RI Brown University Design Standards 2013
$20.15
Brown University Department of Facilities Management – Design Standards – August 14, 2013
| Published By | Publication Date | Number of Pages |
| RI | 2013 | 458 |
None
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 1 | 00000CP (Insert Facility Name) |
| 7 | II. SCHEDULE OF VALUES |
| 8 | III. LIST OF SUBCONTRACTORS IV. UNIT PRICES/HOURLY RATES (PM to Modify) V. Alternates |
| 17 | SUPPLEMENTARY GENERAL CONDITIONS |
| 21 | MINIMUM CONTRACTOR SAFETY REQUIREMENTS |
| 24 | First offense – $ 250 Second offense – $ 500 Third offense – $ 1,000 |
| 25 | 01_13_01 |
| 40 | 01_13_02 |
| 41 | 01_13_03 |
| 42 | 01_13_51 |
| 43 | RFP and Bid Language – Include in all applicable RFP and Bid project documents Process for Completing and Submitting Forms Contacts for National Grid Rebate Assistance |
| 44 | 01_13_52 RFP and Bid Language – Include in all applicable RFP and Bid project documents Process for Completing and Submitting Forms |
| 45 | Contacts for National Grid Rebate Assistance |
| 46 | 01_17_00 |
| 47 | 01_17_71 SECTION 01 17 71 – CONTRACT RECORD DOCUMENTS AND TURNOVER REQUIREMENTS PART 1 – GENERAL 1.1 SUMMARY: 1.2 MARK-UP RECORD DRAWING DOCUMENTS: |
| 48 | 1.3 AS-BUILT RECORD DRAWING DOCUMENTS: |
| 49 | 1.4 BUILDING EQUIPMENT LISTS: |
| 50 | 1.5 OPERATIONS AND MAINTENANCE MANUAL–GENERAL: |
| 51 | 1.6 SCANNING/ELECTRONIC FORMAT FOR O&M MANUALS: 1.7 MANUAL FOR MATERIALS AND FINISHES: |
| 52 | 1.8 MANUAL FOR ROOFING SYSTEMS AND BUILDING ENVELOPE: 1.9 MANUAL FOR EQUIPMENT AND SYSTEMS: |
| 54 | 1.10 START UP AND DEMONSTRATIONS FOR EQUIPMENT AND SYSTEMS: 1.11 PROJECT TURNOVER TO OPERATIONS DEPARTMENT: 1.12 WARRANTY: |
| 55 | 1.13 EMERGENCY CONTACT LIST: End of Section |
| 56 | 01_17_72 01_17_72_EQ Data Collection Form |
| 57 | 01_17_72_EQ Keyword-Type Listing |
| 64 | 01_17_73 SECTION 01 17 73 – BROWN TRADES-SPECIFIC DRAFT OPERATIONS & MAINTENANCE MANUAL SUBMITTAL SECTIONS |
| 67 | 01_17_90 PART 1 – GENERAL 1.1 SUMMARY: A. Brown University operates and maintains extensive campus and building utilities and distribution systems. These systems include: water, chilled water, process water, steam, medium and high temperature hot water, Heating, Ventilation and Air Conditi… B. This section details the minimum coordination requirements for system connections and service interruptions that may be required for new construction and renovation projects. C. RELATED SECTIONS: 1.2 GENERAL REQUIREMENTS: A. If a project or contract work requires the shutdown or de-energizing of any campus utility or building system, FM Operations and Engineering staff must be first contacted for general direction and scheduling availability prior to the work being pe… B. In general, Contractors are not allowed to operate valves open or closed, or energize and de-energize switches without prior coordination and approval from FM Operations staff. Exceptions to this policy are for new construction or within buildings … C. Chilled water, high temperature hot water and steam shutdowns can be scheduled only during off-peak seasons with limited exceptions such as an emergency repair. D. The project team (Engineer of Record and Architect) shall be responsible for the development of draft Utility & Critical System Outage Checklist(s) (OCL’s). E. Contractors shall coordinate to have the building fire alarm system disabled prior to performing any work, such as cutting or welding that may cause inadvertent operation of the fire alarm system, (“Hot Work”) and arrange for it to be enabled at th… F. “Hot work” permits are required prior to any cutting and welding operations within buildings; follow all policy safety precautions. G. Other than Brown-owned or operated utilities shall be coordinated directly with the respective utility owner by the project manager. 1.3 OUTAGE TYPES: A. 0TThere are three general types of outages, depending upon the impact that the work will have on existing building infrastructure and campus utilities. The level of planning and detail coordination required varies for each, as noted below. |
| 68 | B. 0TIndependent Outages: 1. 0TIndependent outages typically have no impact on existing campus utilities, operating communications infrastructure, building occupants or building systems. Examples include work within new building construction or “gut” building renovations, or i… 2. 0TFor independent outages, minimal Brown coordination is required; FM Project Managers (PM’s) will coordinate with the project Construction Manager for the outage scheduling, as well as outage notification, to other Brown departments and building U… C. 0TMinor Outages: 1. 0TMinor outages typically have a limited impact on existing campus utilities, including operating communications infrastructure within the project site or running through the site; building occupants or building systems. Examples include fire alarm… 2. 0TFor Minor outages, limited Brown coordination is required; FM Project Managers will coordinate outage scheduling with the project Construction Manager and with Brown FOE managers for Trades staff required to support the outage work, as well as de… 3. 0TProject Managers will also coordinate the outage notification to other Brown departments and building Users affected by this work. Minimum outage notification times are required and an outage coordination meeting prior to the outage is required t… D. 0TMajor Outages: 1. 0TMajor outages typically have a significant impact on existing campus utilities, communication systems and infrastructure, building occupants or building systems. Examples include shut down of building electrical power systems, central heating and… 2. 0TFor Major outages, significant coordination is required for both Brown staff and the project staff. Determination of major outages will be made in the Project Planning phase. Details of the outage work, and general outage scheduling will be devel… 3. 0TDuring the construction phase, FM Project Managers will coordinate outage scheduling with the project Construction Manager and with Brown FOE managers for Trades staff required to support the outage work, as well as develop work orders for Trades… 4. 0TProject Managers will also coordinate the outage notification to other Brown departments and building Users affected by this work. Minimum outage notification times are required and an outage coordination meeting prior to the outage is required t… |
| 69 | 1.4 OUTAGE PLANNING PROCESS – PLANNING PHASE: A. 0TThe need or potential for required utility outages will generally be determined in the Project Planning process; these expected outages will be conveyed to the Project Engineer of Record at the inception of the Design phase. 1.5 OUTAGE PLANNING PROCESS – DESIGN PHASE: A. 0TDuring the Design phase, the Project Engineer(s) will coordinate and work with Brown FM Operations and Engineering staff to identify and clearly define all new system connections and interconnections to existing building and campus utilities infr… 1. 0TThe outage impacts will be reviewed to determine if the outage(s) are independent, major or minor type. 2. 0TFacilities Management Operations and Engineering staff will assist the Project Engineer in identifying the necessary valves or switching required to accommodate the tie-in of new utility systems or shutdown of existing systems for the project, an… 3. 0TThe Project Engineer is responsible to do a physical walkdown and verification of what systems and equipment are affected by the proposed shutdown. B. 0TRequirements for the specific discharge or disposal of water-based system drainage and flushing effluent shall be determined based on sampling and chemical composition of the effluent. C. 0TOutage and shutdown requirements shall be included in the bid documents by the Project Engineer. This information is required for scheduling, maintaining integrity of existing systems, and rerouting of services during construction. D. 0TThe following Deliverables are required to be provided during the Design phase: 1. 0TSummary of all required outages, and the type of outage. For multiple outages that may be required in the course of a complex project, a detailed conceptual construction phasing plan shall be developed. 2. 0TFor minor outages, a summary of work required and the impacts on each system for each outage shall be developed. 3. 0TFor major outages, a draft 0TUtility & Critical System Outage Checklist (OCL) 0Tshall be developed and filled out for each major outage. E. Utility & Critical System Outage Checklist(s) (OCL’s)0T and shutdown requirements shall be reviewed with FM Operations and Engineering staff, as well as with staff from other Brown departments, such as EH&S, CIS and DPS as required during the desig… 1. 0TDraft Outage schedule (time/date of when work will be performed and outage durations), including contingency communications for work that will extend beyond schedule. 2. 0TRequired prep work to be completed or to be in place prior to support the actual outage work (install portable generator(s), pipe flushing procedures, discharge permits, filling and venting procedures, etc.). |
| 70 | 3. 0TBrief description of the actual outage work and essential tasks being performed during the outage (Switches or valves being opened/closed, piping connections, etc.). 4. 0TNote key coordination issues that need to be included as a part of the outage (need for portable generators to maintain power, street closure(s), police details, etc.). 5. 0TFor hydronic systems, include how system draining, flushing, refilling and venting will be accomplished. 6. 0TIdentify disposal methods of system drain and flush effluent. 7. 0TFor building electrical system outages, include copies of the panelboard schedules for all affected electrical equipment (panelboards, switchboards, motor control centers, etc.). 8. 0TReview and identify any potential outage impacts that may affect ongoing critical Research and Academic activities: i.e.: campus water and/or electrical services; building ventilation and exhaust systems, BAS controls, etc. 9. 0TIdentify required outage lead time required based on FM Operations and Engineering input of project workload and outage complexity. 1.6 OUTAGE PLANNING PROCESS – CONSTRUCTION PHASE: A. 0TThe Construction Manager will utilize the 0TUtility & Critical System Outage Checklist 0Tdeliverables provided in the Design phase and incorporate all required outages into their project construction schedule as milestone activities. B. 0TThe Contractor shall utilize and update the draft 0TUtility & Critical System Outage Checklist(s) (OCL’s) 0Tbased on their proposed project schedule and plan for construction. C. 0TThe updated 0TUtility & Critical System Outage 0Tchecklist shall be used for required outage coordination review meetings to review and confirm the outage impacts and resources required to support the outage from Brown, the project team or others… 1. 0TProject impacts (what buildings, utility systems and/or system loads are impacted by the work). 2. 0TAny updates determined in the course of Contractor’s physical walkdown and verification of what systems and equipment are affected by the proposed shutdown. 3. 0TOutage schedule (time/date of when work will be performed and outage durations), including contingency communications for work that will extend beyond schedule; 4. 0TRequired prep work to be completed or to be in place prior to support the actual outage work (install portable generator(s), pipe flushing procedures, filling and venting procedures, etc.). 5. 0TBrief description of the actual outage work and essential tasks being performed during the outage (Switches or valves being opened/closed, piping connections, etc.); |
| 71 | 6. 0TNote key coordination issues that need to be included as a part of the outage (need for portable generators to maintain power, street closure(s), police details, etc.). 7. 0TFor hydronic systems, include how system draining, flushing, refilling and venting will be accomplished. 8. 0TFor building electrical system outages, include copies of the panelboard schedules for all affected electrical equipment (panelboards, switchboards, motor control centers, etc.). 9. 0TReview and identify any potential outage impacts that may affect ongoing critical Research and Academic activities: i.e.: campus water and/or electrical services; building ventilation and exhaust systems, BAS controls, etc. 10. 0TListing of key contacts and phone numbers for the Contractor, Brown FM staff, EH&S, CIS and DPS staff, and affected building staff. D. As a prerequisite of outage planning and preparations, it is the responsibility of the Contractor/project team to perform their own visual inspection and walk down to verify what utilities and systems will be physically affected by the shutdown. Th… 1. 0TVerify known systems and system loads that will be affected by the outage. 2. 0TIdentify any other undocumented systems and loads that may be affected by the proposed outage. 3. 0TVerify locations of existing system isolation switches, valves, bypasses, and temporary services. 1.7 OUTAGE REQUIREMENTS: A. Brown Environmental Health & Safety (EH&S) office shall be notified for all interruptions that affect building fire alarm and detection systems, fire suppression systems (fire sprinklers, kitchen hood suppression systems, dry systems, clean agent o… B. For Research facilities, EH&S shall be notified of all interruptions affecting: fume hoods, HVAC supply and exhaust systems, Potable and non-Potable water systems, electrical, heating and cooling systems and Process cooling systems. C. Brown Computing and Information Services (CIS) office requires notification for all communications systems and infrastructure outages and interruptions that affect telephone or network services. Notification shall be sent to: campuspoweroutages@br… D. Proper Lockout/Tagout procedures shall be followed by both the Contractor and FM staff. 1.8 SCHEDULING: A. Outage dates shall be coordinated with the Brown Academic calendar and identified blackout (no outage work) periods. |
