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1222 S Sycamore St - Plan
CODE INFORMATION APPLICABLE CODES, LAWS AND REGULATIONS CODE INFORMATION APPLICABLE CODES, LAWS AND REGULATIONS 2022 CALIFORNIA BUILDING CODE (CBC) 2022 CALIFORNIA RESIDENTIAL CODE (CRC) 2022 CALIFORNIA FIRE CODE (CFC) 2022 CALIFORNIA ELECTRICAL CODE (CEC) 2022 CALIFORNIA MECHANICAL CODE (CMC) 2022 CALIFORNIA PLUMBING CODE (CPC) 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 1 9 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M (N) GRID TIED PHOTOVOLTAIC SYSTEM SOLAR INDIVIDUAL PERMIT PACKAGE PEGGY SHACKELFORD 1222 SOUTH SYCAMORE STREET (928) 600-7784 SANTA ANA, CALIFORNIA 92707 8.00 kW-DC AHJ: SANTA ANA CITY UTILITY: SOUTHERN CALIFORNIA EDISON CO (N) 19.5 kWh SUNVAULT ENERGY STORAGE SYSTEM (N) 7.238 kW-AC GRID TIED PHOTOVOLTAIC SYSTEM SATELLITE IMAGE CO V E R S H E E T PROJECT LOCATION SHEET INDEX SCOPE OF WORK - (N) 8.000 kW PHOTOVOLTAIC SYSTEM & (N) 19.5 kWh ENERGY STORAGE SYSTEM - (20) WAAREE ENERGIES LIMITED WSMDi-400 PV MODULES AND (20) ENPHASE IQ7HS-66-M-US MICROINVERTER - POINT OF INTERCONNECTION AT MAIN SERVICE PANEL WITH CIRCUIT BREAKER - QUAD/TWIN BREAKERS REQUIRED - TRENCH REQUIRED: 35FT THROUGH CONCRETE/ASPHALT NOTES ARCHITECTURAL DRAWINGS ELECTRICAL DRAWINGS E-1 ELECTRICAL SINGLE-LINE DIAGRAM & E-2 ELECTRICAL CALCULATION E-3 ELECTRICAL DATA & SPECIFICATIONS SPECIFICATIONS E-4 E-5 BRANCH DIAGRAM STRUCTURAL DRAWINGS S-1 STRUCTURAL INFORMATION & A-0 COVER SHEET A-1 ARRAY LAYOUT EQUINOX GROUNDING DETAILS PV MOUNTING DETAILS E-6 BREAKER SCHEDULE S-2 ESS MOUNTING DETAILS NTS SHEET A-0 NOTE: EXISTING SYSTEM (E) 4.720 KW PHOTOVOLTAIC SYSTEM (E) PV AC SYSTEM SIZE: 4.203 KW-AC COMBINED SYSTEM 12.72 kW PHOTOVOLTAIC SYSTEM Bldg# 101118827 Elec# 20182490 APPROVALS: MSmith The scope of the plans is for the installation of the solar photovoltaic system only and the approval is subject to compliance with all applicable city and state codes and regulations regarding construction. The approval of the plans does not constitute any certification of the accuracy, completeness, or building permit status of the existing buildings and structures as shown. 1222 S Sycamore St - 201824905/3/2024 ROOF 1 ROOF 2 SO U T H S Y C A M O R E S T R E E T HUB+ E-ACD ESS M ROOF ACCESS POINT (E) FENCE/GATE (E) FENCE/GATE (E) PV ARRAY (E) PV ARRAY DETACHED GARAGE NON-HABITABLE HD 10 " (N) ESS LOCATION (INT GARAGE WALL MOUNTED) (N) SAFETY BOLLARD (N) HEAT DETECTOR 57'-4" 35 ' - 3 " (N) HUB+ LOCATION (EXT WALL MOUNTED) AC D TRENCH VIA PVC CONDUIT BURIED 18” MIN ROOF ACCESS POINT E-SUB 21'-2" 21 ' - 1 " PATIO MAIN HOUSE (E) S-LC N- L C 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M AR R A Y L A Y O U T 3/32" = 1'-0" NOTE: 1.FIELD ADJUSTMENTS OF FEWER THAN 6” MAY BE ALLOWED BASED ON SITE CONDITIONS AND MEASUREMENTS. N 1 2ROOF AZIMUTH PITCH MODULE QTY. 0:12 180° 12 0:12 0° 8 SHEET A-1 L E G E N D JUNCTION BOX CONDUIT ACD (N) SOLAR AC DISCONNECT EXISTING SUBPANELE-SUB L E G E N D JUNCTION BOX PROPERTY LINE CONDUIT FIRE ACCESS PATHWAY M UTILITY METER AND MAIN SERVICE PANEL E-ACD (E) SOLAR AC DISCONNECT QTY:SUNVAULT™ ENERGY STORAGE SYSTEM (ESS): BASE HUB+NEW HUB+ ESS NEW SUNVAULT ENERGY STORAGE SYSTEM 1SV-BASE19.5-C NEW BOLLARD NEW HEAT DETECTORHD MODULE: MICROINVERTER: QTY: QTY: ROOF TYPE:NO. OF STORIES: TOTAL ATTACHMENT COUNT: TOTAL ROOF AREA (MAIN): TOTAL % OF ROOF COVERED BY SOLAR: TOTAL ARRAY AREA (MAIN): ROLLED COMP 1 - STORY 62 1803 sq.ft. 28% 497 sq.ft. WAAREE ENERGIES LIMITED WSMDI-400 ENPHASE IQ7HS-66-M-US [240] 20 20 EXISTING ARRAY AREA (MAIN):NEW ARRAY AREA (MAIN): 215 sq.ft.282 sq.ft. TOTAL ROOF AREA (DETACHED):TOTAL ARRAY AREA (DETACHED): 446 sq.ft.215 sq.ft. TOTAL % OF ROOF COVERED BY SOLAR: 48% EXISTING SOLAR LOAD CENTER (E) S-LC NEW SOLAR LOAD CENTERN-LC SEALED FOR ATTACHMENTS AND EXISTING FRAMING ONLY exp: 06/25 Steven Procter Digitally signed by Steven Procter Date: 2024.01.29 10:26:22 -06'00' 1222 S Sycamore St - 201824905/3/2024 TABLE 2: PENETRATION GUIDE FOR INSTALL STACKED STAGGERED FULLY STAGGERED STACKED/STAGGEREDFULLY STAGGERED *CHECK TABLE 1 FOR MAX. PENETRATION SPACING AND PENETRATION PATTERN FOR EACH ARRAY. TWO OR MORE ROWS OF MODULES ONE ROW OF MODULES 2 1 / 2 " M I N . 0.75" MIN. ALUMINUM FLAT TOP 2-PIECE STANDOFF (2)5/16" X 3 1/2" S.S. LAG BOLT WITH 5/16" WASHER @ CENTER TYP. PRE-DRILL REQUIRED. E-CURB M-1 STRUCTURAL SEALANT (E) WOOD SHEATHING MID CLAMP L FOOT INVISIMOUNT RAIL PV MODULE HARDWARE: UNIRAC STANDOFF INVISIMOUNT ROOF ATTACHMENT DETAILS PV MODULE TABLE 1 – ARRAYS INFORMATION ROOF PITCH ROOFING TYPE ATTACHMENT TYPE NO. OF STORIES FRAMING TYPE (in.) MAX. RAFTER SPAN (ft.) PENETRATION PATTERN (in.) MAX. ATTACHMENT SPACING (in.) MAX. RAIL OVERHANG (in.) ROOF 1 2°Rolled Comp Unirac Standoff 1 2x6 Rafter @ 24" OC 8.5'Staggered 48"16" ROOF 2 2°Rolled Comp Unirac Standoff 1 2x12 Rafter@ 16" OC 20'Staggered 48"16" -------------------- -------------------- -------------------- -------------------- INVISIMOUNT RAIL PV MODULE 10 " M A X . EXTERIOR WALL LOAD BEARING (E)RAFTER EXTERIOR WALL LOAD BEARING INVISIMOUNT RAIL PV MODULE 10 " M A X . EXTERIOR WALL LOAD BEARING (E)RAFTER EXTERIOR WALL LOAD BEARING STRUCTURAL FRAMING SIDE DETAIL STRUCTURAL FRAMING SIDE DETAIL ROOF 1 ROOF 2 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M ST R U C T U R A L I N F O R M A T I O N AN D M O U N T I N G D E T A I L S NTS SHEET S-1 SEALED FOR ATTACHMENTS AND EXISTING FRAMING ONLY exp: 06/25 Steven Procter Digitally signed by Steven Procter Date: 2024.01.29 10:26:14 -06'00' 1222 S Sycamore St - 201824905/3/2024 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M ES S M O U N T I N G D E T A I L S NTS SHEET S-2 1222 S Sycamore St - 201824905/3/2024 15A, 1P HD YES 14 (1) #14 THHN (1) #14 THHN EGC