant 0 perating Charge (Condenser Only) Notes 1 Electrical data is for each indiv6dual motor. 2. Maximum ovencurnent protection permitted by nec 440-22 is 225 percent of largest compressor rnotor R LA Plus the nemenning motor RLA and FLAvakies 3 f0ininnurri circud ampacity is 125 percent of the largest earn pressor motor RLA plus the remaining motoq RLA and FI.Avalues 4 Recommended dual element fuse size is 150 percent of the largest compressor motor RLA Plus the remaining motor RLA and FLA Values 5 Local codes may take precedence 6 Electrical data 6 pulled frorn TOPSS (pe6foinnance erignue) If data is missing please check TOPSS 2022/05/04 12:14:47 Page 4 a 202 ��pp ry� RTU -3 /VA 7,7", � � gyk`� ()uaiifity I ,I,k,ITf V411'1( 4)n,rt V/I[hq,� I h I I FiVAC Trane Performance Climate Changer Air Handler Outdoor unit CSAA014 47.7 in 72.0 in 198.6 in 3995 Ib 3677 Ib 1 piece(s) 47.7 in 72.0 in 198.3 in 3677 Ib Airflow '' 7500 cfm Total,Siati�6 Pressure ; 5.484 in H2O Note: Height includes air handler sloped roof panel and standing seam. VIII � III III VIII ul�Vl Panel iu2iunlul�lfoam l lili 11111111111111�II11 IIII IIII 1 with thermal R-13 beakr , Panel All unit inner panels - Material galvanized 7 �� Alk Integral bin. integral bframe rame Rase Frame.. Paint Slate gray Short Circuit 5 kA Current � Rating; Agency UL listed unit Allproval R61of Curt5 Standard roof curb TyP 0.00 ft Circuit number 1 Supply fan motor(s) 460/3/60 21.22 A 26.47 A 45.00 A Circuit number 2 Gas heat 460/1/60 3.26 A 4.08 A 15.00 A i� uu 11 uu 11 uu IIIIII Vu U UU IIIIII IIIII1III IIII �� Controller Type No controller Warranty section Std. warranty only Back Outside Parallel blade 7500 cfm 1325 ft/min 5.66 sq ft 0.342 in H2O Yes damper Bottom Return Parallel blade 7500 cfm 1325 ft/min 5.66 sq ft 0.226 in H2O N/A damper Pleated media - MERV 8 2" MERV 8 4.00 20in.x20in. 2.00 20in.x25in. Pressure Drop,_,",-,"_ Condition; Fadevolocity Airflow Area 0.616 Mid-life 415 ft/min 7500 cfm 18.06 sq ft i I1 1 11 Il 1 I IJ 1 Door Location Right 203 2022/05/09 12:01:52 Page 1 of 28 Product Version: 1 iaumel\n illy f WINE i,jsf\I VI.1 'f 010 ,J, d",iner. A4111'1( 4)n,;i V/I[hq,� I {a11 I IVAC Refrigerant - 3F Capacity 4 Total 238.00 MBh 3/8in. tube diameter (9.5 mm) $elisibie" 162.98 MBh 3/8" Internally enhanced copper tubes Air ' 118 Per Foot Flow 7500 cfm Fin"Material Aluminum fins Entering Dry Bulb 80.00 F Fin Type, Omega flo H (Hi efficient) Entering WetBul4, 67.00 F Fade Area 13.44 sq ft Lsavling Dry Bulb, 60.21 F Grail (tep/single) H x L 32 in. (813 mm) X 61" (1549 mm) finned length Leavin, Wet Bulb 56.99 F Pressure Drop" 0.644 in H2O Casing, Galvanized (Face Vefocityi 558 ft/min Rjbging Wei ht 133.0 lb ��lllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll Type, R-41 OA Drain Pant Galvanized LiauidTemoerature 115.00 F Small Suction Temperature 45.00 F Right Circuiting Type( Intertwined circuits 7.785 in Capacity Circuits Full circuiting 4.524 in IN6m4er of'Distribultors; 2 2.262 in AHRI 4 10 Classification'' " Left AHRI 410 das ilffeation AHRI ACHC Certified Data Generation', Date 5/9/2022 Trane Select Assist update 2590 Note: Certified in accordance with the AHRI Forced -Circulation Air -Cooling and Air -Heating Coils Certification Program which is based on AHRI Standard 410 within the Range of Standard Rating Conditions listed in Table 1 of the Standard. Certified units may be found in the AHRI Directory at www.ahridirectory.org. Right I I I. I I 1 I 1 IJ I 1 ! 1 J f IIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIIII� Illllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll��>�>�1111111111111111111111111111111111111111111111111111111111111111111111111111111�1111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111�16�rrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrrr� Wheel Dlamr3ter/Type/Class, 20in. dd plenum, full width, M press Power Fan' 15 hp �FanQuantity 1 Voltage; 460/3 Discharge Location Front top Sneed 1800 Motor Location Right side drive Blades Higher eff.