| 72 | B. Independent Outages: Per Brown Project Manager discretion. C. Minor Outages: normal workday hours; 48-hour minimum advance notice. Weekend/off-hours; 72-hour minimum advance notice. Actual outage scheduling is subject to FM Operations staff availability. D. Major Outages: As determined by draft Utility & Critical System Outage 0Tchecklist0T: minimum (2) week notice after approval; (4) weeks is preferred for major shutdowns. E. FM Project Managers will assist the Constructor Manager in the scheduling, as well as the notification of, related building Users and other Brown departments affected by this work. 1.9 OUTAGE COORDINATION: A. The FM Project Manager shall coordinate the shutdown details required for the project with the FM Operations and Engineering staff, the project team, EH&S, DPS and CIS staff and the Building Users (as required by the particular system interruptio… B. A coordination meeting shall be held with representatives of the Contractor, affected building Users, and other concerned parties to review the planned outage sequences and timing. FM Operations, Service Response and Engineering staff will generall… C. A Utility and Critical System Outage Checklist (OCL) is required to be filled out for each major outage by the Project Design team and Contractor. The checklist includes relevant pre-outage work required prior to the outage, sequence(s) of work to … D. The FM Project Manager will submit the signed outage checklist to the Brown Service Response Office as well as a Project Support Service Order for the appropriate Divisional resource allocation to perform and monitor the shutdown. Service Response … 1.10 RECORD DRAWINGS A. New lines, valves, and switches installed as part of the project are to be included on the Campus Record Utility drawings. The architect or engineer shall include these details on the as-built documentation to be delivered at the completion of the … END OF SECTION |
| 73 | 01_17_91 |
| 77 | 01_17_92 |
| 78 | 01331C |
| 80 | 01341C |
| 84 | 01500CP TEMPORARY FACILITES AND CONTROLS PART 1 – GENERAL |
| 89 | 01501CP |
| 93 | 01701CPPR |
| 99 | 01702P |
| 100 | 01780C |
| 106 | 04_01_00 |
| 107 | 05_01_00 |
| 109 | 05_05_13 |
| 110 | 06_01_00 |
| 111 | 06_10_00 |
| 112 | 06_40_00 |
| 114 | 07_21_00 |
| 115 | 07_50_00 |
| 119 | 07_62_00 |
| 122 | 07_72_00 |
| 123 | 07_92_00 |
| 124 | 08_10_00 |
| 127 | 08_44_00 |
| 128 | 08_71_00 |
| 129 | 08_80_00 |
| 130 | 08500C |
| 132 | 08520CPPR |
| 141 | 08550CP |
| 143 | 08560CPR |
| 144 | 08595CPR |
| 146 | 08720C |
| 147 | 08750C |
| 148 | 09_21_16 |
| 149 | 09_30_00 |
| 150 | 09_51_00 |
| 151 | 09_60_00 |
| 153 | 09_72_00 |
| 154 | 09_90_00 |
| 157 | 09800C |
| 158 | 10_11_00 |
| 159 | 10_14_00 |
| 161 | 10_28_13 PART 1 GENERAL Design guidelines A. In most locations; Brown uses electric hand dryers and no paper towels. In some buildings, paper towels are also required; review with Brown Project Manager. B. Provide a hose bib at 18” AFF in toilet rooms. And floor drains located near toilets (most frequent overflow issue). C. Locate Mirrors enough above sinks to minimize splash-back (mirror constantly looks dirty in those situations). D. Provide blocking as required for each item. PART 2 PRODUCTS 2.1 MATERIALS A. Toilet and Bath Accessories: Furnished by Brown University for installation by Contractor. 1. Toilet Tissue Dispenser: Dual Roll GP56784 dual roll, GP56744 quad roll, with GP compact coreless bath tissue. 2. Towel Dispenser: GP “Soft Pull” 59489. Do not install unless approved by Brown Project Manager (ie not normally installed when electric hand dryers are used). 3. Soap Dispenser: GOJO CX 8500-01 (counter mount); GOJO FMX 5250-06 (wall mount). 4. Shower Soap Dispensers: review current preference with Director of Custodial Services. B. Toilet and Bath Accessories: Furnished and installed by Contractor. 1. Grab Bars: Bobrick B-6806.99 Series, 1-1/2 inch diameter, satin finish, 1-1/2 inch wall clearance, concealed mounting with snap flange, stainless steel, peened grip. 2. Mirrors: Bobrick B-290 stainless steel framed mirrors, sizes as indicated on the Drawings. 3. Napkin/Tampon Vendor, 50 cents, Surface Mounted, Bobrick B-2706, stainless steel. 4. Sanitary Napkin Disposal, Surface Mounted, Bobrick B-5270 or B-254, stainless steel. 5. Seat Cover Dispenser – generally not provided 6. Electric Hand Dryers: XLERATOR by Excel. 7. Baby Changing Station: Koala Kare Products Horizontal Surface-Mounted Baby Changing Station, plastic liner and stainless steel cover and frame. KB200-00 or KB 110-SS. Can be recessed. 8. Shower Seats – Bobrick 5191-DB 9. Waste Receptacle – Bobrick B-3644 or B-43644 (curved). PART 3 EXECUTION A. Electric Hand Dryers 1. Test and verify operation. The source electrical panel and circuit shall be labeled at the dryer for reference. |
| 162 | 10_81_00 |
| 163 | 10260C |
| 164 | 10410C |
| 165 | 12_00_00 |
| 166 | 12_20_00 |
| 167 | 14_20_00 |
| 168 | 15001C |
| 171 | 15001PPRS |
| 176 | 15114PPR |
| 177 | 15140CPPRS |
| 189 | 15141CPPR |
| 190 | 15142CPPR |
| 191 | 15143CP |
| 192 | 15150CP |
| 197 | 15151P |
| 198 | 15152S |
| 199 | 15160P |
| 201 | 15161PR |
| 202 | 15300C |
| 203 | 15301C |
| 204 | 15302C |
| 205 | 15304C |
| 206 | 15310PPR |
| 208 | 15412CP |
| 214 | 15415PR |
| 215 | 15441CPPR |
| 216 | 15442CPPR |
| 217 | 15443CP |
| 218 | 15480P |
| 220 | 15481P |
| 221 | 23_00_10 1.1 SUMMARY: 1.2 BACKGROUND: 1.3 DESIGN SUBMITTAL REQUIREMENTS: 1. By first submittal or Schematic Design, whichever is earlier: Design narrative / design intent with description of each system, including flow diagram of the proposed system. 2. By second submittal, or Design Development phase, whichever is earlier: Basis of Design, including the following: |
| 222 | a. Space design conditions – indoor temperature / humidity design conditions, outdoor design basis b. Hours of Operation for occupied spaces c. Seasonal system availability for central utility systems (heating and cooling) d. Energy design criteria e. Acoustic design criteria f. Description of each system including: sizing, redundancy, and interconnections with central utilities, etc., with flow diagrams g. BAS sequences of operation h. Deviations from Brown Standards 3. Energy model for larger projects, for projects seeking LEED certification, and for projects requiring comparison of HVAC system options. 4. By third submittal, final review set, or construction documents, whichever is earlier: a. Deviations from previous submittals b. Deviations from Brown Standards c. Final Design Development information with updates noted d. Schedule of Equipment Operation based on intended space occupancy e. Accessibility Drawing detailing accessibility for equipment rigging/ installation as well as access to equipment for routine operation, service and maintenance. 1.4 GENERAL DESIGN REQUIREMENTS: |
| 223 | 1.5 DETAILED HVAC DESIGN REQUIREMENTS: |
| 225 | 1.6 MECHANICAL ROOM DESIGN REQUIREMENTS: 1.7 NAMING CONVENTIONS and EQUIPMENT LISTS: 1.8 VENTILATION: |
| 226 | 1.9 UTILITIES – HEATING: 1.10 UTILITIES – COOLING: |
| 227 | 1.11 HYDRONIC SYSTEMS – BUILDINGS: |
| 228 | 1.12 MOTOR ALIGNMENT: 1.13 INSULATION: 1.14 WATER TREATMENT: 1.15 REFRIGERANTS AND RELATED SYSTEMS: |
| 229 | 1.16 SOUND, VIBRATION AND SEISMIC CONTROL: 1.17 AIR DISPERSION: |
| 230 | 1.18 HEAT RECOVERY: 1.19 LABORATORIES & RESEARCH FACILITIES: 1.20 TUBE-IN-SHELL HEAT EXCHANGERS: |
| 231 | 1.21 Plate and Frame Heat Exchangers 1.22 CLEAN-STEAM GENERATORS AND HUMIDIFIERS: |
| 232 | 23_05_23 PART 1 – GENERAL 1.1 SUMMARY: 1. Section 01 17 01 – Building Systems Labeling and Identification. 2. Section 23 00 10 – HVAC Design Criteria 3. Section 23 09 00 – Building Automation Systems Design Criteria 1.2 GENERAL VALVE APPLICATION REQUIREMENTS: 1. Provide drain valves (ball-type) at all equipment connections and at all low points in the piping system to allow for complete drainage. 2. Drain connections shall have full-size threaded hose end with cap/plug. Caps shall be solid threaded brass with pressure rating equal to 1.5 times system design pressure. “Dust caps” are not acceptable. |
| 233 | 3. For piping up to 4-inches, provide minimum 3/4-inch valves. 4. For piping between 4 and 10 inches, provide minimum 1-1/2 – inch valves. 5. For piping greater than 10-inches, provide 2-inch valves. 1.3 DETAILED VALVE APPLICATION REQUIREMENTS: PART 2 – PRODUCTS 2.1 GATE VALVES: 1. HTHW Service: OS & Y, steel body, socket weld ends, Class 600. 2. MTHW/CHW Service: Use ball valves. 1. HTHW Service: OS & Y. steel body, flanged or welded ends; Class 300. 2. MTHW/CHW Service: Use ball or butterfly valves. 2.2 GLOBE VALVES: 2.3 BALL VALVES: 1. Low Pressure Steam (< 15 Psig), low pressure condensate and all other normal non-corrosive services, ball valves shall be: a. Body Bronze b. Body Style Standard Port c. Trim 316 Stainless Steel Ball & Stem. d. Seat Reinforced Teflon (RTRE), 15 glass filled, double seal. |
| 234 | e. Seat Working P/T 300 psig@250 F Minimum f. Body Working P/T 300 psig@300 F Minimum g. WOG Rating 300 psig Minimum h. Steam Rating 150 psig Minimum. i. Manufacturers: Apollo, Lance, Jamesbury, Watts 2. High Pressure Steam (>15 PSI) shall be: a. Body Carbon A106 or A1 material, ½ chrome, 1/2 moly or 316 Stainless Steel b. Body Style Standard Port, butt or socket welded c. Trim 316 Stainless Steel Ball & Stem. d. Seat High Temp. PTFE, double seal e. Seat Working P/T 100 psig@450 F Minimum f. Body Working P/T 750 psig @100 F Minimum g. WOG Rating 400 psig Minimum. h. Steam Rating 100 psig@450 F Minimum i. Manufacturers: Apollo, Lance, Jamesbury, Watts 2.4 BUTTERFLY VALVES: 1. Manufacturers: Flowseal, Bray, Neles-Jamesbury, DeZurik, Posi-Seal, Zwick (Tri-Con series) or Milwaukee. 1. Manufacturers: Adams type MAK, Flowseal type TOV, Bray, Neles-Jamesbury, DeZurik, Posi-Seal, Zwick (Tri-Con series) or Milwaukee. 2.5 SWING CHECK VALVES – Horizontal Service: 1. Class 150 minimum or as required for service, bronze body and cap, bronze swing disc with rubber seat, solder ends. 2. HTHW Service: Class 300, steel body. Flanged ends. 3. Steam Service: Class 300, malleable iron with stainless-steel 20 mesh strainer. For condensate service, use spring check. 1. Class 250 minimum or as required for service, iron body, bronze swing disc, renewable disc seal and seat, flanged ends. 2. HTHW Service: Class 300, steel body, flanged ends. |
| 235 | 2.6 SPRING LOADED CHECK VALVES: 2.7 RADIATOR VALVES: 2.8 WATER PRESSURE REDUCING VALVES: 1. Construction: Bronze body, stainless steel and thermoplastic internal parts, fabric reinforced diaphragm, strainer, threaded and single union ends. Provide hex locking adjustment nut and integral pressure gage. 1. Construction: MSS SP-85, cast iron body, bronze fitted, elastomeric diaphragm and seat disc, flanged. 2.9 RELIEF VALVES: PART 3 – EXECUTION: 3.1.1 GENERAL: 3.1.2 LABELING AND IDENTIFICATION: |
| 236 | 23_09_00 |
| 250 | 23_09_01 Section 23 09 01 – BUILDING AUTOMATION SYSTEMS POINT NAMES, DESCRIPTIONS, GRAPHICS AND ALARMING 1.1 SUMMARY: 1.2 DISPLAY AND NAMING CONVENTIONS: 1.3 ALARMS and ALARM REPORTING: |
| 252 | 23_20_00 PART 1 – GENERAL 1.1 SUMMARY: B. Related Sections: 1. Section 01 17 0 1 – Building Systems Labeling and Identification. 2. Section 23 00 10 – HVAC Design Criteria 1.2 GENERAL PIPING APPLICATION REQUIREMENTS: 1. The approved manufacturer is Perma-Pipe and the approved types are “Multi-therm 500” and “Polytherm”. PART 2 – PRODUCTS: 2.1 HIGH TEMPERATURE HOT WATER PIPING: 1. Materials: ASTM A53 or A106, Grade B, seamless. 2. Wall thickness: a. Up to and including 2 inch diameter: Schedule 80, socket weld ends. b. Above 2 inch: Schedule 40, butt-weld ends. 3. Fittings: Socket-weld up to and including 2 inch, butt-weld above 2 inch. 4. Below-Grade: Preinsulated Perma-Pipe “Multi-therm 500”. |
| 253 | 2.2 HEATING WATER AND GLYCOL PIPING: 1. Fittings: Malleable iron or forged steel, minimum 150 pound service rating. 2. Joints: Screwed through 2”, or welded in any size. 3. Below-Grade: Preinsulated Perma-Pipe “Polytherm” 1. Fittings: Cast brass, or ASME B16.22 solder wrought copper. 2. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Mechanical joints: “Pro-Press”. 2.3 CHILLED WATER PIPING: 1. Fittings: Malleable iron or forged steel, minimum 150 pound service rating. 2. Joints: Screwed through 2”, or welded in any size. 3. Below-Grade: Preinsulated Perma-Pipe “Polytherm” 1. Fittings: Cast brass, or ASME B16.22 solder wrought copper. 2. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Mechanical joints: “Pro-Press”. 2.4 CONDENSER WATER PIPING: 1. Fittings: Fittings: Malleable iron or forged steel minimum 150 pound service rating; grooved piping permissible if piping not required to be insulated. 2. Joints: Welded. 3. Below-Grade: Preinsulated Perma-Pipe “Polytherm” 1. Fittings: Cast brass, or ASME B16.22 solder wrought copper. 2. Joints: Solder shall be lead-free tin and silver, with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Mechanical joints: “Pro-Press”. 2.5 RADIANT HEATING PIPING: 1. Fittings: Cast brass, or ASME B16.22 solder wrought copper. 2. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Mechanical joints: “Pro-Press”. 1. Fittings: Copper or PEX. 2. Joints: Nipple with stainless steel clamp. |