MODEL: LOCATION: FIRST ALERT - HD6135FB ON CEILING DIRECTLY ABOVE ESS ENCLOSURE NO NONO EGC: Bare CU #6 BRANCH CIRCUIT FROM PV ARRAY TO JUNCTION BOX #12 2 A -- 1 B JUNCTION BOX, NEMA-4 THWN-2 EGC: THWN-2 1 2 B 3 #10 #10 EMT 3/4" #10 CONDUCTOR / CONDUIT SCHEDULE DESCRIPTION & CONDUCTOR TYPE CONDUCTOR SIZE (AWG)CONDUIT/CABLE TYPE CONDUIT SIZENUMBER OF CONDUCTORS 1 ROOFTOP ARRAY WIRING A DC AC Branch Circuit #1AC 8 AC MODULES TAG BRANCH BREAKER TYPE HOM2100 60A, 2P H (E) UTILITY BIDIRECTIONAL METER #: 222012-762150 EXISTING GROUND THWN-2 EGC: THWN-2 1 3 EMT 1" #3 #8 MI D ETHERNET CONNECTION TO DSL/CABLE MODEM CA T 5 e PVS6 BACKUP BUS (200A MAX) (N) HUB+ 200A, 120/240 V, NEMA-3R MODEL: GE N E R A T I O N B U S (1 2 5 A M A X ) 10 YES LOCATION: **PVS6 **BREAKERS ARE FIELD INSTALLED. BREAKER RATING MAY VARY FROM 15A OR 20A SV-HUB-01-C C C OUTSIDE MLO GROUNDED (INCLUDE GEC) UNGROUNDEDü INSTALLATION NOTES 1 CHECK BOX FOR WHETHER SYSTEM IS GROUNDED OR UNGROUNDED: FOR UNGROUNDED SYSTEMS: · DC OCPD DISCONNECT BOTH CONDUCTORS OF EACH SOURCE CIRCUIT. · UNGROUNDED CONDUCTORS MUST BE IDENTIFIED PER NEC 210.5(C). WHITE FINISHED CONDUCTORS ARE NOT PERMITTED. 2 3 4 5 6 7 8 9 10 DC / DC CONVERTERS NO SOURCE CIRCUIT JUNCTION BOX SUNVAULT ESS SUNVAULT BATTERY INVERTER SOLAR LOAD CENTER PV PRODUCTION METER SEPARATE AC DISCONNECT HEAT DETECTOR YES NO 11 13 BACK UP LOAD CENTER NON-BACK UP LOAD CENTER EV SUPPLY EQUIPMENT NO TAG DESCRIPTION 12 REMOTE POWER OFF SWITCH 14 HUB+ INCOMING SOURCE FEED , 120/240 V, 1 PH, 3 W LOCATION: MANUF: GND TOP FED MCB GND 200A, 2P 100A,2P 225A EXTERIOR WALL SQUARE D (E) MAIN SERVICE PANEL THE DESIGNED INTERCONNECTION MEETS NEC 705.12(B)(3)(3) REQUIREMENTS 1 PV MODULE MICROINVERTER (FIELD-INSTALLED) MISOLAR / BRANCH 1. PROPER LISTING EXPECTED FOR CONDITIONS OF USE ON ALL LUGS, FITTINGS, CRIMPS, ETC. 2. ALL CONDUIT BEND RADII TO CONFORM TO THE NEC MINIMUM BEND RADII REQUIREMENTS. 3. MINIMUM CLEARANCE SHALL BE MAINTAINED PER NEC FOR ALL NEW EQUIPMENT TO BE INSTALLED. 4. EXISTING GROUNDING ELECTRODE SYSTEM MUST MEET NEC AND LOCAL UTILITY REQUIREMENTS. 5. COPPER CONDUCTORS SHALL BE USED UNLESS SPECIFIED. 6. TYPE NM (ROMEX) CONDUCTORS ARE ALLOWED FOR INTERNAL AND ATTIC RUNS AND SHALL BE INSTALLED MEETING NEC REQUIREMENTS. 7. IF MAIN SERVICE PANEL IS TO BE UPGRADED, IT WILL BE PERMITTED AND INSTALLED BY 3RD PARTY. 8. AC WIRING SHALL UPSIZE IF VOLTAGE DROP EXCEEDS 2%. 9. RUN CONDUCTORS IN EXISTING CONDUIT WHEN AVAILABLE PROVIDED IT HAS NO OTHER CONDUCTORS RUNNING THROUGH IT. 10. EQUIVALENT SPECIFICATION ON CABLES AND ELECTRICAL EQUIPMENT SPECIFIED ARE ACCEPTABLE. ELECTRICAL NOTES SUNPOWER PROVIDED MICROINVERTER EXTENSION CABLE, LISTED AS AN ASSEMBLY MAKE/MODEL: ENPHASE IQ7HS-66-M-US [240] | QTY: 20 MAKE/MODEL: WAAREE ENERGIES LIMITED WSMDI-400 | QTY: 20 ENERGY STORAGE SYSTEM MODEL: 6 YES YES 6.5 kWh BATTERY 6.5 kWh BATTERY 5 (3) #8 THWN (1) #10 THWN EGC (3) #12 COMM. CABLES 19.5 kWh, 6.8 kW SUNVAULT 6.5 kWh BATTERY INVERTER DC AC LOCKABLE INTEGRATED AC DISCONNECT 40A, 2P SV-BASE19.5-C TO (E)LOADS NO NO **GRID SENSE IN ESS NO N - B A C K U P B U S (1 2 5 A M A X ) TO (E) LOADS NO · RELOCATE APPROPRIATE BREAKERS FROM (E) MSP TO APPROPRIATE PANELS OF (N) HUB+. ·INSTALL (N) 100A, 2P SUB FEED BREAKER IN THE (E) MSP AND FEED (N) HUB+ WITH THIS BREAKER. ·THE SITE CONSUMPTION CTS INSIDE THE HUB+ MUST BE REMOVED AND PLACED UPSTREAM FROM THE POINT OF INTERCONNECTION. ·INSTALL (N) HUB+ ON THE EXTERIOR WALL ·INSTALL (N) ESS INSIDE GARAGE ·LEAVE THE FOLLOWING LOAD/S IN MSP: (E) 60A, 2P EV CHARGER, (E) 40A, 2P PV SOLAR BREAKER ·INSTALL (N) SAFETY BOLLARD ·INSTALL (N) HEAT DETECTOR SINCE ESS IS LOCATED INSIDE GARAGE ·EXISTING PV SOLAR BREAKER IS NON-SPWR MODULES ·QUAD/TWIN BREAKERS REQUIRED ·CTS ARE COMPATIBLE WITH THIS INSTALLATION ·SEE PVE-6 FOR DETAILS. 50A, 2P TO (E) SUBPANEL 40A, 2P (E) EV CHARGER (E) PV SOLAR BREAKER TRENCHING REQUIRED (TRANSITION TO EMT WHERE NECESSARY) D THWN-2 EGC: THWN-2 1 3 SCH 40 PVC 1" #8 #10 D YES JUNCTION BOX, NEMA-4 3 DC AC Branch Circuit ROOFTOP ARRAY WIRING A 9 LOCATED OUTSIDE TRENCHING REQUIRED (TRANSITION TO EMT WHERE NECESSARY) WITH VISIBLE KNIFE BLADES #1010 AC MODULES #1 F UTILITY-LOCKABLE SAFETY SWITCH 60A, 240VAC EATON DG222URB OR EQUIVALENT 40A, 2P YES 20A, 2P E (E) (E) PV MODULE · MANUF: · MODEL: · QTY: (E) INVERTER · MANUF: · MODEL: · QTY: 4.720 KW PV SYSTEM CANADIAN SOLAR CS6K-295MS 16 ENPHASE IQ6-60-2-US 16 THWN-2 EGC: THWN-2 1 EMT 3/4" #10 #10 4 2THWN-2 EGC: THWN-2 1 SCH 40 PVC 1" #8 #10 E F NOTE: SEPARATE CONDUIT RUN WILL BE UTILIZED FOR THE RELOCATED LOADS W/ CONSIDERATIONS TO AMPACITY ADJUSTMENT FACTORS LOAD LABEL BREAKER SIZE RELOCATED LOADS FROM MSP TO (N) HUB+ UNLABELED 20A, 1P 20A, 1P 20A, 1P 20A, 1P 20A, 1P 20A, 2P 20A, 1P NUMBER OF CONDUCTORS/ CONDUCTOR SIZE (AWG) (1)#10 + (1)#10 EGC (1)#10 + (1)#10 EGC (1)#10 + (1)#10 EGC (1)#10 + (1)#10 EGC (1)#10 + (1)#10 EGC (1)#10 + (1)#10 EGC (2)#10 + (1)#10 EGC 20A, 1P (1)#10 + (1)#10 EGC UNLABELED UNLABELED UNLABELED UNLABELED UNLABELED KITCHEN FRIDGE OUTLETS MASTER BED PLUG LITES (2)#10 + (1)#10 EGC15A, 2PKITCHEN LITES FAMILY RM (2)#10 + (1)#10 EGC50A, 2P(E) SUBPANEL (2)#10 + (1)#10 EGC50A, 2P(E) OVEN RANGE · MANUF: · MODEL: · LOCATION: ENPHASE --- NEAR MSP SQUARE D DU222RB, 60A NEAR MSP (E) NON-FUSED AC DISCONNECT (E) SOLAR/COMBINER PANEL · MANUF: · RATING: · LOCATION: (N) LOAD CENTER MIN., 120/240 V, NEMA-3R LOCATION: GND 7 20A, 2P 20A, 2P DETACHED GARAGE 100A DC AC Branch Circuit #102 AC MODULES #2 MLO F 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 1 9 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M EL E C T R I C A L S I N G L E - L I N E D I A G R A M & S P E C I F I C A T I O N S NTS SHEET E-1 Power back feeds are utilizing "Sum of Breakers" rule. A placard must be attached to the