(some bands lower,more spike) DriveService' Factor ll Direct drive Airflow 7500 cfm Total Static Pressure, 5.484 in H2O Total Brake Power 10.340 hp Operating Speed, 2497 rpm Total,Braka,'HP, 10.340 hp AMCA FEG FEG85 Bare fair pr'eir,f9#e( efficir'ftr3f', 75.40 Unit Static Efficiency; 62.71 % VFD w/ bypass 460/3 Internal mounting 85.00 Hz NEMA premium compliant ODP 93.45% 88.64% 8.60 kW 15.000 hp 56.14% Note: VFD driven motor fan electrical power calculated in accordance with AHRI 430. Fan Wheel Balance' Inverter balance with shaft grounding Door Location Right Door Guard Yes Note: Certified by the AHRI Central Station Air -Handling Unit (AHU) Certification Program, based on AHRI Standard 430/431. AHRI certified units are subject to rigorous and continuous testing, have performance ratings independently measured and are third party verified. Certified units may be found in the AHRI Directory at www.ahridirectory.org. 2022/05/09 12:01:52 Page 2 of 28 204 Product Version: 1 iaumel\n illy f WINS i,jsf\I VI.1 'f 010 'J k'ITvr V4111'1( 4)nd V/I[hq'� I h I I I NAC Air mixing section 1.25 Coil section 0.64 Fan section 0.03 Diffuser section 0.14 Gas heat 0.92 Internal Static Pressure 2.98 Air Pressue Drop 0.139 UL/Factory Mutal Natural gas 460V 10:1 Burner Right Right hand door turndown ratio 7500 cfm 45.00 F 83.79 F 400.00 MBh 320.00 MBh iimurni Gas Inlet ' Maximum. Gas Inlet Min temp rise at Max terrip rise at Min MBH Pressure Pressure, selected airflow elected,alfflow_:� 7.000 in H2O 14.000 in H2O 3.88 F 38.79 F 32.00 MBh 2022/05/09 12:01:52 Page 3 of 28 20 Product Version: 1 ui -i h4 J uuj w a wx X1p5i5 i5 � t .... GLaU O. m0101 O1 '*i 'p°pBm��tl� M M t W.0 x x . W %w '"at�aGiG a$ E•o u�Enr - $Z a� v, $3333 19u�,wco©aaU)Ua'"i �.-�a r°'i©acNv2r Oma © LL LU LC K Ci uj cn7 ______________________________hN- ------------------------------ _ ______________ _______________� co LO M a M O ppqq M ____._._ _._._._._._..M1 _._._._._._._._._._.___ .N _._._._�. b,® . . 9 _ - — tPa �a) LL T 1 .cn co — LL 7 tT Z oaoLmM� 1n .-------- -_0 Q N F p w ro U- N = in _____ r,.. 5. ❑ U 0 Q O1 'E O N O_1 uj Q M SM. N � a+ C) f+ �Lo 1, 0 0 T ° a r - O N tttlffii Tbn 9 9 � p C) m — Z 7 N gp�gp O W A 0 Co 0 ^M ~ .L O. LL CL G 0 O N O LL 0 *y N C C ^mA O .— Q C 0 GO O m > a � a cm N uj '55 0 N Condensing unit -Air cooled 20 ton 1548.0 Ib 1872.0 Ib 22.88 kW 0.00 ft 460/60/3 Unit disconnect switch (nonfused) 1.80 A 2.00 Each 1.86 kW Suction service valve R41 Da 95.00 F Standard ambient control 11.7 EER 45.00 A 60.00 A 60.00 A 18.60 A 2.00 Each 0.00 A 0.00 Each 21.02 kW Standalone RAUJ Condenser 266.66 MBh 45.00 F 122.51 F 106.50 F Liquid, Line Size 5/8 in. Refrlgeriant/Char',g (ho ovap) -,10p ft 25.0 Ib Line Opilons . Pressure gauges & piping Refrigerant-Chaarge-(no evap) - 150 ft 32.0 Ib 2022/05/04 12:14:48 Page 1 o 207 ��Ndw UN��NM"1�A�1btl�''dl��Yd° � Condensing unit -Air cooled 20 ton 1548.0 Ib 1872.0 Ib 22.88 kW 0.00 ft 460/60/3 Unit disconnect switch (nonfused) 1.80 A 2.00 Each 1.86 kW Suction service valve R41 Da 95.00 F Standard ambient control 11.7 EER 45.00 A 60.00 A 60.00 A 18.60 A 2.00 Each 0.00 A 0.00 Each 21.02 kW Standalone RAUJ Condenser 266.66 MBh 45.00 F 122.51 F 106.50 F Liquid, Line Size 5/8 in. Refrlgeriant/Char',g (ho ovap) -,10p ft 25.0 Ib Line Opilons . Pressure gauges & piping Refrigerant-Chaarge-(no evap) - 150 ft 32.0 Ib 2022/05/04 12:14:48 Page 1 o 207 'All t, Job f L3iii IW I I i os,n(f Vi I[ I I ad I I IVAC L Mit Tnm C'U 3 0 13 Z lllwheir d I m Owmilty I NOTES: 1 SEE CONNECTION DRAWING FOR CONNECTION LOCATION AND SIZES 2 LOWAMBIENT DAMPER ONLY COMES WITH SELECTED UNIT 3 FRONT & BACK OF UNIT CLEARANCE 72 TEFT& RIGHT SIDE OF UNIT CLEARANCE FAN GRILLE //_3/4" X 4 MTG HOLES < ---------- 112" X 2 FRONT (SEE NOTE 3 FOR CLEARANCE/7 72 112" 1 :314" KO LOW VOLTAGE (30V MA 2 1 _V_ 8" ---------<---------------------------- lr� DOOR 43 1/4" W1 180 DEC, SWING 1 1/4" 57 5/8" 20 TON UNIT /L 11-1 TAIL A) LINE �L_TAGE :CESS /4" x 4 1/2 )T TO R 1 LT CONT NTROL B �E DETAIN DIMENSIONAL DRAWING DETAILA I ...................................................................................................................................... CONTROL BOX BOTTOM LOW AMBIENT DAMPER (SEE NOTE 2)-----\ 'ANEL CONDUIT RAIN POWER ME 2022/05/04 12:14:48 Page 2 of 12 208 'All t' Job f L3iii IW I Ii os,n( f Vi H I I ad I I IVAC L Mit Tnm C'U 3 0 13 Z lllwp�'lwd I m Owmilty I 1 5/8" 1 SUCT I CONN 16 CONTROL PANEL SIDE COIL COMPI PLAN VIEW OF UNIT CONNECTION DRAWING PRESSORS 0 D JID LINE 4NECTION CONTROL PANEL SUCTION 1..I NOTES TVERIFY WEIGHTS, CONN ECT IONS, AND ALL DIMENSIONS WITH -rRANE INSTALLATION OPERATION MAINTENANCE (CIA) DOCUMENTS BEFORE INSTALLATION ORIENTATION VIEW OF UNIT .................................................................................................. ISOMETRIC DRAWING ,ESS BACK VIEW OF UNIT CONNECTION DRAWING CONNECTION DRAWING 20 TON UNIT DIMENSIONAL CONNECTION DRAWING 6" 2022/05/04 12:14:48 Page 3 o 209 �jpnd Vill�,o, I l�,11 I VAC )i i T ( ',' 01, J,, 1) N 1\4 ( I 'i I � i i �i U �� 13 I lwp�,i nd I (,I Owmilty I GENERAL ELECTRICAL DATA GENERAL OUTDOOR MOTOR Tonnage / kW 20 (70.4 kW) Number 2 Unut Operating Voltage Range 414-506 Horsepower. 