| 254 | 2.6 MEDIUM AND HIGH PRESSURE STEAM PIPING 150 PSIG MAXIMUM: 1. Fittings: Malleable iron Class 250, or forged steel welding type, Class 300. 2. Joints: Threaded or welded. 3. Below-Grade: Preinsulated Perma-Pipe “Multi-therm 500”. 2.7 LOW PRESSURE STEAM PIPING 15 PSIG MAXIMUM: 1. Fittings: Malleable iron or forged steel, minimum 150 pound service rating 2. Joints: Threaded or welded. 3. Below-Grade: Preinsulated Perma-Pipe “Multi-therm 500”. 2.8 MEDIUM AND HIGH PRESSURE STEAM UP TO 150 PSIG MAXIMUM CONDENSATE PIPING: 1. Fittings: Malleable iron Class 250, or forged steel welding type, Class 300. 2. Joints: Threaded or welded. 3. Below-Grade: Preinsulated Perma-Pipe “Multi-therm 500”. 2.9 LOW PRESSURE STEAM CONDENSATE PIPING: 1. Fittings: Malleable iron or forged steel Class 150. 2. Joints: Threaded, or welded. 2.10 CLEAN STEAM MAKEUP WATER LINES: 1. Copper Tubing: Type L hard drawn. a. Fittings: Cast brass, or ASME B16.22 solder wrought copper. b. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. c. Mechanical joints: “Pro-Press”. 2. Stainless steel, schedule 10. 1. Stainless steel, schedule 10 2.11 EQUIPMENT DRAINS AND OVERFLOWS: 1. Fittings: Galvanized cast iron, or malleable iron. 2. Joints: Threaded, or grooved mechanical couplings. 1. Fittings: Cast brass, or ASME B16.22 solder wrought copper. |
| 255 | 2. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Mechanical joints: See Part 1. 2.12 ENGINE EXHAUST: 1. Fittings: Malleable iron or forged steel welding type. 2. Joints: Threaded for pipe 2 inch and under; welded for pipe over 2 inch. 2.13 REFRIGERANT PIPING: 1. Fittings: Wrought copper. 2. Joints: Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 1. Fittings: Cast copper. 2. Joints: Flared or soldered. Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. 2.14 UNIONS, FLANGES, AND COUPLINGS: A. Unions for Pipe 2 inches and Under: 1. Ferrous Piping: malleable iron, threaded, 300 PSIG service rating. 2. Copper Pipe: Bronze, soldered joints. Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. B. Flanges for Pipe Over 2 inches: 1. Ferrous Piping: 150 psig service: forged steel, slip-on. 300 psig service: 300 psig rated. 2. Copper Piping: Bronze. If soldered, solder shall be lead-free tin and silver, with melting range 430 to 535 degrees F, or silver solder minimum 5%. 3. Gaskets: 1/16 inch thick preformed neoprene for service under 250 degrees F. Above 250 degrees F, use spiral wound 304 stainless steel similar to “Flexitaulic”. C. Grooved and Shouldered Pipe End Couplings where permitted (See Part 1): 1. Housing Clamps: Malleable iron to engage and lock designed to permit some angular deflection, contraction, and expansion. 2. Sealing Gasket: C-shape elastomer composition for operating temperature range from -30 degrees F 230 degrees F. 3. Accessories: Steel bolts, nuts, and washers. D. Dielectric Connections: Union with galvanized or plated steel threaded end, copper solder end, and water impervious isolation barrier. Solder shall be lead-free tin and silver with melting range 430 to 535 degrees F, or silver solder minimum 5%. E. For Glycol service, provide compatible metals for all vents and fittings connecting to pipe. |
| 256 | 2.15 FLEXIBLE CONNECTORS: A. Corrugated stainless steel or bronze hose with single layer of stainless steel exterior braiding, minimum 9 inches long with copper tube ends; for maximum working pressure as required by specific project. If soldered, solder shall be lead-free tin… B. At end-suction and split-case pump inlets and discharges, steel-reinforced rubber connections with threaded rod restraints are preferred. PART 3 – EXECUTION: 3.1 INSTALLATION: A. Route piping parallel to building structure and maintain gradient. B. Install piping to conserve building space, and not interfere with use of space. C. Group piping whenever practical at common elevations. D. Provide access covers in finished surfaces where valves and fittings are concealed. E. Slope piping and arrange systems to drain at low points. Use eccentric reducers to maintain invert of pipe level. 1. Slope steam piping one inch in 40 feet in direction of flow. Use eccentric reducers to maintain bottom of pipe level. 2. Slope steam condensate piping one inch in 20 feet. Provide drip trap assembly at low points, before control valves and at the end of lines where piping is dead-ended. Run condensate lines from trap to nearest condensate receiver. Provide loop ven… F. For condensate piping draining from chilled water coils, use copper piping only. Provide ball valves at intervals in the piping mains and unions at all branches to facilitate maintenance and repair. Install line-size clean-outs at every change in d… G. Arrange refrigeration piping to return oil to compressor. Provide traps and loops in piping, and where necessary provide double risers. Slope horizontal piping 0.40 percent in direction of flow. H. Install flexible couplings only where required for vibration isolation; orient with respect to rotating equipment and install per manufacturer’s direction. Misaligned piping shall not be permitted to be connected with vibration isolators. I. Flexible connectors are not permitted at any in-line pump location. J. Provide for minimal recirculation in all hydronic systems – minimize use of dead legs. K. Label all piping per requirements of section 01 17 0 1 – Building Systems Labeling and Identification. |
| 257 | A. After flushing, clean systems by circulating and draining water a minimum of 2 times. Where work is an expansion or modification to an existing piping system, cleaning or flushing is to include the existing system or portions of the existing system… B. For high temperature hot water systems, add alkaline boil-out chemical. C. Coordinate with project manager for required permits to dispose of flush water. D. Remove all construction strainers and replace with normal at completion of the project. 3.3 TESTING: D. Radiograph 100% of all welds for underground piping for chilled water and medium temperature hot water systems. |
| 258 | 23_52_00 PART 1 – GENERAL 1.1 SUMMARY 1. Section 01 13 01 – Design Guidelines for Energy and Environment 2. Section 01341C – FM Global Criteria 3. Section 23 00 10 – HVAC Design Criteria 4. Section 23 09 00 – Building Automation Systems Design Criteria 1.2 WARRANTY: 1.3 SUBMITTALS: 1.4 GENERAL REQUIREMENTS: |
| 259 | 1.5 ELECTRIC BOILERS: 1.6 CONDENSING BOILERS: 1.7 OTHER BOILERS: 1.8 BOILER TRIM AND ACCESSORIES: 1. Extend safety relief valve drain to within 6 inches of existing floor drains with full-size ASTM B88 copper or ASTM A53 iron pipe. 2. Support piping every 6 feet maximum, with wall or floor anchors. 3. For boilers over 1 MMBTH: Low water cut-off, or loss-of-flow sensor, and alarm contacts. 1. Provide drip elbows for safety relief valves and extend drain to within 6 inches of existing floor drains with ASTM A53 iron pipe. 2. Provide surface blowdown and pipe to drain. 3. Support piping every 6 feet maximum, with wall or floor anchors. 4. Terminate safety relief vent outside in accordance with local Code requirements. 5. For Boilers over 1MMBTH: low and high water level switches and alarm contacts 1.9 BOILER FEED AND MAKEUP WATER: |
| 260 | 1.10 CONTROLS: PART 2 – PRODUCTS: 1. Condensing Boilers: Camus (DF Series), Lochinvar (Knight or SYNC Series), Harsco (MACH Series), or RBI (Infinite). 2. Electric Boilers: Sussman, Lochinvar and Cleaver-Brooks. 3. Other boilers: Weil-McLain, Cleaver-Brooks, Bryan and Burham. PART 3 – EXECUTION: 3.1 GENERAL: |
| 261 | 3.2 STARTUP AND TRAINING: |
| 262 | 23_64_00 1.1 SUMMARY: A. This section includes design and performance requirements for various types of chiller systems. B. Related Sections: 1. Section 01 13 01 – Design Guidelines for Energy and Environment 2. Section 23 00 10 – HVAC Design Criteria 3. Section 23 09 00 – Building Automation Systems Design Criteria 4. Section 26 00 10 – Electrical Design Criteria 5. Section 28 35 00 – Refrigerant Detection and Alarm Systems 1.2 WARRANTY: 1.3 SUBMITTALS: 1.4 GENERAL CHILLER DESIGN REQUIREMENTS: |
| 263 | 1.5 DETAILED CHILLER DESIGN REQUIREMENTS: |
| 264 | 1.6 CONTROLS: 1.7 FILTRATION AND WATER TREATMENT: 2.1. MANUFACTURERS: 1. Carrier, McQuay, York (water cooled) 2. Carrier, McQuay, York, Trane (air –cooled ) 3. Multistack (modular) |
| 265 | 23_70_00 PART 1 – GENERAL 1.1. SUMMARY 1. Section 23 00 10 – HVAC Design Criteria. 2. Section 23 09 00 – Building Automation Systems Design Criteria 3. Section 26 05 90 – Motors 4. Section 26 29 23 – Variable Speed Drives 1.2. SUBMITTALS: 1. Manufacturer, model, type, finishes of materials, dimensions & weights; 2. Unit air flow and arrangement data; 3. Filter data; 4. Airflow capacity, external static pressure, total static pressure; 5. Motor HP & electrical characteristics; 6. Heating coil data; 7. Cooling coil data; 8. Water flow data; filter media, filter sizes, and filter quantities. 1.3. AIR HANDLERS – GENERAL REQUIREMENTS: 1.4. AIR HANDLERS – DETAILED REQUIREMENTS: 1. Combined height of pad and casing floor shall permit required drain trap depth. |
| 266 | 2. Access Doors: Access doors shall be provided between each air handler component to ensure access and cleanability of the air handler. Each door shall have a minimum of two securing latches, which also operate from inside the unit. Doors in positiv… 3. Casings shall be double-wall construction, with manufacturer’s standard insulation between interior and exterior walls. 4. Provide drain pans, pitched toward the side of the unit for all steam humidification coils and cooling coils to allow for proper trapping of lines. 1. Direct-drive fans are preferred. 2. Fan motor: Totally-enclosed, premium efficiency, inverter-duty rated. See Section 26 05 90 – Motors for additional requirements. 3. Fans shall be statically and dynamically tested as an assembly at the required RPM to meet design specifications. 4. Provide self-aligning, grease lubricated heavy duty sealed or pillow-block bearings. For pillow-block type bearings extend grease lubrication fittings to drive side of unit. 1. Provide return, outside air, and exhaust dampers and controls for a fully functional 100% outside air economizer cycle when design conditions permit. 1. Freeze Protection: Cooling coils shall have non-trapping circuits to facilitate seasonal drainage. 2. In research buildings, provisions to eliminate the need for drainage shall be made, such as the installation of freeze pumps. 3. Steam preheat coils shall be freeze-proof type, tube-in- tube. 1. Prefilter: 2-inch 30% eff. Pleated (MERV 7/8) a. Manufacturer: Camfil-Farr 30/30, or equal 2. Final Filter: 12-inch 85% eff. (MERV 13) a. Manufacturer: Camfil-Farr “Durafill”, or equal 3. Final Filter: (High Moisture Applications) 85% eff. (MERV 13) a. Manufacturer: Camfil-Farr “Hi-Flo ES”, or equal 4. Provide Magnehelic Differential Pressure gage across each filter bank, scale 0-5” water column or as required; for units rated over 4,000 CFM, also provide a differential pressure transducer connected to the BAS. 1. Multi-zone dampers shall be type as required, mounted on stainless steel shafts and stainless steel bearings. |
| 267 | 2. Outside air, return air and exhaust dampers, and Face and Bypass dampers shall be internally-mounted, low leakage type. Provide as opposable blade type, mounted on stainless steel shafts and stainless steel bearings. 1. Provide Marine-style lights for all fan sections, access sections and mixing box sections. Control lights with an exterior-mounted light switch with pilot light. 2. Provide access door double-pane view ports. 3. Provide air blender to provide mixing of air to prevent stratification (if mixing box is not configured to prevent OA/RA stratification). 4. Air Flow Measurement Station: When required, provide electronic type air measurement station. 5. Variable Frequency Drives: When required, provide Variable Frequency Drives (VFD’s) on fan motors. See Section 26 29 23 – Variable Frequency Controllers for requirements. PART 2 – PRODUCTS 2.1 PREFERRED MANUFACTURERS 1. Custom Units: Cambridgeport, Haakon, Ventrol 2. Factory Packaged Units: Aaon, Carrier, McQuay, Trane, York PART 3 – EXECUTION 3.1 INSTALLATION: 1. Make all connections from supply lines to coils with unions or flanges to facilitate coil removal. 2. Connect water supply to leaving airside of coil (counter flow arrangement). 3. Locate water supply at bottom of supply header and return water connection at top. 4. Install water coils to allow draining and install drain connection at low points. |
| 268 | 26_00_10 SECTION 26 00 10- ELECTRICAL DESIGN CRITERIA 1.1 SUMMARY: 1.2 Background: 1.3 RELATED SECTIONS: 1.4 DESIGN SUBMITTAL REQUIREMENTS: 1. Design narrative / design intent with description of each system. 1. Basis of Design, including the following: a. Load design criteria |