main panel indicating that the SUM OF ALL BREAKERS MUST BE 225A OR LESS". CEC 705.12(B)(3)(3) 1222 S Sycamore St - 201824905/3/2024 ELECTRICAL CALCULATIONS BRANCH 2 BRANCH 3BRANCH 1 NUMBER OF MODULES VOLTAGE RATED AC OUTPUT CURRENT: IOUT = MINIMUM WIRE AMPACITY: IMAX = IOUT x 1.25 CONDUCTOR DE-RATING MAXIMUM AMBIENT TEMPERATURE TEMPERATURE USED FOR AMPACITY DE-RATING TEMPERATURE DE-RATING COEFFICIENT FILL DE-RATING COEFFICIENT IWIREMIN = IOUT / TEMP_COEFF / FILL_COEFF WIRE SIZE AMPACITY CONDUCTOR SIZE CONDUCTOR SIZE ADJUSTED FOR VOLTAGE DROP OVERCURRENT PROTECTION MINIMUM OCPD = IOUT x 1.25 CALCULATED VOLTAGE DROP ONE WAY CIRCUIT LENGTH ROOF JCT BOX TO SUBPANEL WIRING #10 10 240 V 16 A 20.00 A 34 °C 34 °C 0.96 0.8 20.83 A 40 A #10 #10 1.07% 20A, 2P 20.00 A #10 8 240 V 12.8 A 16.00 A 34 °C 34 °C 0.96 1 13.33 A 40 A #10 #10 0.60% 20A, 2P 16.00 A #10 2 240 V 3.2 A 4.00 A 34 °C 34 °C 0.96 0.8 4.17 A 40 A #10 #10 0.21% 20A, 2P 4.00 A 65 FT.45 FT.65 FT. NOTE: DISTANCE ABOVE ROOF TO BOTTOM OF CONDUIT: >23mm (7/8") 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M EL E C T R I C A L C A L C U L A T I O N NTS SHEET E-2 1222 S Sycamore St - 201824905/3/2024 PHOTOVOLTAIC SYSTEM AC DISCONNECT RATED AC OUTPUT CURRENT: NOMINAL OPERATING AC VOLTAGE: SIGNAGE LOCATIONS: ·INDOOR / OUTDOOR AC DISCONNECT AMPS VOLTS · RAPID SHUTDOWN SWITCH FOR SOLAR PV SYSTEM SOLAR PV SYSTEM EQUIPPED WITH RAPID SHUTDOWN TURN RAPID SHUTDOWN SWITCH TO THE "OFF" POSITION TO SHUT DOWN AND REDUCE SHOCK HAZARD IN THE ARRAY SOLAR ELECTRIC PV PANELS SIGNAGE LOCATIONS: ·SHALL BE LOCATED ON OR NO MORE THAN 1 M (3 FT) FROM THE SERVICE DISCONNECTING MEANS TO WHICH THE PV SYSTEMS ARE CONNECTED. 19.2 A 240 V SIGNAGE LOCATIONS: ·MAIN SERVICE PANEL ENERGY STORAGE SYSTEM CONTAINS ENERGIZED BATTERIES SIGNAGE LOCATIONS: ·SUNVAULT ENERGY STORAGE SYSTEM ENERGY STORAGE SYSTEM DISCONNECT SIGNAGE LOCATIONS: ·SUNVAULT ENERGY STORAGE SYSTEM CAUTION TRI POWER SOURCES SECOND SOURCE IS AC BATTERY THIRD SOURCE IS PV SYSTEM SIGNAGE LOCATIONS: ·SUNVAULT ENERGY STORAGE SYSTEM AVAILABLE FAULT CURRENT DERIVED FROM THE ESS: DATE CALCULATION PERFORMED: ENERGY STORAGE SYSTEM DISCONNECT NOMINAL ESS AC VOLTAGE: MAXIMUM ESS DC VOLTAGE: 01-28-2024 35 A 57.6 V 120/240 VAC 60 Hz 1.MATERIAL USED FOR THE SIGNAGE SHALL BE REFLECTIVE, WEATHER RESISTANT AND SUITABLE FOR THE ENVIRONMENT. 2.ALL SIGNAGE SHALL HAVE ALL CAPITAL LETTERS WITH MINIMUM 3 8" LETTER HEIGHT, WHITE ON RED BACKGROUND. 3.MAIN SERVICE DISCONNECT MARKING SHALL BE PLACED ADJACENT TO MAIN SERVICE DISCONNECT IN A LOCATION CLEARLY VISIBLE FROM THE LOCATION WHERE THE LEVER IS OPERATED. 4.MARKING IS REQUIRED ON ALL INTERIOR AND EXTERIOR DC CONDUIT, RACEWAYS, ENCLOSURES, CABLE ASSEMBLIES, AND JUNCTION BOXES TO ALERT THE FIRE SERVICE TO AVOID CUTTING THEM. MARKINGS SHALL BE PLACED EVERY 10', AT TURNS AND ABOVE AND/OR BELOW PENETRATIONS, AND AT ALL DC COMBINER AND JUNCTION BOXES. 5.DO NOT USE SCREWS FOR SIGNAGE ATTACHMENT. USE ONLY APPROVED ADHESIVE. SIGNAGE NOTES ELECTRICAL DATA & SPECIFICATIONS WARNING: THIS EQUIPMENT FED BY MULTIPLE SOURCES. TOTAL RATING OF ALL OVERCURRENT DEVICES EXCLUDING MAIN SUPPLY OVERCURRENT DEVICE SHALL NOT EXCEED AMPACITY OF BUSBAR. SIGNAGE LOCATIONS: ·MAIN SERVICE PANEL ·NEW INDOOR / OUTDOOR LOAD CENTER ·INDOOR / OUTDOOR SUBPANEL NEC 705.12(B)(3)(3) DO NOT ADD NEW LOADS SIGNAGE LOCATIONS: ·MAIN SERVICE PANEL NO BRANCH CIRCUIT LOADS LARGER THAN AMPS MAY BE INSTALLED IN THIS SUBPANEL SIGNAGE LOCATIONS: ·HUB+ BACKUP PAN ·BACKUP LOAD CENTERS 35 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M EL E C T R I C A L D A T A & S P E C I F I C A T I O N S NTS SHEET E-3 1222 S Sycamore St - 201824905/3/2024 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M HUB+ E-ACD ESS M HD AC D E-SUB (E) S-LC N- L C FIGURE 1: SUNPOWER EQUINOX GROUNDING DETAILS (N) SOLAR AC DISCONNECT PHOTOVOLTAIC ARRAY ON ROOF SERVICE POINT & UTILITY METERING (E) SUBPANEL FIGURE 2: PLACARD IDENTIFYING LOCATION OF DISCONNECTS AND POWER SOURCES PL A C A R D / S U N P O W E R E Q U I N O X GR O U N D I N G D E T A I L S 1222 SOUTH SYCAMORE STREET HUB+ ENERGY STORAGE SYSTEM 690.47(B) NTS SHEET E-4 CAUTION: MULTIPLE SOURCES OF POWER WITH DISCONNECT(S) LOCATED AS SHOWN: (E) SOLAR AC DISCONNECT (E) PV ARRAY (E) SOLAR LOAD CENTER (N) SOLAR LOAD CENTER 1222 S Sycamore St - 201824905/3/2024 ROOF 1 ROOF 2 HUB+ E-ACD ESS M HD AC D E-SUB (E) S-LC N- L C 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M 1 2ROOF AZIMUTH PITCH MODULE QTY. 0:12 270° 12 0:12 0° 8 BR A N C H D I A G R A M N PRINT NAME OF CREW LEAD ON SITE: _________________________________ CREW LEAD SIGNATURE: _________________________________ BRANCH VOLTAGES: 1. 2. 3. 4. 5. 6. NTS SHEET E-5 HOME OWNER ACKNOWLEDGEMENT (AS-BUILT) SIGNATURE PRINTED NAME LEGEND & SYMBOLS: ROOF RAFTERS 1222 S Sycamore St - 201824905/3/2024 HUB+ Back Up Section 50A, 2p (E) SUBPANEL 20A, 2p/ 20A, 2p KITCHEN FRIDGE OUTLETS/ MASTER BED PLUG LITES 15A, 2p KITCHEN LITES FAMILY RM 20A, 1p/ 20A, 1p UNLABELED/ UNLABELED 20A, 1p/ 20A, 1p UNLABELED/ UNLABELED **, 2P/40A, 2P PVS 6/ ESS Disconnect 20A, 1p/ 20A, 1p UNLABELED/ UNLABELED 15A, 1p HEAT DETECTOR Solar Section 20A, 2P PV BREAKER 40A, 2P SOLAR LOAD CENTER Non Back Up Pan **,2P Grid Sense 50A, 2p OVEN RANGE MSP 200A, 2P MAIN CIRCUIT BREAKER 100A, 2p (N) HUB+ 40A, 2p (E) PV SOLAR BREAKER (E) SUBPANEL 15A, 1p LIGHTS 30A, 1p 20V LITES 20A, 1p WASHER 20A, 1p BATH 20A, 1p DRYER 60A, 2p EV CHARGER **BREAKERS ARE FIELD INSTALLED. BREAKER RATING MAY VARY FROM 15A OR 20A QUAD/TWIN BREAKERS REQUIRED (N) SOLAR LOAD CENTER 20A, 2P PV BREAKER 20A, 2P PV BREAKER 1 4 1 4 H A R B O U R W A Y S O U T H R I C H M O N D , C A 9 4 8 0 4 ( 5 1 0 ) 5 4 0 - 0 5 5 0 C O R P O R A T I O N , S Y S T E M S R E V I S I O N S SO L A R I N D I V I D U A L P E R M I T P A C K A G E GR I D - T I E D P H O T O V O L T A I C S Y S T E M REV DESCRIPTION DATE DB DRAWN BY: PROJECT DATE DRAWN SCALE PE G G Y S H A C K E L F O R D 12 2 2 S O U T H S Y C A M O R E S T R E E T SA N T A A N A , C A L I F O R N I A 9 2 7 0 7 RP-467399 8. 