1.0 Unit PnmaryVoltage 460 r0otor Speed (rpm) 1,140 Lunt Hertz 60 Outdoor lJotor Full Load amps 1 8 th"t Phase 3 Outdoor Motor Locked Rotor amps 90 Minimum CuuntAmpacity. (3) 45 OOA Maxoduld Ovencurrent Protection Device (2) 60 OOA Recommended Dual Element Fuse (4) 60 OOA COMPRESSOR REFRIGERANT OPERATING CHARGRE (Gond Only, per Circuit) Cu-CLWAVA2 GnrcmtBl/B2 Tons (ea) 100/100 Type R410A Compressor Rated Load Amps (ea) 18.0 / 1n 6 Number of Circuits 1 Locked RoforAmps (ea) 142,0/ 1420 Condenser Storage Capacity 18 .7 lb Refrigerant Operating Charge (Condenser Only) 11 9 lb Notes 1 Electrical data is for each indiv6dual motor. 2. Maximum ovencurnent protection permitted by nec 440-22 is 225 percent of largest compressor rnotor R LA Plus the nemenning motor RLA and FLAvakies 3 f0ininnurri circud ampacity is 125 percent of the largest earn pressor motor RLA plus the remaining rnotoq RLA and FI.Avalues 4 Recommended dual element fuse size is 150 percent of the largest compressor motor RLA Plus the remaining motor RLA and FLA Values 5 Local codes may take precedence 6 Electrical data 6 polled frorn TOPSS (pe6foinnance erignue) If data is missing please check TOPSS 2022/05/04 12:14:48 Page 4 a 210 TU -4 (OPTION RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -4 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 36 of 57 211 Unit Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 030 (30 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6, 1„ Unit Operating Weight: 4652 Ib Unit Shipping Weight: _______________________4690 Ib ***Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve ---------------------------- 15 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D030LPG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 15 HP Applied Rooftop Builder 3.29s Page 37 of 57 212 Unit Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 38 of 57 213 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d T N Q U Q 2 CU U) Co C� U L Q Co O 2i c m G U ca N O � � d Ln r N Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: 48A6D030LPG64AGQ Unit Refrigerant: R41 OA EER (AHRI 340/360): ---- ----- - 9.8 ------------------------------------------------------------------------------- - - - - - IEER (AHRI 340/360). 14.0 Unit Dimensions Unit Length. 13' 9" Unit Width: 7' 10" Unit Height: 6' 1" Unit Operating Weight: 4652 Ib Unit Shipping Weight: 4690 Ib *Unit operating weight does not include accessories weight. Unit Heating Type: Gas Heat Supply/Return: Vertical/Vertical Application Type: Staged Air Volume Voltage: 460-3-60 Cooling Airflow: 7800 CFM Altitude: 0 ft Cond. Ent. Air Temp: 105.0 F Ent. Air Dry Bulb: 80.0 F Ent. Air Wet Bulb: 67.0 F Ent. Air Enthalpy: 31.44 BTU/Ib Lvg. Air Dry Bulb: --- --- - 54.7 F Lvg. Air Wet Bulb: ---- ---- - 54.1 F Lvg. Air Enthalpy 22.64 BTU/Ib Gross Cooling Capacity: 308.94 MBH Gross Sensible Clg. Cap: 212.84 MBH Compressor Power. 29.3 kW Coil Bypass Factor. 0.112 Refrigerant Charge, Circuit A: 15.1 Ib Refrigerant Charge, Circuit B: 15.3 Ib Part Load(%) Operation Cooling Capacity Steps: 25,50,75,100 Gas Heating Data: Heating Airflow: 7800 CFM Heating Ent. Air Temp: 55.0 F Gas Input: 262.5/ 350 MBH Number of Heating Steps: 2 Gas Input (Min): 262.5 MBH Gas Input (Max): 350 MBH Gas Output: 283.5 MBH Heating Lvg. Air Temp: 88.7 F Steady State Eff: 81 Temp.Rise: 33.7 F Supply Fan Information: Ext.Static Pressure. 