| 269 | b. Description of each system including: including One-Line diagram of the proposed system(s). c. Lighting and fire alarm system controls and sequences of operation. 2. Deviations from Brown Standards. 1. Deviations from previous submittals 2. Deviations from Brown Standards 3. Final Design Development information with updates noted. 4. Accessibility Drawing detailing accessibility for equipment rigging/ installation as well as access to equipment for routine operation, service and maintenance. 1.5 DESIGN CALCULATIONS: 1. Fault current availability (Short Circuit Analysis), to determine the worst-case fault current at each major equipment location. This study is required for proper selection and verification of powered mechanical equipment and electrical distributio… 2. Load calculations and building power requirements for sizing of electrical distribution equipment, transformers and feeders. For modifications to existing building systems, verify existing system loads and perform analysis to evaluate impact of ne… 3. Emergency and legally required standby power requirements and equipment sizing. For additional loads to be added to existing Emergency systems, coordinate with the Brown University Project Manager to determine existing system loading and spare capa… 4. Short circuit and coordination studies for fuse sizing and selection of adjustable trip circuit breakers, relays and other circuit protective devices. 5. Voltage drop (on long, low-voltage circuit runs). 1.6 Arc Flash and Overcurrent Device Coordination Studies: 1. Short circuit and overcurrent device coordination study: perform studies in accordance with IEEE “Red Book” standard 141 for all service and distribution equipment. Overcurrent device coordination study to include time-current plots for phase and g… |
| 270 | 2. Arc-flash protection studies, provision and installation of specific equipment Arc-flash labeling for determination of the level of incident energy available and required personnel hazard protection, per IEEE 1584 and NFPA 70E requirements. 3. Power system harmonic analysis study: required for all applications involving loads with high concentrations of harmonic content, such as server racks, data processing equipment and variable speed drives for motors over 25 HP. Analysis shall includ… 1.7 MISCELLANEOUS REQUIREMENTS: |
| 271 | 1.8 GENERAL ELECTRICAL DESIGN REQUIREMENTS: 1. Mechanical equipment and lighting panels should be 480Y/277V. 2. Distribution step down transformers should provide 208Y/120V to panels serving convenience power and receptacle loads. 1.9 RELIABILITY AND REDUNDANCY CONSIDERATIONS FOR FACILITIES: |
| 272 | 1. Double-ended switchgear/building service transformers, in a “main-tie-main” configuration, and connected to the primary distribution system in a “loop-fed” primary configuration. The switchgear/building service transformers shall be sized such that… 2. Installation of permanent provisions at building exterior wall for ready connection of a roll-up generator to the building main switchboard. 1.10 EMERGENCY AND STANDBY POWER CONSIDERATIONS: 1. “Tri-Star”- brand portable generator connection box (or equal), located on the building exterior. Connection box provided as a NEMA 3R enclosure, with Cam-Lok cable connectors, capacity as required, and phase rotation meter. 2. Wired connection from connection box to dedicated circuit breaker, key-interlocked to building main service circuit breaker, to prevent simultaneous closure of both devices. |
| 273 | 1.11 ELECTRICAL SPACE PLANNING GUIDES: 1.12 ELECTRIC ROOM DETAILED DESIGN GUIDES: 1.13 ELECTRIC METERING: |
| 274 | 1.14 EQUIPMENT MANUFACTURERS: 1.15 NAMING CONVENTIONS and EQUIPMENT LISTS: 1.16 ACCEPTANCE TESTING: |
| 275 | 26_00_20 |
| 281 | 26_05_10 PART 1 – GENERAL 1.1 SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 26 00 10 – Electrical Design Criteria 1.2 QUALITY ASSURANCE: 1.3 GENERAL REQUIREMENTS: 1. MC cable used for Building Automation System (BAS) control wiring: Blue 2. MC cable used for fire alarm wiring: red 1.4 CABLE APPLICATIONS: A. Following is a summary of where various common types of cable installation methods are allowed. All other wiring installations shall be run in conduit. B. Type NMR (Romex) cable: 1-3 family residential facilities, run concealed for branch circuit power, lighting, fire and carbon monoxide circuit wiring only. C. Type UF cable: irrigation systems, run underground. D. Type AC cable (jacket used as ground): Not allowed. E. Type MC cable (with full-rated ground conductor): standard (steel) jacket and “MC-Light” aluminum jacket acceptable. 1. Cable allowed after the first pull-point from the local branch circuit distribution panel; final connections to distribution panel to be run in conduit. |
| 282 | 2. All facilities, dry interior, non-classified locations only, where run concealed within accessible walls and above accessible (hung) ceilings. Accessible walls are walls that have an accessible (hung ceiling) on at least one adjacent side. a. Electrical branch circuits, equipment feeders rated less than 30 amps and control circuits (equipment and distribution panel feeders rated over 30 amps to be run in conduit). b. Fire alarm circuits, notification and detection circuits and controlled device circuits (home run circuits from floor to floor and from main panel to subpanels to be run in conduit). 3. Residential facilities with hard (plaster) ceilings, dry interior locations: a. Electrical branch circuits, equipment feeders rated less than 30 amps and control circuits (equipment and distribution panel feeders rated over 30 amps to be run in conduit). b. Fire alarm: notification and detection circuits and controlled device circuits (home run circuits from floor to floor to be run in conduit). c. Carbon monoxide detector circuits and smoke detector circuits. F. Power-limited control wiring (BAS controls, telecommunications wiring, Audiovisual control wiring, etc.): All facilities, dry interior locations only, run concealed within accessible walls and above accessible (hung) ceilings. Accessible walls are… G. Cabling run exposed within return air plenum spaces shall be rated for the application (low smoke jacketed cable). H. Type SO and SJO Cables (with full-rated ground conductor): All facilities, dry interior locations only. Use for portable equipment rated less than 30 amps. Larger loads shall be hard-wired. 1.5 TERMINATIONS: A. Splices and taps under 600 volts: 1. 10 AWG and smaller: copper compression type or twist-on metal spring-type connectors with color-coded insulating nylon covering. Connectors for exterior and direct burial use shall be listed for the application. 2. 8 AWG and larger: hydraulic compression connectors, mechanical bolted pressure type, such as ILSCO Clear tap, or listed insulated terminal blocks. B. Cable lugs and Terminations under 600 volts: 1. 10 AWG and smaller: copper compression type with color-coded insulating nylon covering. 2. 8 AWG and larger: hydraulic compression connectors, pre-filled with anti-oxidant compound. 3. Lug connections to bus bars: provide with tin-plated lugs and “Belleville” style washers. 4. Tape all terminations to match cable insulation rating. C. “Push-on” type terminators and splice taps are not acceptable. |
| 283 | PART 2 – PRODUCTS Not Used PART 3 – EXECUTION 3.1 EXISTING WORK: A. Remove exposed abandoned wire and cable, including abandoned wire and cable above accessible ceiling finishes. Patch surfaces where removed cables pass through building finishes. B. Disconnect abandoned circuits and remove circuit wire and cable. Remove abandoned boxes when wire and cable servicing boxes is abandoned and removed. Install blank cover for abandoned boxes not removed. C. Provide access to existing wiring connections remaining active and requiring access. Modify installation or install access panel. D. Clean and repair existing wire and cable remaining or is wire and cable to be reinstalled. 3.2 INSTALLATION: A. Identify wire and cable under provisions of Section 01701. Identify each conductor with its circuit number or other designation indicated. B. All wiring and cabling shall be run in a neat and workmanlike manner; routed parallel or perpendicular to walls, beams, ceiling supports and building structure. C. Cables shall be directly supported to building structure and independent of other piping, mechanical equipment or ceiling supports. Cable supports shall be devices such as “caddy clips” and “bridle ring” supports and “J hooks”, listed for the inten… D. Nylon tie wraps are not acceptable for cable supports; they are acceptable for cable training and bundling. E. Splices and terminations shall be made only within accessible outlet or junction boxes or equipment connection boxes. 3.3 WIRE COLOR: A. General: 1. For wire sizes 6 AWG and smaller, install wire colors in accordance with the following: a. Black and red for single phase circuits at 120/240 volts. b. Black, blue, and red for circuits at 120/208 volts single or three phase. c. Brown, orange, and yellow for circuits at 277/480 volts single or three phase. 2. For wire sizes 4AWG and larger, identify wire with colored tape at terminals, splices and boxes. Colors are as follows: a. Black and red for single phase circuits at 120/240 volts. |
| 284 | b. Black, blue, and red for circuits at 120/208 volts single or three phase. c. Brown, orange, and yellow for circuits at 277/480 volts single or three phase. B. Neutral Conductors: White for 120/240 and 120/208 volt circuits, and gray with a yellow tracer for 277/480 volt circuits. When two or more neutrals are located in one conduit, individually identify each with proper circuit number. When a common … C. Ground Conductors: 1. For 6 AWG and smaller: Green. 2. For 4 AWG and larger: Identify with green tape at both ends and visible points including junction boxes. |
| 285 | 26_05_19 PART 1 – GENERAL 1.1 SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 26 00 10 – Electrical Design Criteria 1.2 QUALITY ASSURANCE: 1.3 MEDIUM-VOLTAGE DISTRIBUTION SYSTEM DESIGN REQUIREMENTS: 1. Minimize routing of medium-voltage distribution circuits within occupied portions of buildings. Where such circuits are run through a building, install within galvanized, rigid steel conduit, painted orange and labeled for the circuit voltage conta… 2. Within dedicated building electrical service rooms and vaults: galvanized rigid steel conduit or wireways. Exposed cable is not acceptable. 3. Underground: concrete-encased ductbank. 4. Above ground: galvanized, rigid steel conduit, painted orange and labeled for the circuit voltage contained within them. 5. Within dedicated high voltage electric rooms and substations, where not subject to mechanical damage: EMT conduit, galvanized rigid steel conduit or in cable tray. 1.4 MEDIUM-VOLTAGE CABLE – 5KV and 15KV CLASS: |
| 286 | 1.5 TERMINATORS: 1. Elastimold 35MSC series; 2. 3M QT-3 tubular series; 3. RAYCHEM TFT-R cold-shrink kits. 1. 600 amp 5 and 15 KV: Elastimold 656LR series elbow kit with ground adapter and IEEE386 capacitive test points. 2. 200 amp 5 and 15 KV: Elastimold 166LR series elbow kit with ground adapter and IEEE386 capacitive test points. 3. Fused 5 KV class elbows: Elastimold 166FLR series elbow kit with fuse and (2) IEEE386 capacitive test points. 1. Raychem ESC 2. 3M EC series 1. MOV, Elastimold BSA elbow/bushing type. 1.6 SPLICES: 1. Elastimold premolded “T” assembly, series 655LR with shield grounding device, sized for the cable. 1. Elastimold premolded straight assembly, series 151SP or pre-molded “T” assembly, series 150T, sized for the cable. 1.7 JUNCTIONS: 1. Cooper “Multipoint” 2. Elastimold 650J 1.8 FAULT DETECTORS/ INDICATORS: |
| 287 | 1.9 FIREPROOFING: 1.10 LABELING and CABLE IDENTIFICATION: 1. Plastic 10-mil plastic heat-laminated typewritten paper tags, double-sided, with brass grommet, and tie-wrapped to each cable. Tags shall include the following information: 2. Cable section identification 3. Location of cable tag (ie., manhole number) 4. Cable size, type and voltage rating 5. Cable origin (switchgear and switch number) 6. Cable destination (switchgear and switch number, or Building and disconnect switch location) 7. Date of installation 8. 11 KV cable tags are to be colored orange, 4.16 KV cable tags are to be colored blue. PART 2 – PRODUCTS 2.1 CABLE 1. Okonite 2. Pirelli 3. General Cable PART 3 – EXECUTION 3.1 EXISTING WORK: 3.2 CABLE INSTALLATION – GENERAL: |
| 288 | 1. Arrange pulling equipment to minimize side loads on duct banks and enclosures, and maximize the bending radius of the cables. 2. Maintain a minimum bending radius of 10 times the cable diameter. 3. Do not exceed manufacturer’s recommended cable pulling tension. Monitor and record cable pulling tensions during installation. 3.3 TERMINATIONS and SPLICES: 3.4 IDENTIFICATION: 1. Phase conductors: Black, blue, and red. 2. Ground: green 3. Neutral: white 3.5 TESTING: |
| 289 | 26_05_26 PART I – GENERAL 1.1 SUMMARY: 1.2 QUALITY ASSURANCE: 1.3 GROUNDING SYSTEM – GENERAL DESIGN CRITERIA: 1. The building grounding system shall include the following grounding electrodes: building metal underground water pipe, building structural steel, and either a Ufer ground system (connections to reinforcing steel not smaller than #4 within the colum… 2. Ground rods tied to the UFER ground and/or ground loop shall be provided at the service entrance ground bus, at each lightning downlead (when provided), and at each corner of the building. 3. Known areas of high soil resistivity shall be provided with additional ground rods or chemically-enhanced ground rods. 1. Supplementary grounding electrodes shall consist of a grounding counterpoise made up with three ground rods driven in the pattern of an equilateral triangle with sides of 8 feet, connected with # 4/0 wire. 1. Data Center: Less than 2 ohms. 2. Outdoor Transformer/Switchyard: Less than 5 ohms. 3. Low-Voltage Building Service: Less than 10 ohms. 4. Medium-Voltage Building Service: Less than 5 ohms. |