0 0 k W - D C 01-28-2024 G. Perez GRACE PEREZ C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 C A L I C E N S E C - 1 0 , B # 8 9 0 8 9 5 (N ) 19 . 5 k W h S U N V A U L T E N E R G Y S T O R A G E S Y S T E M BR E A K E R S C H E D U L E NTS SHEET E-6 1222 S Sycamore St - 201824905/3/2024 20 psf 95 mph C 0 psf Exposure Cat: Ground Snow: Code:2022 California Building Code ASCE 7-16 Live Load: Ult Wind Speed: Design Criteria: 1/29/2024 Attn.: To Whom It May Concern re: Job PEGGY SHACKELFORD RP: 1222 SOUTH SYCAMORE STREET, SANTA ANA, CALIFORNIA 92707 The following calculations are for the structural engineering design of the photovoltaic panels. All PV mounting equipment shall be designed and installed per manufacturer's approved installation specifications. If you have any questions, don't hesitate to contact. 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 Steven Procter Digitally signed by Steven Procter Date: 2024.01.29 10:27:26 -06'00' 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 2 of 7 Structure Geometry: Mean Roof Height, hn =13 ft Eave Height, he =8 ft Building Length, L =57 ft Building Width, B =35 ft Module Area =21.6 ft² Roof Properties: Roof Pitch (deg) = Roofing Type = Sheathing Type = Wood Species = Wood Fb (psf) = Wood Fv (psf) = Wood E (psf) = Wood Lag Withdrawal (lb/in) = Framing Type = Framing OC Spacing (in.) = Section Thickness, b (in.) = Section Depth, d (in.) = Section Modulus, Sx (in.^3) = Beam Span (ft) = Pen Trib Width (ft) = Rail Span (ft) = CD (Wind) = CD (Snow) = CLS = CM = Ct = CL = CF = Cfu = Ci = Cr = Mallowable_Wind (lb-ft) = Mallowable_snow (lb-ft) = 1357 4366 975 3138 1.0 1.0 1.15 1.15 1.3 1.0 1.0 1.0 1.0 1.0 1.0 1.0 1.00 1.00 1.0 1.0 1.6 1.6 1.15 1.15 4.00 4.00 1.71 3.16 8.5 20 5.50 11.25 7.56 31.64 1.50 1.50 2x6 Rafter 2x12 Rafter 24 12 230400000 230400000 266 266 129600 129600 25920 25920 5/8 OSB Sheathing 5/8 OSB Sheathing Doug Fir-Larch #2 Doug Fir-Larch #2 Rolled Comp Rolled Comp 2 2 ROOF 1 ROOF 2 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 3 of 7 Dead Load: 2.0 2.0 0.9 1.0 Total ROOF 1 DL 5.9 psf 2.0 2.0 3.9 1.0 Total ROOF 2 DL 8.9 psf 2.3 psf Roof_Dist_DL = M_Roof_Dist_DL = Def_Roof_Dist_DL = PV_uni_Dist_DL = M_PV_uni_Dist_DL = Def_PV_uni_Dist_DL = Total_uni_DL = M_Total_uni_DL = Def_Total_uni_DL = Rail_Down_DL = Rail_M_DL = Pens_Down_DL = Pens_Side_DL = Wind Load: Ultimate Wind Speed =95 mph Directionality Factor, kd =0.85 1 1 4 8 16 29 4 7 0.0048 0.0118 16 11 149 558 41 114 0.0013 0.0024 0.0035 0.0093 5 2 12 9 107 444 PV DL ROOF 1 ROOF 2 2x12 Rafter @ 12" OC Misc (Insulation etc) Rolled Comp 5/8 OSB Sheathing 2x6 Rafter @ 24" OC Misc (Insulation etc) Rolled Comp 5/8 OSB Sheathing 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 4 of 7 Topographic Factor, kzt =1 Velocity Pressure Exposure Factor, kz =0.85 Ground Elevation Factor, ke =1.00 psf Velocity Pressure, qz =16.67 Solar Equalization Factor, γa =0.60 Array Edge Factor, γE = External Pressure Up, GCp_1 = External Pressure Up, GCp_2 = External Pressure Up, GCp_3 = External Pressure Down, GCp = psf Design Pressure Up, p_1 = psf Design Pressure Up, p_2 = psf Design Pressure Up, p_3 = psf Design Pressure Down, p = uni_Dist_W_up = M_uni_Dist_W_up = Def_uni_Dist_W_up = uni_Dist_W_down = M_uni_Dist_W_down = Def_uni_Dist_W_down = Module_Up_W1 = Module_Up_W2 = Module_Down_W = Rail_Up_W1 = Rail_Up_W2 = Rail_Down_W = Rail_M_Up_W1 = Rail_M_Up_W2 = Rail_M_Down_W = Pens_Up_W1 = Pens_Up_W2 = Pens_Down_W = -220 -407 109 202 30 56 -92 -170 -26 -47 -61 -113 -55 -102 27 51 16 16 -23 -43 -14 -14 -32 -32 289 800 0.0094 0.0169 -0.0079 -0.0142 32 16 -27 -14 -244 -675 -43.51 -43.51 16.00 16.00 -13.50 -13.50 -32.26 -32.26 -2.90 -2.90 0.25 0.25 -0.90 -0.90 -2.15 -2.15 ROOF 1 ROOF 2 1.5 1.5 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 5 of 7 Rail Check (LRFD): ROOF 1 1.4D :6 lb-ft <548 lb-ft OK ROOF 1 1.2D + 1.6S + 0.5W :20 lb-ft <548 lb-ft OK ROOF 1 1.2D + 0.5S + 1.0W :36 lb-ft <548 lb-ft OK ROOF 1 0.9D + 1.0W (Up z1) :22 lb-ft <548 lb-ft OK ROOF 1 0.9D + 1.0W (Up z2) :57 lb-ft <548 lb-ft OK ROOF 2 1.4D :11 lb-ft <548 lb-ft OK ROOF 2 1.2D + 1.6S + 0.5W :38 lb-ft <548 lb-ft OK ROOF 2 1.2D + 0.5S + 1.0W :66 lb-ft <548 lb-ft OK ROOF 2 0.9D + 1.0W (Up z1) :40 lb-ft <548 lb-ft OK ROOF 2 0.9D + 1.0W (Up z2) :106 lb-ft <548 lb-ft OK Attachment Check (ASD): ROOF 1 1.0D + 0.6W :81 lbs <1325 lbs OK ROOF 1 1.0D + 0.75*[1.0S + 0.6W] :65 lbs <1325 lbs OK ROOF 1 1.0D + 1.0S :16 lbs <1325 lbs OK ROOF 1 0.6D + 0.6W (Up z1) :46 lbs <707 lbs OK ROOF 1 0.6D + 0.6W (Up z2) :123 lbs <707 lbs OK ROOF 2 1.0D + 0.6W :150 lbs <1325 lbs OK ROOF 2 1.0D + 0.75*[1.0S + 0.6W] :120 lbs <1325 lbs OK ROOF 2 1.0D + 1.0S :29 lbs <1325 lbs OK ROOF 2 0.6D + 0.6W (Up z1) :85 lbs <707 lbs OK ROOF 2 0.6D + 0.6W (Up z2) :227 lbs <707 lbs OK Lag Screw Uplift Check (ASD): ROOF 1 Lag Screw Withdrawl Value =266 lbs 5/16 Dia. ROOF 1 Lag Screw Penetration =2.5 ROOF 1 0.6D + 0.6W (Up z1) : 46 lbs <665 lbs OK ROOF 1 0.6D + 0.6W (Up z2) : 123 lbs <665 lbs OK ROOF 2 Lag Screw Withdrawl Value =266 5/16 Dia. ROOF 2 Lag Screw Penetration =2.5 ROOF 2 0.6D + 0.6W (Up z1) : 85 lbs <665 lbs OK ROOF 2 0.6D + 0.6W (Up z2) : 227 lbs <665 lbs OK 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 6 of 7 Framing Check (Pre Install vs Post Install): ROOF 1 pre: 1.0D + 1.0L :21 psf ROOF 1 post: 1.0D + 1.0L :9 psf ROOF 1 % Increase -56 %<5%OK ROOF 2 pre: 1.0D + 1.0L :23 psf ROOF 2 post: 1.0D + 1.0L :12 psf ROOF 2 % Increase -46 %<5%OK Seismic Check: Stucco 10.0 