2.50 in wg Selection Static Pressure: 2.50 in wg Supply Fan RPM: 956 * Supply Fan BHP: 6.07 BHP Supply Fan Motor HP: 15 HP *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: 6800 CFM Applied Rooftop Builder 3.29s Page 41 of 57 216 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.84 in wg Page 42 of 57 217 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 11.2 Compressor #A1 LRA: 75 Compressor#A2 RLA: ---- --- 11.2 Compressor #A2 LRA: 75 Compressor #B1 RLA: 11.2 Compressor#B1 LRA: ---- --- 75 Compressor #132 RLA: 11.2 Compressor #132 LRA: 75 Indoor Fan Motor HP: 15 Indoor Fan Motor FLA: 21 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 90 Power Supply MOCP (Fuse or HACR): 110 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3-3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 43 of 57 218 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 92.9 88.8 63.9 125 Hz 82.3 77.2 72.2 250 Hz 80.6 75.7 78.9 500 Hz 83.1 71.5 82.1 1000 Hz 82.8 73.2 84.1 2000 Hz 78.6 68.9 78.8 4000 Hz 76.1 67.5 72.5 8000 Hz 70.6 63.0 64.6 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 43 of 57 218 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.9 72.2 78.9 82.1 84.1 78.8 72.5 64.6 87.9 Lw B 37.7 56.1 70.3 78.9 84.1 80.0 73.5 63.5 86.7 LwA C 30.6 38.9 45.6 48.8 50.8 45.5 39.2 31.3 54.5 Lp D 4.4 22.8 37.0 45.6 50.8 46.7 40.2 30.2 53.4 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 44 of 57 219 Performance Summary For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve Aidow(CFM-thousands) RPM=956BHP=6.07MaximumRPM=1200Maximumf]P=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 45 of 57 220 � �7zpm x7\--, 11UE 3 70DF PM 6DOR -M \ \ I I 1 7'� 10.00B 1 15. BHP I HP 1. P 2.00 P 5 B 25. HP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 2 Aidow(CFM-thousands) RPM=956BHP=6.07MaximumRPM=1200Maximumf]P=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 45 of 57 220 Corner Weight / Center of Gravity Report For RTU -4 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 7' 10" CG Dimension (B): 3' 8" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1" Unit Weight: 4652.3 Ib Unit Shipping Weight: 4690.0 Ib Corner Weight (1): 1001.0 Ib Corner Weight (2): 1001.0 Ib Corner Weight (3): 1325.0 Ib Corner Weight (4): 1325.3 Ib Total Corner Weight: 4652.3 Ib Applied Rooftop Builder 3.29s 3 4 48A6D030LPG64AGQ Page 46 of 57 221 RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM RTU -5 REV2 Tag Cover Sheet Unit Report Certified Drawing Performance Report Corner Weight Applied Rooftop Builder 3.29s Page 47 of 57 222 Unit Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Unit Parameters Unit Size: Volts -Phase -Hertz:___ Supply / Return:______ Configuration:_________ Evaporator Coil Type: Heating Capacity:____ Heat Option:__________ Greenspeed:__________ Factory Installed Options Application Type: Non Fused -Disconnect:____ CO2 Sensor: --- Control Expansion Module:_ Return Air Smoke Detector: Exhaust/Outdoor Air OA Intake/Return:__ Outdoor Air Intake:_ Supply Fan Supply Fan Type:_______ Supply Fan Motor HP:__ Condenser Coil Cond. Coil Fin Coating:___ 030 (30 Tons) 460-3-60 Vertical/Vertical Staged Air Volume Standard Low Gas Heat --------2 Stage Selected Mixed -Air and Outdoor Air Filters Mixed -Air Filter Type:________________ Mixed -Air Filter (Quantity) Size:____ Outdoor Air Filter (Cleanable Mesh Warranty Information First Year- Parts Only (Standard) Start-up, First Unit Complete Unit 1st Year Carrier CCS Labor Compressor Years 2-5 Parts Only Shipping Dimensions Unit Length: ------ 13,9" Unit Width: ------ 7, 10.. Unit Height: 6-11" Unit Operating Weight: 4652 Ib Unit Shipping Weight: _______________________4690 Ib —Weights and Dimensions are approximate. Weight does not include curbs and accessories. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions refer to certified drawings. ** Shipping Weight does not include extended leadtime options' weight. Air Volume Selected Selected Selected Selected Non -Modulating Power Exhaust Differential Dry -Bulb Ultra Low Leak Economizer Forward Curve 15 HP MCHX Cond, AI/Cu Evap Standard Efficiency Throwaway - (10)20x24x2 (8) 16 x 25 x 2, (4) 20 x 25 x 2 An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. NOTE: Please see Warranty Catalog 808-218 for explanation of policies and ordering methods. Ordering Information Part Number Description Quantity 48A6D030LPG64AGQ Rooftop Unit With Greenspeed Intelligence 1 Base Unit Premium Efficiency Differential Dry -Bulb Ultra Low Leak Economizer Non -Modulating Power Exhaust Non -Fused Disconnect 115v Convenience Outlet: Field Wired Premium Efficiency 15 HP Applied Rooftop Builder 3.29s Page 48 of 57 223 Unit Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Return Air CO2 Sensor & Return Air Smoke Detector & Controls Expansion Module CEM with Phase Monitor Domestic w/BACnet