| 290 | 1.4 BUILDING GROUNDING SYSTEM – DETAILED DESIGN CRTIERIA: |
| 291 | 1.5 MATERIALS: |
| 292 | Not Used PART 3 – EXECUTION |
| 293 | 26_05_33 PART 1 – GENERAL 1.1 SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 26 00 10 – Electrical Design Criteria 1.2 QUALITY ASSURANCE: 1.3 RACEWAY APPLICATIONS: 1. Power circuits above 600 volts run above ground or exposed in building. 2. Elevator machine rooms, pits and shafts. 3. Fire Pump and jockey pump feeders and control circuits. 4. Smoke exhaust fan feeders when required by Code 5. Exposed exterior and outdoor locations and building roofs for power feeders, controls and low-voltage wiring systems. 6. Underground conduit penetrations up through concrete floor slabs for power feeders, controls and low-voltage wiring systems. 7. Exposed areas subject to impact damage. 8. PVC-coated within lab areas where exposed to chemicals. 9. PVC-coated conduit color shall be consistent throughout the project. 1. In lab areas where exposed to chemicals. 2. Exposed exterior and outdoor locations and building roofs for power feeders, controls and low-voltage wiring systems. |
| 294 | 1. Interior dry locations, for power feeders, branch circuit feeders and control circuits. 2. Homeruns for MC cable branch circuit wiring back to panelboards. 3. Interior dry locations, for fire alarm, telecommunications, AudioVisual, building automation and security systems. 1. Interior dry locations, for final connections (36 inches or less) to vibrating equipment, light fixtures and other equipment. 2. Within plenums or other spaces used for environmental air. Provide grounding conductor. 1. Exterior and interior damp and wet locations, for final connections (36 inches or less) to vibrating equipment, light fixtures and other equipment. Provide grounding conductor. 2. Do not use in plenums or other spaces used for environmental air. 1. Schedule 40: In-slab locations, underground locations, concrete encased, for low and medium-voltage power feeders, branch circuit feeders, control circuits, telecommunications and fire alarm circuits. 2. Schedule 80: underground locations, direct-buried, for irrigation and low voltage control and security system wiring. 1. Interior dry locations, for branch circuit feeders, control circuits, fire alarm, telecommunications, AudioVisual, building automation and security systems run exposed on walls and ceilings. 1.4 OUTLET and JUNCTION BOXES: 1. Cast metal boxes or nonmetallic handhole. 1. Cast metal or nonmetallic outlet, pull, and junction boxes. 1. Cast metal or nonmetallic outlet, junction, and pull boxes. Provide flush mounting outlet box in finished areas. 1. Sheet-metal boxes. Provide flush mounting outlet box in finished areas. Provide hinged enclosure for large pull boxes. 1. Provide smooth-sided, welded seam sheet-metal boxes where surface-mounted. 2. Provide flush mounting sheet metal outlet box in finished areas. 3. Provide hinged enclosure for large pull boxes. |
| 295 | 1.5 GENERAL REQUIREMENTS: 1. Floor boxes to be gasketed type, UL listed to meet scrub water exclusion requirements. Provide with ADA covers 2. Poke through fittings to be UL listed with fire rating to match floor rating. PART 2 – PRODUCTS 2.1 SURFACE METAL RACEWAY: 1. WireMold 2. Hubbell 2.2 FLOOR BOXES AND FIRE RATED POKE-THROUGHS: 1. Hubbell PART 3 – EXECUTION: 3.1 INSTALLATION: |
| 296 | 3.2 IDENTIFICATION: END OF SECTION |
| 297 | 26_05_43 PART 1 – GENERAL 3.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 26 00 10 – Electrical Design Criteria 3.2. QUALITY ASSURANCE: 3.3. GENERAL REQUIREMENTS: 3.4. UNDERGROUND RACEWAY APPLICATIONS: 1. Electrical Circuits over 600 volts: concrete-encased ducts, 5” minimum. 2. Building Electric service-entrance conductors: concrete-encased ducts, 4” minimum. 3. Under building floor slab: direct-buried PVC Schedule 40 raceways. 4. 480/277 volt and 208/120 volt branch circuits: direct-buried PVC Schedule 40 raceways, except under roadways and parking lots. |
| 298 | 5. Site lighting circuits: direct-buried PVC Schedule 40 raceways, except under roadways and parking lots. 6. Fire Alarm, Telecommunications, Security circuits and CATV local circuits: direct- buried PVC Schedule 40 raceways, except under roadways and parking lots. 7. Site lighting circuits, Fire Alarm, Telecommunications, Security circuits and CATV Services under parking lots and roadways: PVC Schedule 80 raceways. 8. Exterior conduit risers and sweeps from underground to ten feet above ground: rigid steel conduit. 3.5. MANHOLES AND HANDHOLES: PART 2 – PRODUCTS Not Used. PART 3 – EXECUTION: 3.1. DUCTBANK and UNDERGROUND RACEWAY INSTALLATION: |
| 299 | 3.2. MANHOLE AND HANDHOLE INSTALLATION: |
| 300 | 26_05_90 PART 1 – GENERAL 1.1. SUMMARY: 1.2. QUALITY ASSURANCE: 1.3. GENERAL REQUIREMENTS: 1.4. DETAILED REQUIREMENTS: A. Three-Phase Motors: NEMA MG 1, Design B, energy-efficient squirrel-cage induction motor: |
| 301 | a. Anti-friction ball bearings rated for minimum ABMA 9, L-10 life of 200,000 hours. b. Provide grease lubricated bearings with housings equipped with plugged provision for relubrication, where available in motor size, to be compatible with Brown University preventive maintenance standard grease. PART 2 – PRODUCTS: Not Used PART 3 – EXECUTION: 3.1 INSTALLATION: |
| 302 | 26_08_01 |
| 308 | 26_09_01 SECTION 26 09 01 – CAMPUS CENTRAL METERING SYSTEM DESIGN CRITERIA PART 1 – GENERAL 1.1 SUMMARY: 1.2 RELATED SECTIONS 1.3 General: |
| 309 | 1.4 GENERAL METERING REQUIREMENTS: |
| 310 | 1.5 Submittals: 1.6 Electrical Metering: 1.7 Electric meter installation requirements: |
| 311 | 1.9 THERMAL (BTU) meter installation requirements: 1.10 Gas Metering: |
| 312 | 1.11 Gas Metering installation requirements |
| 313 | PART 2 – PRODUCTS 2.1. ELECTRIC METERS: |
| 314 | 2.2. THERMAL METERS: |
| 315 | 3.1 INSTALLATION – GENERAL: 3.2 TESTING AND REPORTS: 3.3 DOCUMENTATION AND TURNOVER MATERIALS: |
| 316 | 26_09_02 |
| 317 | 26_09_03 260903 thru 260907 EN-1074R3 8x11L_260903 |
| 318 | 26_09_04 260903 thru 260907 EN-1074R3 8x11L_260904 |
| 319 | 26_09_05 260903 thru 260907 EN-1074R3 8x11L_260905 |
| 320 | 26_09_06 260903 thru 260907 EN-1074R3 8x11L_260906 |
| 321 | 26_09_07 260903 thru 260907 EN-1074R3 8x11L_260907 |
| 322 | 26_12_00 PART 1 – GENERAL 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 1.2. QUALITY ASSURANCE 1.3. SUBMITTALS: 1. Dimensions, weights, lifting and installing provisions 2. Voltage (primary and secondary) 3. kVA rating 4. Tap configurations 5. Insulation system type and rated temperature rise 6. Sound Level 7. Design Impedance 8. K-Factor Rating (where applicable) 9. Energy Star Label compliance 10. Basic Impulse Level (BIL) for transformers over 600 Volts 11. Oil capacity 12. Factory Test Reports. 1.4. TRANSFORMER GENERAL REQUIREMENTS: |
| 323 | 1.5. COMMON TRANSFORMER REQUIREMENTS: 1. Nominal 3-phase primary voltage: 11.5 KV 2. Taps: (4) 2.5% below nominal rated voltage 1. Nominal 3-phase primary voltage: 4.16 KV 2. Taps: (2) 2.5% above and (2) 2.5% below nominal rated voltage 3. Nominal 1-phase primary voltage: 4.16 KV (Phase to Phase) 4. Taps: (2) 2.5% above and (2) 2.5% below nominal rated voltage 1.6. TRANSFORMERS – PADMOUNT TYPE: 1. High and low voltage, full-height compartments located side by side, separated by a steel barrier. Low voltage on the right side when facing the front of transformer. 2. High voltage door fastenings not accessible unless low voltage door is opened. 3. 3-point latches for both enclosures. 4. Low voltage door provided with vault type handle with padlock provisions and penta-head access bolt. 5. Stainless steel hinges and door stays. 6. Removable doors, sills and barriers to facilitate cable installation. |
| 324 | 1. Dial-type thermometer 2. Liquid level gage 3. Pressure vacuum gage 4. Automatic Pressure relief device 5. 1” upper filter press and filling plug 6. 1” lower drain valve and sampling port, provide with threaded type sealing plug. 1.7. TRANSFORMERS – SUBSTATION TYPE: 1. Dial-type thermometer 2. Liquid level gage 3. Pressure / vacuum gage 4. Automatic Pressure relief device 5. 1” upper filter press and filling plug 6. 1” lower drain valve and sampling port, provide with threaded type sealing plug. 7. Sudden pressure relay 8. Alarm contacts for temperature and level gages 9. Forced air cooling: Control panel with temperature indicator, status indicating lights, fan controls, test switches, alarm and alarm silence switches, with 120VAC external power source. 1.8. TRANSFORMERS – “POLEMOUNT” TYPE: |
| 325 | 1. Dial-type thermometer 2. Liquid level gage 3. Automatic Pressure relief device 4. Alarm contacts for temperature and level gages 2.1. MANUFACTURERS: 1. Cooper 2. Pauwels 3. Square D 4. Siemens 3.1. INSTALLATION: G. Transformer installation shall be left neat and clean with all foreign material removed from inside and around enclosures. 3.2. IDENTIFICATION: |
| 326 | 26_22_00 PART 1 – GENERAL 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 1.2. QUALITY ASSURANCE 1.3. DRY-TYPE TRANSFORMERS – GENERAL REQUIREMENTS: |
| 327 | 1.4. TRANSFORMERS – GENERAL PURPOSE TYPE: 1. Less than 15 KVA: 185 degrees C insulation system. 2. 15 KVA and above: 220 degrees C insulation system. 1. 3 through 12 KVA: two 5% taps below rated primary voltage 2. 15 KVA and above: six 2.5% taps, 2 above and 4 below rated primary voltage. 1. For transformers rated 9KVA and below, completely encapsulate the core and coil windings in a resin and aggregate to provide a moisture-proof and shock resistant seal, and to provide reduced sound levels. 1.5. TRANSFORMERS – DRIVE ISOLATION TYPE: 1. 7.5 KVA and above: 220 degrees C insulation system. 1. Six 2.5% taps, 2 above and 4 below rated primary voltage. 1.6. TRANSFORMERS – NON-LINEAR LOAD TYPE: 1. Six 2.5% taps, 2 above and 4 below rated primary voltage. PART 2 – PRODUCTS 2.1. MANUFACTURERS: |
| 328 | 1. Square D 2. Siemens PART 3 – EXECUTION 3.1. MOUNTING CONSIDERATIONS: 3.2. INSTALLATION: 3.3. IDENTIFICATION: A. Label each transformer with laminated plastic nameplate, secured to the case with corrosion-resistant screws. |
| 329 | 26_24_00 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 1.2. QUALITY ASSURANCE: 1.3. SUBMITTALS: 1.4. PANELBOARDS: 1. Bussing shall be bare or tin-plated copper. Bussing shall be full rated throughout the height of the panel. 2. Neutral bussing shall be full rated, and electrically isolated from the cabinet. Neutrals shall be 200% rated for all K-rated panel applications. 3. Panelboards shall be provided with a copper ground bus equal to a minimum of 1/2 the capacity of the phase bus. Ground bus shall be electrically bonded to the cabinet. 4. Where isolated ground bus is required, provide an additional, full-rated ground bus in the panel, electrically isolated from both the neutral and panel ground bus. 1. Tandem mounted breakers are not acceptable. |
| 330 | 2. All circuit breakers shall be clearly and visibly marked on the handles for their ampere trip rating. Panel and breaker designs where the panel trim must be removed to determine trip rating are not acceptable. 3. Panelboards designated for use as lighting panelboards with circuit breakers as the source of switch control shall have branch circuit breakers U.L. listed as type SWD for lighting circuits. 4. Provide circuit breakers with switched neutral, ground-fault trip, arc-fault trip or shunt trip capacity where required. 5. Provide circuit breakers with handle locking devices to prevent manual breaker operation where required. 6. Where new circuit breakers are to be installed within existing panelboards, they shall be listed for use with the existing panelboard type, and of sufficient short circuit rating for the application. 7. Circuit breakers for frame sizes less than 250 amps shall be thermal-magnetic type trip units. 8. Circuit breakers in frame sizes 250A and larger shall have adjustable, electronic trip units with long time, short time, instantaneous and time delay settings. 1. Panel board bussing, main and branch circuit breakers shall be rated for the minimum fault current level available on the system. Where fault current information is not readily available, the following ratings shall apply: a. 120-208/240 VAC panels rated 225 amps and less shall be rated for 10,000 AIC minimum. b. 120-208/240 VAC panels rated over 225 amps shall be rated for 22,000 AIC minimum. c. 277/480 VAC panels rated 225 amps and less shall be rated for 14,000 AIC minimum. d. 277/480 VAC panels rated over 225 amps shall be rated for 25,000 AIC minimum. 1. Panelboards shall be furnished with lockable or screw-type, hinged, door-in door type cabinet trims. 2. Provide panels with auxiliary gutters where panels are of the feed-through type. 3. Cabinets shall be rated NEMA type-1 for dry interior areas, and type-4x for wet and exterior areas. 4. Provide panelboards with a hinged door, combination spring lock and catch, directory frame and two (2) keys. Panels over 48 inches high shall be provided with 3-point type latches or multiple latches. All panel locks shall be keyed alike and a neat… 5. Trim clamps, locks and hinges shall be of the concealed type. 1.5. SEPARATELY ENCLOSED MOLDED CASE CIRCUIT BREAKERS: |
| 331 | 2.1. MANUFACTURERS: 1. Square D 2. Siemens PART 3 – EXECUTION 3.1. INSTALLATION – GENERAL: |