psf 2x4 Studs @ 16"2.0 psf Gypsum 3.0 psf Misc. (Insulation, etc.)2.0 psf 17 psf 1472 ft^2 25024 lbs 6 psf 1995 ft^2 11861 lbs 44 lbs 20 889 lbs %increase = (Wexisting + Wadditional) / Wexisting =OK Limits of Scope of Work and Liability 2.41% The increase in weight as a result of the solar system is less than 10% of the existing structure and therefore no further seismic analysis is required. Total Roof Area = Total Roof W =Existing Weight PV Panel W = Number of Panels = Total PV W =Additional Weight Total Wall DL = Total Wall Area = Total Wall W =Existing Weight Total Roof DL = 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 Date :1/29/2024 Job Code: PEGGY SHACKELFORD RP 7 of 7 The calculations produced for this dwelling's assessment are only for the proposed solar panel installation referenced in the stamped plan set and were made according to generally recognized structural anlaysis standards and procedures. 51 Rio Roble, San Jose, CA 95134 | 1-408-240-5500 1222 S Sycamore St - 201824905/3/2024 1222 S Sycamore St - 201824905/3/2024 Rev: 7/15/2021 RESIDENTIAL PHOTOVOLTAIC SOL-01 CBC 2019 Solar Photovoltaic (PV) Checklist for Detached SINGLE FAMILY RESIDENCES Only Instructions: The licensed contractor of record shall complete all sections, answer the ten questions and sign the certification section below. A copy of this form shall be attached to each of TWO sets of plans, of minimum 11” x 17” size. If answering NO to any of the questions, plan check shall be required. Project Address: Contractor Company Name: Contractor License Number: YES NO Are the following applicable to the proposed project? 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Will the PV system layout provide the required three-foot wide clear access pathways per Section 605.11 of the California Fire Code, and is this shown on the roof plan? Will the PV system be installed on a roof having only one roofing layer with no overlays? Will the PV array be flush mounted to the existing roof so that the plane of the modules (panels) are parallel to the plane of the roof? Will the PV system weigh maximum 4 pounds per square feet or less? Will the PV system be installed where the modules do not overhang any roof edges (such as eaves, gabled ends, ridges and hips)? Will the PV system be installed witha space of 2” minimum to 10” maximum between the underside of modules and the surface of the roof? Will the PV system be installed without using any ballast system or counter-weight system? Will the anchors be installed with a maximum horizontal anchor spacing of 6 feet and is this maximum horizontal spacing shown on the plans? Will the minimum 5/16” lag screws be installed with a minimum of 2-1/2 inch embedment into roof rafters (with pre-drilled holes) and is this minimum embedment shown on the plans? Are ALL the structural pages of the plans stamped and signed by a California licensed professional engineer? (including project specific site plan, PV layout, anchorage spacing, anchorage details and manufacturer’s PV support information.) I certify under penalty of perjury under the laws of the State of California that the above is true: Print Name: Signature: Phone Number: Date: Email Address: Planning & Building Agency Building Safety Division 20 Civic Center Plaza P.O. Box 1988 (M-19) Santa Ana, CA 92702 (714) 647-5800 www.santa-ana.org 1222 S Sycamore St - 201824905/3/2024 Design Responsibility: These tables are intended to be used under the responsible charge of a registered design professional where required by the authority having jurisdiction. In all cases, these tables should be used under the direction of a design professional with sufficient structural engineering knowledge and experience to be able to: • Evaluate whether these tables are applicable to the project, and • Understand and determine the appropriate values for all input parameters of these tables. This letter certifies that the loading criteria and design basis SunPower Invisimount Mounting System Span Tables are in compliance with the Codes above. This certification excludes the capacity check of the building structure to support the loads imposed on the building by the array, such as bending strength of roof rafters spanning between supports. This requires additional knowledge of the building and is outside the scope of the design tool and our review. If you have any questions on the above, do not hesitate to call. Prepared By: PZSE, Inc. - Structural Engineers Roseville, CA REENIIGER LARUTCURTS AINROFILACFOETATS GNELANOISSEFORPDERETSEHCAZHTENEKL N AP Exp. 3-31-25 No. S3878 R U DIGITALLY SIGNED 1222 S Sycamore St - 201824905/3/2024 February 10, 2023 SunPower 77 Rio Robles San Jose, CA 95134 TEL: (408) 514-4063 Attn: Sunpower – Engineering Department Re: Engineering Certification for the SunPower Corporation Invisimount Mounting System Span Tables and Design Methodology PZSE, Inc.-Structural Engineers has reviewed the SunPower Invisimount Mounting System Span Tables Revision F published September 21, 2021 and Revision G published August 25, 2022 and their design methodology. This certification covers the module clamp, rail analysis, and attachment Tile hook/L bracket components. All information, data and analysis contained within are based on, and comply with, the following building codes and typical specifications: Building Codes: 1. Minimum Design Loads for Buildings and other Structures, ASCE/SEI 7-16 2. 2022 California Building Code, by California Building Standard Commission 3. 2022 California Residential Code, by California Building Standard Commission 4. 2021 International Building Code, by International Code Council, Inc 5. 2015 Aluminum Design Manual, by The Aluminum Association 6. CPP Wind Tunnel report number 9790, dated 16 February 2017. 