Communication Accessories Accessory Part # Description Quantity CRRFCURB005A00 14 -inch Roof Curb 1 33CONNECTSTAT Carrier ConnectTM Wi-Fi 7 -da program mable/non-pro 1 CRPECONV006A00 Bldg. Pressure Transducer 1 Applied Rooftop Builder 3.29s Page 49 of 57 224 Q N ry U Q 2 _- MCU U) C� U L Q Co O L c+ m G U ca N O 9) � d Ln N N Q U Q 2 CU U) Co C� U L Q O 2i c m G U ca N O � � d co N N Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Part Number: Unit Refrigerant:________ EER (AHRI 340/360): IEER (AHRI 340/360):_ _ Unit Dimensions Unit Length: ------------------- Unit Width: ------------------- Unit Height: ------------------------- Unit Operating Weight: ------------------------------- Unit Shipping Weight: -------------------------------- *Unit operating weight does not include accessories weight. Unit Heating Type: Supply/Return: Application Type: Voltage: Cooling Airflow: Altitude: Cond. Ent. Air Temp:_________ Ent. Air Dry Bulb:______________ Ent. Air Wet Bulb:_____________ Ent. Air Enthalpy:_____________ Lvg. Air Dry Bulb:_____________ Lvg. Air Wet Bulb:_____________ Lvg. Air Enthalpy:_____________ Gross Cooling Capacity:______ Gross Sensible Clg. Cap:_____ Compressor Power:___________ Coil Bypass Factor:___________ Refrigerant Charge, Circuit A: Refrigerant Charge, Circuit B: Part Load(%) Operation Cooling Capacity Steps: Gas Heating Data: Heating Airflow:___________ Heating Ent. Air Temp:____ Gas Input: Number of Heating Steps: Gas Input (Min):___________ Gas Input (Max):__________ Gas Output: Heating Lvg. Air Temp:___ Steady State Eff:__________ Temp. Rise: Supply Fan Information: Ext.Static Pressure. Selection Static Pressure: Supply Fan RPM: ------------ Supply Fan BHP: ------------------- Supply Fan Motor HP: ------------------------- *Field supplied and installed sheave package may be required* Power Exhaust Information: Airflow: Applied Rooftop Builder 3.29s 48A6D030LPG64AGQ R41 OA 9.8 14.0 13' 9" 7. 10" 6-1" ___ 4652 lb 4690 lb 5,50,75,100 CFM ft F F F BTU/Ib F F BTU/Ib MBH MBH kW I 10500 CFM 55.0 F .5/ 350 MBH 2 ___262.5 MBH _____350 MBH 283.5 MBH 80.0 F 81 25.0 F 2.50 in wg 2.50 in wg 1037 * 8.99 BHP 15 HP ___9000 CFM Page 52 of 57 227 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Selection Static Pressure:_ Applied Rooftop Builder 3.29s 0.45 in wg Page 53 of 57 228 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Electrical Data Discharge, Lw Voltage Range: 414-508 Compressor #A1 RLA: 11.2 Compressor #A1 LRA: 75 Compressor#A2 RLA: ---- --- 11.2 Compressor #A2 LRA: 75 Compressor #B1 RLA: 11.2 Compressor#B1 LRA: ---- --- 75 Compressor #132 RLA: 11.2 Compressor #132 LRA: 75 Indoor Fan Motor HP: 15 Indoor Fan Motor FLA: 21 Combustion Fan Quantity: 2 Combustion Fan FLA (ea.): 1.1 Pwr. Exhaust Fan Motor Qty: 4 Pwr. Exhaust Fan Motor FLA (ea.): 3.15 Power Supply MCA: 90 Power Supply MOCP (Fuse or HACR): 110 Electrical Convenience Outlet: None Outdoor Fan [Qty / FLA (ea)]: 2/3-3 SCCR, Short Circuit Current Rating: 5kA An uncoated Novation condenser coil was selected for this product. This is based on an installed location with postal code: 60056 and a non -corrosive localized environment. Acoustic Information Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 54 of 57 229 Discharge, Lw Inlet, Lw Outdoor, Lw 63 Hz 94.3 89.5 63.9 125 Hz 86.8 78.2 72.2 250 Hz 84.2 75.7 78.9 500 Hz 87.2 71.7 82.1 1000 Hz 87.9 73.3 84.1 2000 Hz 84.4 69.1 78.8 4000 Hz 80.9 67.6 72.5 8000 Hz 74.5 63.0 64.6 Discharge / Inlet Duct Sound Power test data rated in accordance with the AHRI 260 Standard. Calculation methods used in this program are patterned after the ASHRAE Guide; other ASHRAE Publications and the AHRI Acoustical Standards. While a very significant effort has been made to insure the technical accuracy of this program, it is assumed that the user is knowledgeable in the art of system sound estimation and is aware of the tolerances involved in real world acoustical estimation. This program makes certain assumptions as to the dominant sound sources and sound paths which may not always be appropriate to the real system being estimated. Because of this, no assurances can be offered that this software will always generate an accurate sound prediction from user supplied input data. If in doubt about the estimation of expected sound levels in a space, an Acoustical Engineer or a person with sound