| 333 | 26_24_10 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 1.2. QUALITY ASSURANCE: 1.3. SUBMITTALS: 1.4. SWITCHBOARDS – GENERAL REQUIREMENTS: 1. General-purpose use within Academic, Support and Administrative Facilities: Front accessible switchboards with individual, fixed main circuit breakers and group-mounted, fixed distribution circuit breakers. |
| 334 | 2. Research Facilities and Essential-Use Facilities: Draw-out style main (and tie) circuit breakers, and group-mounted, fixed distribution circuit breakers. 1.5. SWITCHBOARDS – DETAILED REQUIREMENTS: 1. Enclosures shall include gutters and wireways of ample size for the feeders and outgoing circuits. 2. Enclosures shall be rated NEMA type-1 for dry interior areas, and type-12 (gasketed) for dusty and dirty indoor areas. 3. Provide switchboard gutters with hinged-type doors. 4. Provide rear accessible switchboards with hinged, lockable access covers. 1. Switchboards requiring metering of the incoming power or submetering of outgoing circuits shall have meters installed within dedicated metering compartments. 2. Metering compartments shall be physically barriered and isolated from live bussing and circuit routing paths; provide with hinged front access door. 3. Metering compartments shall be pre-wired to include required control power transformer(s), current transformer connections and potential (voltage) transformer connections to the meters. 4. Metering shall be per Campus Metering requirements. 1. Switchboard bussing shall be bare, silver-plated or tin-plated copper. Bussing shall be full rated throughout the switchboard. 2. Neutral bussing shall be full rated, and electrically isolated from the cabinet. 3. Provide with a copper ground bus equal to a minimum of 1/2 the capacity of the phase bus. Ground bus shall be electrically bonded to the cabinet. Where isolated ground bus is required, provide an additional, ground bus, electrically isolated from b… 1. Overcurrent devices may include fixed molded case circuit breakers, draw-out type molded case circuit breakers, or draw-out type air-insulated “power” circuit breakers. 2. All circuit breakers shall be clearly and visibly marked for their ampere trip rating and “on”, “off”, and tripped positions. Designs where the trim must be removed to determine trip rating are not acceptable. 3. Fixed circuit breakers for frame sizes less than 250 amps shall be thermal-magnetic type trip units. 4. Fixed circuit breakers in frame sizes 250A and larger shall have adjustable, electronic trip units with long time, short time, instantaneous and time delay settings. 5. Service entrance circuit breakers and all circuit breakers rated over 400 amps shall have adjustable, electronic trip units with long time, short time, instantaneous, ground and time delay settings. |
| 335 | 6. Where new circuit breakers are to be installed within existing switchboards, they shall be listed for use with the existing switchboard type, and of sufficient short circuit rating for the application. 1. Tie breakers shall be key-interlocked with the main secondary disconnecting means, requiring the spare key to parallel sections. 2. Tie breakers shall be manually operated; avoid use of automatic changeover schemes. 3. Double-ended switchboards have multiple connections of system neutral and grounds; provide suitable ground-fault detection and protection scheme to prevent nuisance tripping when operating under all possible scenarios. 4. Connect main feeders to separate incoming power supplies. 1. Switchboard bussing, main and branch circuit breakers shall be rated for the minimum fault current level available on the system. 2. Switchboards shall be fully rated, versus series rated. 3. Where fault current information is not readily available, the following ratings shall apply: a. 120-208/240 VAC switchboards shall be rated for 42,000 AIC minimum. b. 277/480 VAC switchboards rated 2,000 amps and less shall be rated for 42,000 AIC minimum. c. 277/480 VAC switchboards rated over 2,000 amps shall be rated for 65,000 AIC minimum. 2.1. MANUFACTURERS: 1. Square D 2. Siemens PART 3 – EXECUTION 3.1. INSTALLATION – GENERAL: |
| 336 | 3.2. INSTALLATION – DETAILED: |
| 337 | 26_27_26 PART 1 – GENERAL 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 1.2. QUALITY ASSURANCE 1.3. GENERAL DESIGN GUIDELINES: 1. Stainless steel 2. Colored plates: unbreakable nylon; Plastic plates are not acceptable. 3. Weatherproof Cover Plate: Gasketed cast metal plate with hinged and gasketed device cover. 4. Wet locations with connected cords: gasketed, “weathertight when in use” cover plates and gasketed device cover. 5. Specify jumbo size plates for outlets installed in masonry walls. 1. Wall switches and dimmers – 48” Aff. 2. Wall Receptacles – 18” Aff. 3. Counter and bench receptacles – 42” Aff |
| 338 | 1.4. RECEPTACLES: 1.5. SWITCHES: 1.6. DIMMER SWITCHES: 1. Lutron 2. Substitutions: Not permitted 1.7. MULTIOUTLET SURFACE RACEWAY ASSEMBLY (Where Allowed): 1. Wiremold 2. Hubbell 1.8. FLOOR BOXES: |
| 339 | 1. Hubbell PART 2 – PRODUCTS Not Used PART 3 – EXECUTION 3.1 INSTALLATION END OF SECTION |
| 340 | 26_29_23 Part 1 GENERAL 1.1. SUMMARY: A. This section details general requirements for Variable Speed Drives (VFD’s) used for the operation and control of electric motors. 1.2. RELATED SECTIONS: E. Section 26 00 10- Electrical Design Criteria 1.3. QUALITY ASSURANCE: 1.5 WARRANTY: |
| 341 | 1.6. VARIABLE SPEED DRIVE GENERAL REQUIREMENTS: 1. VFD’s shall have the following features and operational requirements: Auto restart after a power line transient (over or under voltage, or power loss) when the power line returns to normal. 2. Auto restart after selected drive faults. The number of restart attempts shall be adjustable at the drive for zero, one or two. 3. Internal drive control shall be fully field programmable without external hardware. 4. “On-the-fly” restart into a coasting load. Resynchronization shall not require more than 150% current. 5. Auto/off/manual switch; manual local speed control; adjustable current limit, adjustable acceleration and deceleration rates; remote start/stop for automatic control. It shall not be necessary to stop the drive when toggling from remote to local sp… 6. Capable of accepting external, permissive contacts such as a freezestat, static pressure safety, damper end switch and fire alarm shutdown contacts to de-energize the motor whether the drive is in automatic, manual drive, or bypass mode. 7. Dedicated “Fireman’s override” external contacts for programmable VFD operation to a preset speed setting for smoke purge or emergency reduced power operation. 8. Programmable auxiliary output dry contacts (2 N/0, 2 N/C each) to indicate: drive run, bypass run or to control devices such as damper open/close. 9. Isolated 4-20mA speed input follower and speed feedback circuits. 10. EIA-485 and EIA-232 communications ports, for BACNET communications card interface with Building Automation Systems (BAS). 11. 5% Input line reactors for harmonic suppression. 12. External three-contactor DRIVE/OFF/BYPASS/TEST SWITCH that allows operation of the motor via line power in the event of VFD failure. |
| 342 | 1.7. VFD DESIGN CONSIDERATIONS: |
| 343 | Part 2 – PRODUCTS: 2.1 VARIABLE SPEED DRIVES: 1. ABB 2. Toshiba 3. Mitsubishi PART 3 – EXECUTION: 3.1 GENERAL: A. Ensure that VFD programing and motor protective devices are properly calibrated and set. B. Provide hardcopy of all VFD program settings, wiring diagrams and Operating manual within the VFD cabinets. C. Include copy of all VFD program settings, wiring diagrams and Operating manual with project O & M Manual. D. Clean interior of VFD enclosures at completion of installation. E. Machine-Label VFD with equipment served, VFD operating voltage, and source power panel and circuit number. 3.2 START-UP: A. A factory-trained and certified technician shall check the installation, program and start the VFD’s and place them into operation. B. Provide certified start-up report for each VFD. 3.3 TRAINING: A. Provide On-site instruction with each VFD via a Factory trained and certified instructor. B. All training aids shall be provided by trainer. Content to include care, troubleshooting, servicing, and operation of the equipment and systems installed. |
| 344 | 26_32_13 PART 1 GENERAL 1.1 SUMMARY: 1.2 RELATED SECTIONS: 1.3 QUALITY ASSURANCE: 1.4 SUBMITTALS: 1.5 EMERGENCY GENERATOR DESIGN CRITERIA: |
| 345 | 1. Generators shall have critical-grade silencers. 2. Exterior-mounted generator enclosures, if required, shall be premium- sound attenuated. 3. Remote-mounted radiators shall be low-noise, sound attenuated where required. 4. Noise considerations to include generator air intake and exhaust louvers. 1. Fuel filling station shall have spill containment and be provided with spill absorption kit. 2. Fuel storage tanks and piping shall be of double wall construction. Provide leak detection system for underground fuel storage tanks and piping systems. Leak detection system to be connected to Building Automation Systems for alarms. 3. Remote located tanks (indoor or underground) to have local fuel tank level indicator and high level alarm monitor at the fuel filling location. 1. Generators “run” status alarms to be connected to building fire alarm and to Building Automation System for supervisory monitoring. 2. Provide remote generator alarm annunciator panel, per NFPA 110, adjacent to fire alarm panel. |
| 346 | 3. Provide remote generator shut-down switch, under a break-glass cover, outside the generator room per NFPA 110. 1.6 Automatic Transfer Switches: |
| 347 | PART 2 PRODUCTS: 2.1 GENERATORS 1. Caterpillar 2. Cummins/Onan 2.2 AutomatiC Transfer Switches: 1. ASCO 7000 series 2. RussElectric RMTD -series PART 3 EXECUTION: 3.1 ELECTRICAL DEVICE COORDINATION 3.2 FIELD TESTING: |
| 348 | 26_50_00 PART 1 – GENERAL 1.1. SUMMARY: 1. Section 01301 – Design Guidelines for Energy and Environment 2. Section 01701 – Building Systems Identification and Labeling 3. Section 265200 – Emergency Lighting 4. Section 265600 – Exterior Lighting 1.2. REFERENCED PUBLICATIONS: 1. International Energy Conservation Code (IECC) 2. ASHRAE 90.1 – Energy Standard for Buildings Except Low Rise Residential Buildings 3. Illuminating Engineering Society of North America (IESNA) Handbook. 1.3. SUBMITTALS: 1.4. WARRANTY: 1.5. GENERAL DESIGN GUIDELINES: |
| 349 | 1.6. EMERGENCY LIGHTING: 1.7. LAMP TYPES: |
| 350 | 1.8. LAMP COLOR: 1.10. DAYLIGHT HARVESTING: |
| 351 | 1.11. FIXTURES: 1.12. BALLASTS: |
| 352 | 1.13. DETAILED LIGHTING DESIGN REQUIREMENTS: PART 2 PRODUCTS 2.1 LIGHTING FIXTURES: 1. Day-Brite 2. Day-O-Lite 3. Hubbell 4. Lightolier 5. Spectrum 6. I.C.E. 7. New England Lighting 2.2 Lamps: 2.3 Occupancy Sensors: 2.4 Ballasts: |
| 353 | 2.5 Dimming Ballasts: 2.6 Dimming Systems /MASTER LIGHTING CONTROLS: PART 3 EXECUTION 3.1 INSTALLATION: A. Install materials and systems in accordance with manufacturer’s instructions and approved submittals. Install materials and systems in proper relation with adjacent construction and with uniform appearance. B. Install fixtures with sufficient clearance form other utilities, ducts, piping, etc. to allow for ready access to fixture components for servicing. C. Restore or replace damaged components and finishes. Test for proper operation. Clean and protect work from damage. D. Lighting fixtures shall be labeled with the manufacturer, model number and lamp type, in addition to the source panel, circuit number and voltage. 3.2 DOCUMENTATION –CLOSEOUT DATA: A. Provide a complete list of fixture, lamp and ballast data, organized by building and room area, for use in procuring spare parts inventories. The tabulation shall be in a spreadsheet format consistent with FM – Lighting Fixture Inventory data. Requ… 1. Building 2. Room Number 3. Fixture Description 4. Fixture Model Number 5. Fixture Quantity 6. Color/K temp 7. Lamp Part Number 8. Lamp Quantity 9. Ballast Part Number 10. Occupancy Sensor Part Number 11. Tamper Proof Tool Required? Y/N 12. Lamp location over 12ft High? Y/N 13. Installation Date 14. Fixture Warranty Expiration Date 15. Lamp Warranty Expiration Date 16. Ballast Warranty Expiration Date B. Include the following Operations & Maintenance information for building lighting systems: 1. As-built drawings of the lighting and control system including locations of all lighting controllers, |
| 354 | 2. Recommended relamping program, 3. Schedule for inspecting and recalibrating lighting controls, 4. Complete narrative of how each lighting control system is supposed to operate, including its recommended settings. 3.3 SPARE PARTS: A. Provide spare lamps and ballasts in quantities equal to 5 percent of the amount used on the project. The Architect shall provide lockable space within the building for the storage of spare lamps and spent lamps to be recycled. B. For special lamps, provide attic stock of six spare lamps. |
| 355 | 26_52_00 PART 1 GENERAL: 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 265000 – Interior Lighting 3. Section 265600 – Exterior Lighting 1.2. GENERAL EMERGENCY LIGHTING DESIGN GUIDELINES: 1.3. DETAILED EMERGENCY LIGHTING DESIGN GUIDELINES: |
| 356 | 1.4. EMERGENCY BATTERY UNITS: 1.5. EMERGENCY INVERTERS: |
| 357 | 1.6. EXIT SIGNS: PART 2 PRODUCTS: 2.1. EMERGENCY BATTERY UNITS: 2.2. INVERTERS: PART 3 EXECUTION: 3.1 INSTALLATION: |