7. SEAOC PV-2, 2017 8. 2018 NDS, by the American Wood Council 9. UL 2703 Testing report for PV solar panels. 10. AC428, Acceptance Criteria for Modular Framing Systems Used to Support Photovoltaic (PV) Panels, November 1, 2012 by ICC-ES Component and Cladding Roof Zones: The Components and Cladding Roof Zones shall be determined based on ASCE 7 Chapter 30, and CPP Wind Tunnel test number 9790, dated 16 February 2017. Notes: 1) Racking system and panels shall be installed per manufacturer’s specifications. 2) Design assumptions are specified in the Inputs pages of attached span tables. 3) Attachment design is based on 5/16” Dia. Lag Screw with 2.5” Embedment into SPF#2 or equivalent per NDS. Designer shall be responsible for verifying project specific site conditions. 4) Wind speeds are LRFD values. 5) Attachment spacing(s) apply to seismic design category E or less. 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 SPAN TABLES, INVISIMOUNT 22 SQ. FT. MODULE WITH COMPOSITE SHINGLE - MOUNTING ROOF ATTACHMENT ASCE 7-16 VERSION Item Number: 524734 8-25-22 Ethan Ely REVISION HISTORY REV. DCR# DESCRIPTION DATE AUTHOR A DCO-008990 • Initial Release 4-10-17 P. Todd B DCO-010454 • Exposure D added. 10-10-17 G. Rossi C DCO-010454 • A-Series Modules Added. • Color coding of Span Tales Added. 6-11-19 E. Ely D DCR-003763 • CA Only • ASCE 7-16 Update 2-20-20 J. Mansell E DCR-003794 • Module Pressure Capacities Increased • Expanded for all States 4-27-20 J. Mansell F DCR-003922 • M-series module added 9-21-21 E. Ely G TBD • Version for Universal InvisiMount system 8-25-22 E. Ely Instructions: 1. Tables in this document have been generated from the Excel tool, item #524735 2. See the Engineering Certification Letter for Professional Engineer stamp. 3. Delete this first page when printing. 4. The Span Tables are split among several volumes due to the various combinations of Modules + Attachments + Applicable Codes. 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 List of Volumes Standard Volumes 1. 22 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-10 2. 22 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-16 3. 22 Sq. Ft. Module + Tile Attachment w/ ASCE 7-10 4. 22 Sq. Ft. Module + Tile Attachment w/ ASCE 7-16 High Loading Volumes 5. High Wind Speeds: 22 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-10 6. High Wind Speeds: 22 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-16 7. High Wind Speeds: 22 Sq. Ft. Module + Tile Attachment w/ ASCE 7-16 8. High Wind Speeds: 20 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-10 9. High Wind Speeds: 20 Sq. Ft. Module + Composite Shingle Attachment w/ ASCE 7-16 10. High Wind Speeds: 20 Sq. Ft. Module + Tile Attachment w/ ASCE 7-16 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 Document #524734 Rev G, Vol. 2 1 SunPower Proprietary InvisiMount Span Tables Engineering Summary Letter Volume: 2 ASCE 7 Version: 7-16 Module Type: 22 Sq. Ft. Module Roof Attachment: Composite Shingle High Wind: No High Snow: No The Span Tables are divided into two Parts: • Part 1: Simplified Tables (Wind Tunnel Loads) • Part 2: General Tables (ASCE 7 Analytical Method) Part 1 features spans based on forces on the InvisiMount system using exposure coefficients, GCp, provided by a Wind Tunnel Test Report by Cermak, Petrka, & Petersen (CPP). These values provide a more accurate and economical solution but apply to less configurations. It is recommended to use these values whenever possible, and when not, to use the spans provided in Part 2. Approved Attachments: The following span tables are adequate for the following roof attachments: • SunPower InvisiMount L-Foot attachment • Pegasus Composite Shingle Roof Attachment o And roof attachments with capacities equal to or greater than all of the following Load and Resistance Factor Design (LRFD) values: ▪ Tension – 1000lb ▪ Compression – 1000lb ▪ Shear – 390lb Scope: • Module orientations: Portrait & Landscape • Gable and Hip roofs only with modules not in the overhang sections of the roof • Roof heights o 30ft (Part 1 only) o 20-60ft (Part 2 only) • Roof Slope o 4:12 to 8:12 (Part 1 only) o 2:12 to 12:12 (Part 2 only) • Exposures Categories B, C, D • Basic Wind Speeds: o ASCE 7-10: 110-140mph – High Wind: 145-180mph o ASCE 7-16: 90-130mph – High Wind: 135-180mph • Ground Snow Loads: o 0-60psf (10psf increments) o High Snow Volumes: 80-200psf (20psf increments) o High Wind Volumes: 0psf 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 Document #524734 Rev G, Vol. 2 2 SunPower Proprietary Module Size and Capacity: • These tables are applicable to modules with the following dimensions: o Maximum length: 6.56 ft. (2.00 m) o Maximum surface area: 22 sq. ft. (2.04 sq. m) o Maximum height: 1.57 in. (40 mm) • These tables do not include a check of the module’s capacity. A module check must be performed by the user in addition to identifying the appropriate span. • In the Part 1 (Wind Tunnel-based) span tables, module pressures are provided adjacent to the corresponding spans. These module pressures are derived from the Wind Tunnel Test Report for each output condition. The user must confirm that the design capacities of the module to be used are greater than both the uplift and downforce pressured identified. • For the Part 2 span tables, pressure on the module must be calculated per the appropriate ASCE code (7-10 or 7-16). • A summary of the equations required to calculate these values is provided in the following section. 