prediction expertise should be consulted. Advanced Acoustics Page 54 of 57 229 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Advanced Accoustics Parameters 1. Unit height above ground: 30.0 ft 2. Horizontal distance from unit to receiver: 50.0 ft 3. Receiver height above ground: 5.7 ft Detailed Acoustics Information Octave Band Center Freq. Hz 63 125 250 500 1 k 2k 4k 8k Overall A 63.9 72.2 78.9 82.1 84.1 78.8 72.5 64.6 87.9 Lw B 37.7 56.1 70.3 78.9 84.1 80.0 73.5 63.5 86.7 LwA C 30.6 38.9 45.6 48.8 50.8 45.5 39.2 31.3 54.5 Lp D 4.4 22.8 37.0 45.6 50.8 46.7 40.2 30.2 53.4 LpA Legend A Sound Power Levels at Unit's Acoustic Center, Lw B A -Weighted Sound Power Levels at Unit's Acoustic Center, LwA C Sound Pressure Levels at Specific Distance from Unit, Lp D A -Weighted Sound Pressure Levels at Specific Distance from Unit, LpA Applied Rooftop Builder 3.29s Page 55 of 57 230 Performance Summary For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM Supply System Curve 4 11 � �7zpm 3 700FPM IM \ \ I I 1 1 I 10.00B 15. BHP 00 HP 1. P 2.00 P `' B �'� 25. HP 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 23 Aidow(CFM-thousands) RPM= 1037 BHP=8.99 MaximumRPM=1200 MaximumHP=23.40 SC- SystemCurve RP-RatedPoint Applied Rooftop Builder 3.29s Page 56 of 57 231 Corner Weight / Center of Gravity Report For RTU -5 REV2 Project: Mt Prospect Village Hall HVAC Repl 05/11/2022 Prepared By: Marshall M Sayles 09:12AM 2 Rooftop Unit Part Number: CG Dimension (A): 7' 10" CG Dimension (B): 3' 8" Unit Length: 13' 9" Unit Width: 7' 10„ Unit Height: 6' 1„ Unit Weight: 4652.3 Ib Unit Shipping Weight: 4690.0 Ib Corner Weight (1): 1001.0 Ib Corner Weight (2): 1001.0 Ib Corner Weight (3): 1325.0 Ib Corner Weight (4): 1325.3 Ib Total Corner Weight: 4652.3 Ib Applied Rooftop Builder 3.29s 3 4 48A6D030LPG64AGQ Page 57 of 57 232 Burns & McDonnell 1431 Opus Place, Suite 400 Downers Grove, IL 60515 O 630-724-3200 F 630-724-3201 www.burnsmcd.com 233 MAYOR Paul Wm. Hoefert TRUSTEES - Agostino S. Filippone Terri Gens John J. Matuszak Richard F. Rogers Colleen E. Saccotelli Michael A. Zadel VILLAGE MANAGER Michael J. Cassady DIRECTOR OF PUBLIC WORKS Sean P. Dorsey Village of Mount Prospect Public Works 1700 W. Central Road, Mount Prospect, Illinois 60056 Request for Proposals July 18, 2022 FROM: Scott Moe, Streets/Buildings Superintendent Village of Mount Prospect Public Works Department RE: Request for Proposals Village Hall HVAC Unit Replacement Phone: 847/870-5640 Fax: 847/253-9377 www.mountprospect.org Your firm is invited to submit a Technical Proposal and Cost Proposal to become eligible for a possible interview for engineering services for the Village Hal I HVAC Project. Attached to this memo are: 1. A list of materials and information that should be included with your Technical Proposal and Cost Proposal (Exhibit A). 2. A general definition of the scope of work and requirements for your submittal (Exhibit B). 3. The evaluation process and tentative schedule (Exhibit C). The Village of Mount Prospect appreciates your interest in this project. Any questions regarding this Request for Proposals can be directed to Scott Moe, Streets/Buildings Superintendent with the Village of Mount Prospect, by phone at 847-870-5640 or email at smoe,(d iiMqantprn Your Technical Proposal and Cost Proposal are to be submitted one of the following two ways and received no later than 5:00 p.m. on Friday, August 19, 2022: via DemandStar login or register at www.demandstar.com search for and click on Village Hall HVAC Replacement Project follow directions to upload documents via Email send documents to the attention of Scott Moe, Public Works Streets/Buildings Superintendent, at srrafac �rrwµrt.Nrtprcrp t.trg, with Village Hall HVAC Replacement Project in the Subject line 234 Exhibit A Requirements for Technical and Cost Proposal Agency: Village of Mount Prospect Project: Village Hall HVAC Replacement Project Location: Village Hall, 50 S Emerson Mount Prospect IL Your Technical Proposal and Cost Proposal should include the following information: 1. Name, address and brief history of firm. 2. Organizational chart and resumes of key personnel to be assigned to this project. 3. Related experience during the last five (5) years. 