| 358 | 3.2 DOCUMENTATION –CLOSEOUT DATA: 1. As-built drawings of the Emergency lighting and control system including locations of all lighting transfer relays and controllers, 2. Schedule for inspecting and recalibrating lighting controls and batteries. 3. Complete narrative of how Emergency lighting control system is supposed to operate, including its recommended settings. 3.3 SPARE PARTS: |
| 359 | 26_56_00 PART 1 – GENERAL: 1.1. SUMMARY: 1. Section 01301 – Design Guidelines for Energy and Environment 2. Section 01701 – Building Systems Identification and Labeling 1.2. REFERENCED PUBLICATIONS: 1. International Energy Conservation Code (IECC) 2. Illuminating Engineering Society of North America (IESNA) Handbook. 1.3. SUBMITTALS: 1.4. WARRANTY: 1.5. GENERAL DESIGN GUIDELINES: |
| 360 | 1.6. EMERGENCY LIGHTING: 1.7. LAMP TYPES: A. The following lamp types are utilized for exterior lighting: B. Do not use low pressure sodium or mercury vapor lamps. 1.8. LAMP COLOR: A. Lamp color temperature shall be consistent to match existing area lighting, in the range of 3500K to 4, 500 K color temperature. |
| 361 | 1.10. FIXTURES: 1.11. BALLASTS: |
| 362 | PART 2 – PRODUCTS: 2.1 Lighting COntrols: A. Tork B. Paragon PART 3 – EXECUTION: 3.1 INSTALLATION: A. Install materials and systems in accordance with manufacturer’s instructions and approved submittals; install in proper relation with adjacent construction and with uniform appearance. B. Restore or replace damaged components and finishes. Test for proper operation. Clean and protect work from damage. C. Lighting fixtures shall be labeled with the manufacturer, model number and lamp type, in addition to the source panel, circuit number and voltage. 3.2 DOCUMENTATION –CLOSEOUT DATA: A. Include the following Operations & Maintenance information for building lighting systems: 3.3 SPARE PARTS: A. Provide spare lamps and ballasts in quantities equal to 5 percent of the amount used on the project, with no less than one of each type. |
| 363 | 27_05_00 |
| 364 | Part 1 — GENERAL 1.1 Summary A. Communications infrastructure must be designed to allow replacement of cable infrastructure during the life of the building. The life time of a new building is over 80 years, renovations last 30 to 40 years, but advances in communication technology… B. The system design must permit replacement and upgrade of system components while supporting present service. Technicians must be able to access the front and rear of electronics and network patch panels. They must be able to add new cable to existi… C. The communications system installed must function for current and near future communications standards for speed, reliability, and security. Transmission of information at higher speeds requires more energy closer to the consumer. The current gener… D. The system must accommodate applications to new services such as telephone and video. Telephone service will eventually operate on the data network and will require additional power for telephone handsets. New services will require a substantial in… 1.2 Design Engineer and Architect Qualifications A. The Construction and Design Engineer must have a BICSI (Building Industry Consulting Service International) Registered Communications Distribution Designer (RCDD) on staff that is thoroughly familiar with the cabling methods established by the curr… B. The Design Engineer shall have at least 5 years experience designing telecommunications systems. 1.3 communication system component definitions A. Modern communication systems are complex and delicate. There are eight major components that make up a communications system within a building. Item 1-6 below are defined by BICSI and are designed, built, and funded by the construction project. Ite… |
| 365 | 1.4 Telecommunications Services A. Work area outlets should be as plentiful as power outlets. Each must be named and labeled according to CIS labeling standards (Section 1.13). This is to identify locations for support and security for network traffic. The number of work area drops … B. Jack Types |
| 366 | C. Administrative Work Areas Offices and Work Partitions D. Conference Rooms E. Wireless Service A. General |
| 367 | 2. Interior Wireless Installation 3. Exterior Wireless Installation F. DAS |
| 368 | G. Voice over IP H. Student Rooms I. Laboratories J. Reception and Waiting Areas, Study Spaces, and Lounges K. Emergency RED phones |
| 370 | L. Special Use Outlets |
| 371 | Applying Design Guidelines to System Components: 1.5 building entrance Connections between buildings are based on location and building size. CIS must be consulted for the quantity and location of the underground infrastructure. 1.6 telecommunications room A. The room must be clean, secure and permit maintenance without disruption of services. The number of work area drops per floor determines the MEP (Mechanical Electric Plumbing) requirements of each telecommunication room. In addition, TRs must meet … |
| 374 | 1.7 backbone A. Backbones must be designed in such a way to protect the cables from damage and to provide redundant communications paths to network equipment installed in telecommunication rooms. Backbone capacity must be sufficient to connect each local telecommu… |
| 375 | B. The capacity and destination for OSP backbone cable building feed is determined by the location and purpose of the building, typically from a minimum of 24 to 96 strands of single mode fiber. C. The minimum strand count for riser fiber between TRs within a building is one 12 strand single mode and one 12 strand 50-micron OM3 multimode from each TR to the building entrance facility. D. Fiber must be protected. All inside plant fiber cable must be armored. E. The minimum pair count for copper inside plant (ISP) riser for telephone is 25 pair. F. All backbone cable must be protected and supported. G. 40% fill for new raceway provides replacement during the lifetime of the renovation. H. OSP fiber and copper is typically specified in the Facilities Utility memo issued by Facilities Management. 1.8 horizontal cabling A. Horizontal cable must be protected from damage (crushing or twisting) during and after installation. Supporting raceway must accommodate for growth and maintenance of the cable as well as non-disruptive installation of replacement cabling as cable … B. The maximum fill is 40% fill for new raceway. This provided for replacement of cable without disruption to users. C. The requirements in this section are harmonized with the horizontal pathway and related space requirements specified in American National Standards Institute/Telecommunications Industry Association/Electronic Industries Alliance (ANSI/TIA/EIA)—569—… D. Horizontal cable must be accessible or in conduit over such areas as hard ceilings. E. When designing a building, the layout and capacity of the horizontal pathway system must be thoroughly documented in floor plans and other building specifications. The designer is responsible for ensuring that these systems have built-in flexibilit… F. All design and construction for pathway systems must meet or exceed national and local codes and standards. G. When grounding telecommunications pathways, ensure that the installation conforms to applicable practices and codes (in the United States, ANSI TIA-607-B, Commercial Building Grounding (Earthing) and Bonding Requirements for Telecommunications) the… |
| 376 | H. Use systematic methods and procedures for labeling and managing horizontal pathways and spaces. For details on guidelines and requirements for the color coding and administration of horizontal cabling systems, ANSI/TIA/EIA-606-B, Administration Sta… 1.9 rack equipment layout A. Standard network equipment rack: B. Dressing of Horizontal Distribution Cables |
| 377 | C. Rack UPS Layout (One Battery Pack) — For one to three switches per rack D. Rack UPS Layout (Two Battery Packs) — For four to six switches per rack (see picture following) |
| 378 | 1.10 cable supports/cable raceway A. The Consulting Engineer shall specify Cable raceway and supports subject to approval by CIS. B. Snap in fittings for surface raceway may use a Wiremold adapter manufactured by Hubbell (A22). C. Furniture adapter plates are available for Steelcase, Haworth, etc. are available from Hubbell (A21) 1.11 naming conventions & labeling standards A. Work Area Outlet Names B. Work Area Outlet Cable Names |
| 379 | C. Telecommunications Rooms: BBBB-RRRR |
| 380 | D. Racks: BBBB-RRRR-Z E. Bays in Racks: BBBB-RRRR-ZNN |
| 381 | F. OSP fiber: NNN-FZ |
| 382 | G. Riser fiber/cable: BBBB-RRRR-TN H. Fiber Patch Panels: ZNN-X I. Copper Patch Panels: ZNN |
| 383 | Part 2 — PRODUCTS 2.1 faceplates 2.2 modular inserts 2.3 horizontal cable 2.4 data patch panels (communications room) |
| 384 | 2.5 fiber optic termination hardware (communications room) 2.6 VOICE TERMINATION hardware (Communications room) 2.7 intra-building backbone cables |
| 385 | 2.8 inter-building backbone cables 2.9 equipment racks A. Ortronics Mighty Mo 10 – Cable Management Rack: P/N OR-MM10716 B. Ortronics Mighty Mo Blank Filler Panels C. Vertical Cable Management System 1. Single Rack Line-Up: 2. Multi-Rack Line-Up: |
| 386 | 2.10 edge network electronic (supplied by CIS) A. All Research Buldings: Cisco: P/N WS-C3750X-48P-S B. All Non-Research and Residence Hall Buildings: Cisco: P/N WS-C3750V2-48P-S 2.11 wireless devices (supplied by cis) A. Indoor: B. Outdoor: 2.12 uninterruptible power supply (supplied by cis) A. Rack Mounted UPS (Supplied by CIS) |
| 387 | B. Building Wide UPS (Supplied by the Project) 2.13 outside emergency phones 2.14 elevator emergency phones 2.15 wheelchair lift phones |
| 388 | 2.16 conference phones (supplied by end user) 2.17 tamper proof housing Secure IT Plate for Laundry and vending 2.18 ceiling Housing for wifi radios Pre assembled Heavy duty box to Tbar fastener |
| 389 | Part 3 — EXECUTION 3.1 planning 3.2 design A. Facilities Management will update the Project Fact Sheet to notify CIS a project is underway. B. CIS will assist the electrical and telecommunications engineers retained for the project to define the following requirements for the communications system: |
| 390 | F. Construction plans must show communications outlet locations, type , and name. G. A CIS work order may be submitted for discovery of existing conditions if necessary. H. At that time CIS will determine which work is appropriate to. For example, CIS is able to install communications outlets for small projects. On most projects the communications contractor is hired directly by the GC. |
| 391 | 3.3 construction A. General B. Milestones C. Kick Off |
| 392 | D. Draft Tap List E. Pre-Acceptance Walk Thru F. System Acceptance 1. Telecommunications Contractor Deliverables by System Acceptance 2. Telecommunications Room Readiness Criteria |
| 393 | G. Service Turn-up 3.4 closeout A. The O&M documentation must include: |
| 394 | B. Printed test results are not required as part of the O&M documentation package since they are submitted to Hubbell and Corning as part of the warrantee application and to CIS prior to service turn-up. |
| 395 | 27_40_00 PART 1 GENERAL 1.1 SUMMARY A. Guidelines: Installed classroom AV design is inherently tied to the specific space in question. Factors such as ambient light control, sound reflectivity, size and shape all play a role in determining appropriate display tools. 1. Designs should reflect the industry standard DM (digital media) signal transmission.. 2. Designs should recognize the need to refresh AV equipment and cabling on average every five years. 3. Projects that result in spaces that will be scheduled by the Registrar are required to add Crestron DM room control system with LCD touch panel interface as well as programming to add spaces(s) to the CIS RoomView server. 1.2 SUBMITTALS A. Product Data: Submit manufacturer’s product data and installation instructions for each material and product used. B. Shop Drawings: Submit shop drawings indicating material characteristics, details of construction, connections, and relationship with adjacent construction. C. Warranty: Submit manufacturer’s standard warranty. We require 2 years parts & labor extended warranty on all installations. Include labor and materials to repair or replace defective materials. Warrantees must be submitted as a project deliverable. D. Maintenance Data: Submit manufacturer’s maintenance data, including maintenance schedule. E. Extra Stock: Submit extra stock equal to 2 percent of total used. 1.3 QUALITY ASSURANCE A. Comply with governing codes and regulations. Provide products of acceptable manufacturers which have been in satisfactory use in similar service for three years. Use experienced installers. Deliver, handle, and store materials in accordance with ma… B. Electrical Components, Devices, and Accessories: Listed and labeled as defined in NFPA 780, “Definitions” Article. PART 2 PRODUCTS 2.1 ROOM SPECIFICATIONS A. Smaller spaces (<12 seats) are typically outfitted with: 1. Large format digital flat panel display (Samsung LCD/LED commercial/professional models. ME55/ME65 or equivalent). 2. Direct input HDMI and VGA/w audio-follow. 3. Flat panel displays have built-in speakers for audio playback. 4. Hard room network taps specified for patron access to the web-based video. |