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 Document #524734 Rev G, Vol. 2 3 SunPower Proprietary Module Pressure Calculation (ASCE 7-16): • The following equations reflect ASCE-prescribed calculations, with values specific to InvisiMount included where possible. • Note that some conservative assumptions have been made and, in some cases, the resulting values may be more conservative than a site-specific iteration of the ASCE-based calculations. • The below equations are applicable only to modules with an area equal to or greater than 19.5 ft^2. • See below glossary for definitions of all referenced variables. • ASCE 7 §2.3 defines load combination equations for LRFD, which generate design load pressures. The controlling equations which define the design load on the module are: o 𝑷𝒖𝒑=𝟎.𝟗𝑫+𝟏.𝟎𝑾𝒖𝒑 o 𝑷𝒅𝒐𝒘𝒏=𝑴𝒂𝒙{𝟏.𝟐𝑫+𝟏.𝟔𝑺+𝟎.𝟓𝑾𝒅𝒐𝒘𝒏 𝟏.𝟐𝑫+𝟏.𝟎𝑾𝒅𝒐𝒘𝒏+𝟎.𝟓𝑺 • The process for solving for these equations is as follows: o Identify site-specific inputs: ▪ 𝒛 =[ ] 𝑓𝑡 ▪ 𝑬 =[ 𝐵 / 𝐶 / 𝐷 ] ▪ 𝑽 =[ ] 𝑚𝑝ℎ ▪ 𝒑𝒈=[ ] 𝑝𝑠𝑓 ▪ 𝜽 =[ ] 𝑑𝑒𝑔𝑟𝑒𝑒𝑠 ▪ 𝒁𝒐𝒏𝒆=[ 1 / 2 / 3 ] o Select the following coefficients from the below Look-up Tables: ▪ 𝒛𝒈 =[ ] 𝑓𝑡 ▪ 𝑪𝒆 =[ ] ▪ 𝜶 =[ ] ▪ 𝑮𝑪𝒑,−=[ ] ▪ 𝑮𝑪𝒑,+=[ ] o Use the following equations to establish wind and snow loads: ▪ The minimum allowable value for 𝑊𝑢𝑝 & 𝑊𝑑𝑜𝑤𝑛 is 16 psf. ▪ Wind, Uplift: 𝑾𝒖𝒑 =𝟎.𝟎𝟎𝟑𝟏𝟔𝟓(𝒛 𝒛𝒈 ) 𝟐 𝜶∗𝑽𝟐∗𝑮𝑪𝒑,− ▪ Wind, Downforce: 𝑾𝒅𝒐𝒘𝒏=𝟎.𝟎𝟎𝟐𝟑𝟔𝟐∗(𝒛 𝒛𝒈 ) 𝟐 𝜶∗𝑽𝟐∗𝑮𝑪𝒑,+ ▪ Snow: 𝑺 =𝒑𝒔,𝒈𝒓∗𝐜𝐨𝐬(𝜽) If 𝜃≥15°, 𝑝𝑠,𝑔𝑟=0.84 ∗𝐶𝑒∗𝑝𝑔 If 𝜃<15° 𝐴𝑁𝐷 𝑝𝑔<20 𝑝𝑠𝑓, 𝑝𝑠,𝑔𝑟=𝑝𝑔 If 𝜃<15° 𝐴𝑁𝐷 𝑝𝑔>20 𝑝𝑠𝑓, 𝑝𝑠,𝑔𝑟=𝑀𝑎𝑥{20 𝑝𝑠𝑓 0.84 ∗𝐶𝑒∗𝑝𝑔 o Add the resulting load pressures in the load combination equations (dead load is provided): ▪ 𝑷𝒖𝒑=𝟐.𝟓 𝒑𝒔𝒇+𝟏.𝟎𝑾𝒖𝒑 ▪ 𝑷𝒅𝒐𝒘𝒏=𝑴𝒂𝒙{𝟑.𝟓 𝒑𝒔𝒇+𝟏.𝟔𝑺+𝟎.𝟓𝑾𝒅𝒐𝒘𝒏 𝟑.𝟓 𝒑𝒔𝒇+𝟏.𝟎𝑾𝒅𝒐𝒘𝒏+𝟎.𝟓𝑺 1222 S Sycamore St - 201824905/3/2024 SUNPOWER CORPORATION Document #524734 Rev G SPAN TABLES, INVISIMOUNT Template FILE-074910, Ed. 2 Document #524734 Rev G, Vol. 2 4 SunPower Proprietary • Look-up Tables o Exposure-based coefficients: Exposure 𝑪𝒆 𝜶 𝒛𝒈 B 0.9 7 1200 C 0.9 9.5 900 D 0.8 11.5 700 o External pressure coefficients: ▪ These values are based on a minimum module size of 19.5 ft^2. ASCE 7-16 Gable Roof Hip Roof 7 < θ <= 20 20 < θ <= 27 27 < θ <= 45 7 < θ <= 20 20 < θ <= 27 Gcp,- Zone 1 -2.000 -1.500 -1.510 -1.800 -1.226 Zone 2 -2.585 -2.179 -1.777 -2.333 -1.777 Zone 3 -3.078 -2.471 -2.200 -2.333 -1.777 Gcp,+ All Zones 0.467 0.467 0.784 0.584 0.584 ASCE 7-16 Hip Roof θ = 30.26 (7:12) θ = 33.69 (8:12) θ = 36.87 (9:12) θ = 39.81 (10:12) θ = 42.51 (11:12) θ = 45 (12:12) Gcp,- Zone 1 -1.062 -1.126 -1.185 -1.239 -1.290 -1.336 Zone 2 -1.265 -1.419 -1.561 -1.693 -1.814 -1.926 Zone 3 -1.413 -1.541 -1.647 -1.735 -1.808 -1.866 Gcp,+ All Zones 0.551 0.551 0.551 0.551 0.551 0.551 • Glossary of variables: o 𝑃𝑢𝑝=𝑚𝑜𝑑𝑢𝑙𝑒 𝑢𝑝𝑙𝑖𝑓𝑡 𝑝𝑟𝑒𝑠𝑠𝑢𝑟𝑒 o 𝑃𝑑𝑜𝑤𝑛=𝑚𝑜𝑑𝑢𝑙𝑒 𝑑𝑜𝑤𝑛𝑓𝑜𝑟𝑐𝑒 𝑝𝑟𝑒𝑠𝑠𝑢𝑟𝑒 o 𝐷=𝑑𝑒𝑎𝑑 𝑙𝑜𝑎𝑑=2.7 𝑝𝑠𝑓 o 𝑊𝑢𝑝=𝑢𝑝𝑙𝑖𝑓𝑡 𝑤𝑖𝑛𝑑 𝑙𝑜𝑎𝑑 (𝑝𝑠𝑓) o 𝑊𝑑𝑜𝑤𝑛=𝑑𝑜𝑤𝑛𝑓𝑜𝑟𝑐𝑒 𝑤𝑖𝑛𝑑 𝑙𝑜𝑎𝑑 (𝑝𝑠𝑓) o 𝑆=𝑠𝑛𝑜𝑤 𝑙𝑜𝑎𝑑 (𝑝𝑠𝑓) o 𝑧=𝑟𝑜𝑜𝑓 ℎ𝑒𝑖𝑔ℎ𝑡 (𝑓𝑡) o 𝐸=𝑒𝑥𝑝𝑜𝑠𝑢𝑟𝑒 (𝐵,𝐶,𝑜𝑟 𝐷) o 𝑣=𝑤𝑖𝑛𝑑 𝑠𝑝𝑒𝑒𝑑 (𝑚𝑝ℎ) o 𝑝𝑔 =𝑔𝑟𝑜𝑢𝑛𝑑 𝑠𝑛𝑜𝑤 𝑙𝑜𝑎𝑑 (𝑝𝑠𝑓) o 𝜃=𝑟𝑜𝑜𝑓 𝑝𝑖𝑡𝑐ℎ (𝑑𝑒𝑔𝑟𝑒𝑒𝑠) o 𝑍𝑜𝑛𝑒=𝑟𝑜𝑜𝑓 𝑧𝑜𝑛𝑒 (1,2,𝑜𝑟 3) o 𝑧𝑔=𝑔𝑟𝑎𝑑𝑖𝑒𝑛𝑡 ℎ𝑒𝑖𝑔ℎ𝑡 (𝑓𝑡) o 𝛼=𝑔𝑢𝑠𝑡 𝑝𝑟𝑜𝑓𝑖𝑙𝑒 𝑓𝑎𝑐𝑡𝑜𝑟 o 𝐶𝑠=𝑅𝑜𝑜𝑓 𝑠𝑙𝑜𝑝𝑒 𝑓𝑎𝑐𝑡𝑜𝑟 o 𝐶𝑒=𝑒𝑥𝑝𝑜𝑠𝑢𝑟𝑒 𝑓𝑎𝑐𝑡𝑜𝑟 o 𝐺𝐶𝑝,−= 𝑒𝑥𝑡𝑒𝑟𝑛𝑎𝑙 𝑝𝑟𝑒𝑠𝑠𝑢𝑟𝑒 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡,𝑢𝑝𝑙𝑖𝑓𝑡 o 𝐺𝐶𝑝,+= 𝑒𝑥𝑡𝑒𝑟𝑛𝑎𝑙 𝑝𝑟𝑒𝑠𝑠𝑢𝑟𝑒 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡,𝑑𝑜𝑤𝑛𝑓𝑜𝑟𝑐𝑒 o 𝑝𝑠=𝑠𝑙𝑜𝑝𝑒𝑑 𝑟𝑜𝑜𝑓 𝑠𝑛𝑜𝑤 𝑙𝑜𝑎𝑑 o 𝑝𝑠,𝑔𝑟=𝑠𝑛𝑜𝑤 𝑙𝑜𝑎𝑑,𝑖𝑛 𝑑𝑖𝑟𝑒𝑐𝑡𝑖𝑜𝑛 𝑜𝑓 𝑔𝑟𝑎𝑣𝑖𝑡𝑦 1222 S Sycamore St - 201824905/3/2024 Document #524734 Rev G, Vol. 2 5 SunPower Proprietary Inputs (ASCE 7-16): The following tables list the allowable spacing of attachment points for the SunPower InvisiMount mounting system. The following building codes and standards were used in the calculations: • International Building Code (IBC 2018) • International Residential Code (IRC 2018) • Minimum Design Loads for Buildings and Other Structures (ASCE 7-16) • Aluminum Design Manual (ADM1), 2015 • National Design Specification (NDS) for Wood Construction, 2018 The International Building Code is either adopted fully or mostly by each state. The accompanying Engineering Certification Letter lists the building code for the state which this project. Loads on the system were calculated in accordance with ASCE 7-16, using the following parameters: • Risk Category II • Dead Load: System weight (including PV modules and rails) = 2.7 psf • Roof Live Load: 0psf – No live load acts on top of the PV modules • Roof Snow Load Data: o Ground snow load, pg, as indicated in the tables (Fig. 7-1) o Thermal factor, Ct = 1.2, ‘unheated and open-air structures’ (Table 7.3-2) o Exposure factor, Ce = 0.9, ‘fully exposed’ (Table 7.3-1) o Slope factor, Cs, varies with slope and assumes the array is an ‘unobstructed slippery surface’ where snow is free to slide off the array (Figure 7.4-1) • Wind Design Data (Designed per Chapter 30, Components & Cladding): o With modifications to GCp values per SEAOC PV2-2017 o Basic Design Wind speed, V, and exposure category as indicated in the tables (Figure 26.5-1B) o Roof height and slope as indicated in the tables (§26.2) o Topographic factor, Kzt = 1.0 (Table 26.6-1) o Directionality factor, Kd = 0.85 (Table 26.6-1) o Velocity Coefficient, Kh = 2.01(z/zg)^(2/a) (as indicated in Table 26.10-1) o Velocity Pressure Exposure Coefficient, Ke=1 (Table 26.9.1) o Pressure coefficients, GCp, per either wind tunnel testing or Chapter 30 (see notes below tables) • Earthquake Design Data (Designed per Chapter 13: Non-structural Components) o Seismic Design Category E, Soil Site Class D assumed o Mapped MCE Short Period, 0.2sec, Ss = 3.73g, maximum in the United States (Fig. 22 -1) o Mapped MCE Short Period, 1sec, S1 = 1.39g (Fig. 22-2) o Importance Factor, Ip = 1.0 (§13.1.3) o Amplification Factor, ap=1.0 (Table 13.6-1) o Response Factor, Rp=1.5 (Table 13.6-1) • Load combinations per IBC §1605, using Load and Resistance Factor Design (LRFD) 1222 S Sycamore St - 201824905/3/2024 Document #524734 Rev G, Vol. 2 6 SunPower Proprietary Methodology: The maximum allowable spans shown in the tables are based on a combination of