4. Description of process to accomplish the required tasks of the project. This should include: a. An understanding of the project. b. Objectives to be met as part of the project. c. Your approach to completing the project. d. The projected number of hours to complete the project broken down by task and personnel. e. A project schedule. Exhibit B General Scope of Work Agency: Village of Mount Prospect Project: Village Hall HVAC Replacement Project Location: Village Hall, 50 S Emerson Mount Prospect IL 1. Overview Mount Prospect Village Hall is a 3 -story municipal building constructed in 2003. The building is served by five (5) Carrier roof top units that condition each Village Hall floor and the Board Room. Three (3) of the RTU's, which condition the 11t, 2nd, and 3rd floors, were installed on the roof of the main building, but are located in an eight (8) ft deep pit area, surrounded by solid walls on four sides. The small enclosed area along with the black roof material has prevented heat generated from the HVAC units from escaping causing for multiple failures during the cooling season because of overheating. The Village hired a consultant in May of 2022 to evaluate the current conditions and to provide various options/recommendations to mitigate the overheating condition. See Attachment A. The village is considering option #1 which is to replace the units with a similar type but with a higher entering condenser temperature range and changing the roof membrane from a black color to a white color to aid in reducing the ambient temperature of the pit area. Option 1 further recommends increasing the cooling tons of each unit. Village of Mount Prospect Public Works Department I Page 2 235 The Village would like the following to be considered: Design/Specify an HVAC system that addresses the over -heating problem in the exterior pit area, design/specify the replacement of the three (3) RTU's in the pit area and the two (2) RTU's on an adjacent roof with units of similar size and with no substantial change in existing duct work, design/specify RTU's that are capable of operating in a higher ambient temperature, design/specify a replacement for the existing roof membrane for both RTU roof areas and design for an upgrade to the buildings automation system (BAS) to a non-proprietary system to serve the new BTU's and associated VAV boxes. 2. Scope of Services: The scope of services sought by the Village shall include the provision of all required labor, materials, equipment, expertise and consultation of professional engineering related to completion of the following tasks. The Village will consider additional tasks at the consultant's recommendation. Review available original design and/or as -built documents to become familiar with the construction of the Village Hall HVAC systems. Review the 3 options from the May 2022 report. Verify that the option #1 recommendation is feasible and that it will adequately mitigate the overheating conditions. Upon review of Option #1 it is determined that a better solution should be considered, provide supporting information for a different solution. Provide estimated construction costs for current construction season Provide cost estimate with anticipated hours that your firm will spend on Design, Bid Review, and Construction Oversight as a separate document. ■ Perform a visual review of the HVAC system from the exterior and interior. Visually review the existing HVAC unit placement. Document existing conditions and installation details Schedule: Award to MEP Firm 9/7/22 Public Bid for Construction 11/7/22 Bid Award 12/7/22 Substantial completion 6/1/23. Understanding this is based on equipment lead times. ■ Based on field findings and installation requirements, develop a replacement approach for the Village of Mount Prospect's consideration. Preparation of Plans, Contract Documents, and Cost Estimate a. Prepare design parameters and recommended standards. b. On the basis of the prior work, and the approval thereof, prepare engineering plans, specifications, and contract documents, which shall include bid forms, instruction to bidders, contract forms, special provisions, bonding and insurance requirements and, where applicable, county, state or federal compliance requirements, and assist in the preparation of other related documents. c. During prosecution of the contract documents, the Consultant will submit for review pre -final plans, special provisions and cost estimate at completion