| 396 | 5. Ethernet connection is also needed for the RoomView Express room-control/monitor software. 6. Crestron digital room controller DM-RMC-100 7. Crestron wall plate digital media transmitter DM-TX-200 8. Crestron Digital presentation system DMPS-300-C 9. Crestron LCD touch panel TPS-6 10. Install requires minimum 6 data taps dedicated to room control/operation. B. Medium spaces (15-25) vary greatly in approach. Typically a projector/screen combination is specified, but depending on pedagogy: 1. Dual flat panels (Samsung LCD/LED commercial/professional models. ME55/ME65 or equivalent). 2. Projector should be 16:9 aspect ratio with a minimum resolution of 1920 x 1200. (Eiki LC-WB200/LC-WUL100L or current Eiki equivalent + appropriate lensing. HD wide screen.) 3. Installed projection screen, recessed/powered/tensioned where appropriate (DaLite). 4. Depending on room size, installed room speakers may be required for audio playback. (JBL Control series; sized/quantity to space; ceiling-voice; wall-program) 5. Equipment rack can either be free standing or contained within room podium. 6. Digital room system (Crestron DMPS-100/200/250/300) 7. Digital room controller (Crestron DM-RMC-100) 8. Digital wall plate transmitter (Crestron DM-TX-200) 9. LCD touch panel (Crestron TPS-6). 10. Region-free BluRay DVD (commercial/professional models. Sony BDPS480 or equivalent) 11. Auxiliary video/audio inputs to include: composite video; component YPbPr video; HDMI; VGA; 3.5mm audio; RCA audio. The Crestron room control system in the rack requires network connectivity for remote access/polling. 12. Install requires minimum 8 data taps dedicated to room control/operation. C. Large spaces (+50) dependent on room configuration and materials to be displayed: 1. Multiple projectors are positioned so as to enable projection and simultaneous use of whiteboards. This requires projectors capable of creating viewable images in rooms lit for note-taking. (Eiki LC-WUL100L or better or current Eiki equivalent. … 2. Installed motorized projection screen for rooms with projection. (DaLite) 3. Audio reinforcement is required in larger spaces, especially spaces that are dual-purposed for classroom and event activities. (JBL speakers, Audio-Technica wireless mics/receivers/antennas, Shure mixers, Mackie/Prosonus sound boards, BSS digital … 4. Teaching podium (Spectrum) outfitted with a condenser gooseneck microphone (Audio-Technica). Consider installed computer with dedicated monitor (Dell small form tower + monitor on articulating arm). Smart Sympodium annotation tablet can be config… 5. Minimum (2) channels of wireless audio – (4) is optimal; up to (6) hard-wired audio mic inputs for panel discussions. Loudspeaker size, location and quantity are space-specific. (Audio-Technica wireless receivers, wireless handhelds & lavalieres, … 6. Digital soundboard is required to manage these audio signals. (Presonus) Crestron programming to accommodate need for ‘live’ mode (mic mixing) and ‘auto’ mode basic presentations with podium mic. |
| 397 | 7. Require region-free BluRay DVD so visiting faculty/speakers from international locations can be accommodated (Sony BDPS480 or equivalent). 8. Spaces of this size may be considered for lecture capture installation. This requires an Echo360 HD (current campus standard) appliance, network connectivity and input feeds from teaching podium VGA, audio and as an option, installed room camera(s… 9. Equipment racks (Middle Atlantic) are to be kept to a minimum size to accommodate required equipment. Depending on room size/complexity, a media booth may be required. 10. Crestron room processor (DMPS-100/200/250/300) 11. Crestron digital room controller (DM-RMC-200) 12. LCD touch panel (Crestron TPS-6). More complex spaces may require larger touch panels (Crestron TPS-12) or additional wall control panels if podium is removable. 13. Require region-free BluRay DVD playback. (Sony BDPS480 or equivalent). 14. Aux video/audio inputs required: composite video; component YPbPr video; HDMI; VGA; 3.5mm audio; RCA audio. The Crestron room control system in the rack requires network connectivity for remote access/polling. 15. Audio processing gear (BSS LondonBlu digital sound processors, Crown amplifiers, Furman power supplies) 16. Audio-Technica 4000 series wireless mic systems (ATW4313) + body pack lavaliere mic AT989 + handheld mic AEWT3300) 17. Proper rack mounted cooling (multiple fans) may be required to avoid overheating from concentration of rack equipment processing gear. 18. Consider addition of video teleconferencing codec (Tandberg) 19. Install requires minimum 10 data taps dedicated to room control/operation. D. Ambient light control and adjustment is critical to managing the quality of the projected/displayed image in a given space. Where exterior windows are present it is recommended that both light-filtering and room-darkening shades be installed. Roo… E. Network connectivity should include room wireless access. In spaces outfitted with room control touch panels, adequate rack space is required to house standard playback media (BluRay DVD) as well as room controller, audio amps and auxiliary inputs… F. Proper power to support all equipment, rack equipment and motorized screen. Low voltage power control for lighting, shades. Recommend installation of an uninterruptible power supply (APC UPS SC1000/1500) at equipment rack. G. Media Technology Service (AV): Specification of current equipment models must be MTS approved equal or equivalent. 1. Projector Models Specified on Recent Projects: a. Eiki LC-XL200 (XGA – 1024 x 768, 6000 ANSI lumens, 1000:1 contrast ratio) b. Eiki LC-WXL200 (WXGA – 1280 x 800, 5500 ANSI lumens, 800:1 contrast ratio) c. Eiki LC-WB200 (WUXGA – 1920 x 1200, 5000 ANSI lumens, 2000:1 contrast ratio) |
| 398 | d. Eiki LC-WUL100 (WUXGA – 1920 x 1200, 5000 ANSI lumens, 2000:1 contrast ratio) e. Eiki LC-WSP3000 (WUXGA – 1920 x 1200, 5000 ANSI lumens, 2000:1 contrast ratio) 2. Required Crestron components to support RoomView remote access in a digital space: a. Crestron digital presentation system DMPS-100/200/250/300 b. Crestron digital media switcher (DM-MD8x8) c. Crestron DM input cards (DMC-HD/CAT) d. Crestron Room Controller + DM CAT receiver (DM-RMC-100/200/300) e. Crestron Ethernet card (C2ENET-2) f. Crestron Digital media CAT transmitter wallplate (DM-TX400-3G) A/V Preferred Vendors: Shanix Technologies 40 Worthington Road Cranston, RI 02920 (401) 941-4222 www.shanix.com. Ambient 75 New England Way Warwick, RI 02886 (401) 941-8500 www.ambientsound.com 3. Shanix & Ambient have developed and implemented the standard Crestron interface used on campus. They are required to be involved with any new rooms which include the installation of a Crestron control system in order to ensure it is programmed prop… H. Video Conferencing: 1. Brown currently maintains a Tandberg VCS-TMS infrastructure system for video conferencing. Currently we are specifying Tandberg endpoints. The information contained in this section is inclusive of the video conferencing portion and does not incl… 2. Items outside the video conferencing equipment which are required include: a. Flat panel or projector/screen b. Audio system c. Crestron control system d. Polycom conference phone e. Telephone line f. Network connection setup on the Brown/VOIP network g. Power outlets to support equipment 3. Other factors can greatly affect a video conference and need to be considered: a. Room Brightness – are shades needed? dimmable lighting? b. Room set-up in a manner such that all seats are viewable via the camera. c. Sound issues – is the room fairly sound proof – minimized sound in and out of the room |
| 399 | d. Number/location of cameras needed e. Number/location of microphones needed 4. Tandberg Standard Equipment Specifications: a. C20: 1). 1 – CTS-QSC20-K9, QuickSet C20 – Incl NPP, PreHD1080pCam, Mic, Rmt, Cbls 2). 1 – CTS-PHD-1080P12X, 12 X Zoom Percision HD Camera 3). 1 – CTS-PHD-1080P4XSI, 4 X zoom Percision HD Camera 4). 1 – LIC-QSC20-DD, QuickSet C20 – Dual Display Option (requires LIC-QSC20-HD) 5). 1 – LIC-QSC20-HD, QuickSet C20 – HD (720p) option 6). 1 – LIC-QSC20-PR, QuickSet C20 – Premium Resolution Option (requires LIC-QSC20-HD) 7). Support 1-3yr 8). CTS-CTRL-DVC8 TelePresence Touch 8” b. C40: 1). 1 – CTS-INTP-C40-K9, IntPkg C40 – NPP, PHD 1080p Cam, Rmt Cntrl, Mic, Cbls ++ 2). 1 – LIC-INTP-C40-DD, Codec C40 Integrator Package Dual Display (DD) Option 3). 1 – LIC-INTP-C40-MS, IntPkg C40, 4Way Individual Transcoding Multisite Option 4). 1 – LIC-INTP-C40-PR, IntPkg C40 Premium Resolution (1080p/720p60) Option 5). Support 1-3yr 6). CTS-CTRL-DVC8 TelePresence Touch 8” c. C60: 1). 1 – CTS-INTP-C60-K9, IntPkg C60 – NPP, PHD 1080p Cam, Rmt Cntrl, Mic, Cbls ++ 2). 1 – LIC-INTP-C60-MS, IntPkg C60, 4 Way HD Multisite (HD-MS) 3). 1 – LIC-INTP-C60-PR, IntPkg C60 Premium Resolution (1080p/UXGA) Option 4). Support 1-3yr 5). CTS-CTRL-DVC8 TelePresence Touch 8” 5. Any installation of Video Conferencing equipment must be coordinated with CIS Media Technology Services. This coordination will ensure that proper equipment is selected and that the units can communicate with the CIS Central Video Conferencing Inf… PART 3 EXECUTION 3.1 INSTALLATION A. Install materials and systems in accordance with manufacturer’s instructions and approved submittals. Install materials and systems in proper relation with adjacent construction and with uniform appearance. Coordinate with work of other sections. B. Restore or replace damaged components and finishes. Test for proper operation. Clean and protect work from damage. |
| 400 | 28_31_10 SECTION 28 31 10 – FIRE ALARM SYSTEMS, SMOKE ALARMS, CARBON MONOXIDE ALARMS and DETECTION SYSTEMS PART 1 – GENERAL 1.1 SUMMARY: 1.2 SCOPE OF STANDARD: 1.3 REFERENCED PUBLICATIONS: |
| 401 | 1.4 QUALITY CONTROL: 1.5 800MHZ RADIO SYSTEM SURVEY AND INTERCONNECTIONS: 1.6 FIRE ALARM SYSTEM BASIC DESIGN CRITERIA: |
| 404 | 1.7 CARBON MONOXIDE ALARMS and DETECTION SYSTEMS BASIC DESIGN CRITERIA: (Only applies to buildings that contain fuel burning appliances) |
| 405 | 1.8 FIRE ALARM SYSTEM ACCESSORIES: 1.9 FIRE ALARM SYSTEM FUNCTIONAL DESCRIPTION: |
| 407 | 1.10 SUBMITTALS: |
| 409 | PART 2 – PRODUCTS 2.1. MANUFACTURERS: 2.2. GENERAL: 2.3. FIRE ALARM CONTROL PANEL (FACP): |
| 410 | 2.4. DISTRIBUTED POWER SUPPLIES: 2.5. ADDRESSABLE DEVICES – GENERAL: |
| 411 | 2.6. DETECTOR BASES: 2.7. ADDRESSABLE MONITOR MODULE: 2.8. ADDRESSABLE CONTROL RELAY MODULE: 2.9. AUXILIARY RELAYS: 2.10. MANUAL PULL STATIONS: |
| 412 | 2.11. HEAT DETECTORS: 2.12. SMOKE DETECTORS: 2.13. DUCT-MOUNTED SMOKE DETECTORS: 2.14. PROJECTED-BEAM SMOKE DETECTORS: 2.15. ELECTROMAGNETIC DOOR HOLDERS: |
| 413 | 2.16. ALARM NOTIFICATION APPLIANCES: 2.17. AUDIBLE ALARM NOTIFICATION APPLIANCES: 2.18. VISUAL ALARM NOTIFICATION APPLIANCES: 3.1 CONNECTIONS TO EXISTING SYSTEMS: 3.2 TEMPORARY SHUTDOWNS: |
| 414 | 3.3 INSTALLATION – GENERAL: 3.4 WIRING AND CIRCUIT IDENTIFICATION: |
| 415 | 3.5 FIRE ALARM SYSTEM IDENTIFICATION/LABELING: |
| 416 | 3.6 TESTING AND REPORTS: 3.7 DOCUMENTATION AND TURNOVER MATERIALS: |
| 417 | 3.8 TRAINING: |
| 418 | 28_35_00 SECTION 28 35 00 – REFRIGERANT DETECTION AND ALARM SYSTEMS PART 1 – GENERAL |
| 420 | PART 2 – PRODUCTS PART 3 – EXECUTION |
| 422 | 32_13_13 |
| 423 | 32_13_14 |
| 425 | 32_14_00 |
| 426 | 32_17_23 |
| 427 | 32_30_10 |
| 443 | 32_30_20 |
| 444 | 32_30_30 |
| 445 | 32_80_00 1.1. SUMMARY: 1. Section 01701 – Building Systems Identification and Labeling 2. Section 01771 – Contract Record Documents 1.2. SUBMITTALS: 1.3. WARRANTY: 1.4. IRRIGATION SYSTEM DESIGN CRITERIA – GENERAL: |
| 446 | 1.5. IRRIGATION SYSTEM DESIGN CRITERIA – DETAILED: |
| 448 | 1.6. IRRIGATION SYSTEM ELECTRICAL DESIGN CRITERIA : |
| 449 | 2.1. CONTROLLERS: 2.2. PVC IRRIGATION PIPE FOR LATERALS AND MAINLINES: |
| 450 | 2.3. PVC PIPE FITTINGS: 2.4. PVC PIPE SLEEVES: 2.5. PVC PIPE FITTINGS: 2.6. POLYETHYLENE IRRIGATION PIPE: 2.7. POLYETHYLENE IRRIGATION FITTINGS: 2.8. POLYETHYLENE CLAMPS: |
| 451 | 2.9. SWING JOINTS: 2.10. VALVES: 2.11. SPRINKLERS: |
| 452 | 3.1. PIPING: 3.2. VALVES AND VALVE BOXES: 3.3. ELECTRICAL: 3.4. IRRIGATION SYSTEM FLUSHING, TESTING AND ADJUSTMENTS: |
| 453 | A. Flushing: 1. Open the control valves and flush out the system under a full head of water after all piping, valves, sprinkler bodies, pipe lines and risers are in place and connected, but prior to installation of sprinkler internals. 2. Sprinkler internals, and nozzles shall be installed only after flushing of the system has been successfully accomplished. 3. Contractor shall be responsible for flushing the entire system after installation is complete and will be responsible for any clogged nozzles for thirty (30) days after substantial completion of the landscape irrigation system. B. Testing: 1. Leakage test: test all lines for leaks under operating pressure. Repair all leaks and re-test. Brown project manager must observe test. 2. Coverage test: perform a coverage test in the presence of the Owner’s Representative (notify Owner’s Representative at least seven (7) days in advance of scheduled coverage test). Representative will determine if the water coverage is complete and … 3. System Test: Perform operational test to ensure that controller is properly operating from local and remote controls. Test controller to ensure that zones are properly programmed for sequence and run times. Readjust and calibrate as required. END OF SECTION |
| 454 | 32_90_00 |
| 456 | 32_92_00 |
| 457 | Standards Compliance Form.C |
| 458 | Standards Waiver Form.B |
Related products
-
ASCE AdvancesinPublic PrivatePartnerships 2016
Advances in Public-Private Partnerships Published By Publication Date Number of Pages ASCE 2016 651
-
ASHRAE Fundamentals Handbook IP 2013
2013 ASHRAE Handbook – Fundamentals – IP Edition Published By Publication Date Number of Pages…