intervals of 50%, and 95%. One complete Village of Mount Prospect Public Works Department I Page 3 electronic set shall be submitted to the Village for both of the pre -final review. Bidding: a. The Consultant shall submit final contract documents to the Village; one hard copy and one electronic version. b. The Consultant shall be available to respond to any questions that may arise during the bidding process. c. The consultant shall identify qualified contractors and assist the Village of Mount Prospect in obtaining bids for the project. d. The scope of work will consist of the following: • Assist the Village of Mount Prospect in preparing a bid advertisement • Send bid documents to prospective contractors • Hold a pre-bid meeting at the site. Prepare and distribute pre-bid meeting minutes. • Answer questions from prospective contractors and prepare an addendum if necessary. • Review submitted bids and provide a summary of bids. • Based on review of bids, recommend a contractor to perform the work. Construction Phase Services: The consultant shall preform contract administration services and field observations. The services consists of the following: • Represent the Village of Mount Prospect in dealing with the Contractor as well as advise and consult with the Village of Mount Prospect on matters pertaining to repairs. • Perform field observations on a part-time basis and provide written reports summarizing our observations. The objectives of the field reviews will be to assess conformance of work with project specifications as well as progress and quantityof repair work. The extent of required site visits will greatly depend on the project approach, and the Contractor's work schedule and sequence. • Hold periodic progress meetings with Village of Mount Prospect representatives and Contractor to discuss schedule, pay requests, general progress, etc. Prepare meeting minutes and distribute to attendees and other designated parties. • Review Contractor's submittals required by Contract Documents.. • Review Contractor's payment requests and provide written payment recommendations to the Village of Mount Prospect. • Review Contractor's requests for information (RFI) and issue clarifications. • Prepare bulletins for design changes necessitated by field conditions. • Review requests for change orders, and when appropriate, issue changeorders. • Provide input to assist in resolving unanticipated field conditions or problems, if they arise. Village of Mount Prospect Public Works Department I Page 4 237 Provide contract close-out services including punch list preparation, final review of work, contract close-out and warranty submittals, and recommendations regarding final payment. 0 Provide a close-out package in electronic format. Village of Mount Prospect Public Works Department I Page 5 238 Exhibit Evaluation Process Agency: Village of Mount Prospect Project: Village Hall HVAC Replacement Project Location: Village Hall, 50 S Emerson Mount Prospect IL Your Technical Proposal and Cost Proposal are to be submitted one of the following two ways and received no later than 5:00 p.m. on Friday, August 19, 2022: via DemandStar login or register at www.demandstar.com search for and click on Village Hall HVAC Replacement Project follow- directions to upload documents via Email send documents to the attention of Scott Moe, Streets/Buildings Superintendent, at s a @Mo!jtLtp sp ,. t pfg with Village Hall HVAC Replacement Project The Technical Proposal and Cost Proposal will be evaluated based on the following factors: • Project Understanding & Technical Approach • Similar Project Experience • Project Team Capabilities • Overall Completeness of Submittal The Village may choose to conduct interviews with the shortlist firms. If so, those selected for an interview will be contacted by the Village to arrange a date/time to meet at the Mount Prospect Public Works Department, 1700 W. Central Road, or via GoToMeeting. The Village of Mount Prospect appreciates your interest in this project. Any request for information or questions regarding this Request for Proposals can be directed to Scott Moe, Streets/Buildings Superintendent, by phone at 847-870-5640 or email at ; r oe wN cat r t fr gggEg,;, Village of Mount Prospect Public Works Department I Page 6 239 ATTACHMENT: A Village of Mount Prospect Public Works Department I Page 7 240