dead, wind, seismic, and snow loads calculated from the inputs above and combined using LRFD combinations. The maximum forces are then compared to the minimum capacities determined in the following ways: • Rail bending and shear: ADM1 LRFD checks • Rail to roof attachment: SunPower Test Reports of the rail bolt between the rail and the roof attachment. • Roof attachment: Manufacturer product information • Roof attachment to rafter: Lag screw withdrawal and shear per NDS • The reported maximum spacing is the greatest allowed spacing, rounded down to the nearest rafter spacing increment, for which the demand/capacity ratios are less than or equal to 1.0, assuming both 16” and 24” rafter spacings. • These tables do not consider the strength of the supporting roof structure. In areas of low snow load, the weight of the array is often considered to offset the design live load of the roof, since personnel and equipment cannot be placed on top of the array. It is recommended to stagger attachment points, as shown in Figure 1, to evenly distribute loads to the rafters. Figure 1 • These tables assume that each module is installed centered over a pair of rails, as shown in Figure 2(a). In cases where one rail is closer to the midpoint of the module, as shown in Figure 2(b), adjustments to the spacing may be required. Figure 2 1222 S Sycamore St - 201824905/3/2024 Document #524734 Rev G, Vol. G 29 SunPower Proprietary InvisiMount Span Tables Part 2: General Tables (ASCE 7 Analytical Method) How to Use These Tables • Determine the snow load and roof height for the site and select the corresponding table. • Determine the wind speed and roof slope for the site. The value in the table, for this wind speed and roof slope, is the allowable span between attachment points, in inches. • See figure below for locations of zones 1, 2 and 3. Dimension “a” is 10% of the least horizontal dimension or 0.4h, whichever is smaller, but not less than either 4% of the least horizontal dimension or 3 feet. 1222 S Sycamore St - 201824905/3/2024 Notes: • Tables are based on strength of the InvisiMount rail and approved roof attachment in the Engineering Summary Letter of this document, in conformance with IBC and referenced standards. • Maximum allowable cantilever is equal to 1/3 of the allowable span. • Wind speeds are ultimate values in mph, as defined in ASCE 7. Wind pressure coefficients are derived from ASCE 7 Chapter 30. • User is responsible for verifying the strength of the roof. • User is responsible for verifying the capacity of the module. Refer to the section of this document titled “Module Pressure Calculation”, or the appropriate ASCE code (7-10 or 7-16), for instructions on calculating the uplift and downforce module pressures. Document #524734 Rev G, Vol. 2 95 SunPower Proprietary Exposure C Ground Snow (psf) 0 Roof Height (ft) 20 INVISIMOUNT ALLOWABLE SPANS - ZONE 1 (IN) Slope → 9.46 ° 14.04 ° 18.43 ° 22.62 ° 26.57 ° 30.26 ° 33.69 ° 36.87 ° 39.81 ° 42.51 ° 45 ° Speed↓ 2:12 3:12 4:12 5:12 6:12 7:12 8:12 9:12 10:12 11:12 12:12 90 96 96 96 96 96 96 96 96 96 96 96 95 96 96 96 96 96 96 96 96 96 96 96 100 96 96 96 96 96 96 96 96 96 96 96 105 80 80 80 96 96 96 96 96 96 96 96 110 80 80 80 96 96 96 96 96 96 96 96 120 72 72 72 80 80 80 80 80 80 80 80 130 72 72 72 80 80 80 80 80 80 80 80 INVISIMOUNT ALLOWABLE SPANS - ZONE 2 (IN) Slope → 9.46 ° 14.04 ° 18.43 ° 22.62 ° 26.57 ° 30.26 ° 33.69 ° 36.87 ° 39.81 ° 42.51 ° 45 ° Speed↓ 2:12 3:12 4:12 5:12 6:12 7:12 8:12 9:12 10:12 11:12 12:12 90 80 80 80 96 96 96 96 96 96 96 96 95 80 80 80 96 96 96 96 96 96 96 96 100 80 80 80 80 80 96 96 96 96 96 96 105 72 72 72 80 80 96 96 96 96 96 96 110 72 72 72 80 80 80 80 80 80 80 80 120 48 48 48 72 72 80 80 80 80 80 72 130 48 48 48 64 64 72 72 72 72 72 64 INVISIMOUNT ALLOWABLE SPANS - ZONE 3 (IN) Slope → 9.46 ° 14.04 ° 18.43 ° 22.62 ° 26.57 ° 30.26 ° 33.69 ° 36.87 ° 39.81 ° 42.51 ° 45 ° Speed↓ 2:12 3:12 4:12 5:12 6:12 7:12 8:12 9:12 10:12 11:12 12:12 90 80 80 80 96 96 96 96 96 96 96 96 95 72 72 72 80 80 96 96 96 96 96 96 100 72 72 72 80 80 80 80 80 80 80 80 105 64 64 64 72 72 80 80 80 80 80 80 110 48 48 48 72 72 80 80 80 80 80 80 120 48 48 48 64 64 72 72 72 72 72 72 130 48 48 48 48 48 64 64 64 48 48 48 1222 S Sycamore St - 201824905/3/2024 sunpower.com Datasheet SunPower® SunVault™ Energy Storage System (ESS) Performance SunVault Base SunVault Base High Energy Model Number SV-BASE13-C SV-BASE19.5-C DC Rated Energy 13 kWh 19.5 kWh Max. Usable Energy (DC)1 12 kWh 18 kWh Battery Cell Chemistry Lithium iron phosphate (LiFePO4) Nom. Internal Battery Voltage 51.2 V CEC Weighted RTE Efficiency2 > 86% Max. AC Continuous Backup Output Current 28.3 A Max. AC Output Fault Current 35 A AC Overcurrent Protection Device 40 A / two pole Nom. AC Voltage (L–N–L) 120 / 240 VAC 60 Hz, split phase4 Max. Short Circuit Rating 10 kA Max. Single-Phase Load Supported (120 V) 4.8 kW (up to 5 minutes) Power Factor (full-rated power) ± 0.85 Rated Continuous Charge Power (Grid tied & Backup) 6.4 kW AC Rated Continuous Discharge Power (Grid tied) 6.0 kW AC Rated AC Continuous Output Current (Grid tied) 25.0 A Rated Backup Discharge Power Continuous 6.8 kW AC Environmental Seismic Rating IEEE 693-2005, AC-156 Environmental Rating10 Indoor and outdoor rated Acoustic Noise Level < 50 dBA @ 1 m distance, 86°F (30°C) Recommended Operating Temp. 32°F to 86°F (0°C to 30°C) Ambient Operating Temp.6 14°F to 122°F (−10°C to 50°C) Shelf Ambient Temp. −4°F to 113°F (−20°C to 45°C) Initial Energy Reserve 30% Humidity 0–95% (non-condensing) Enclosure Type / Ingress Rating NEMA Type 3R / IP54 Max. Elevation 6560 ft (2000 m) Warranties, Certifications, and Compliance Warranty 10 years Certifications and Compliance • IFCC Part 15 Subclass B • IEEE 1547 • UL 1973 (UL 1642) • UL 1741 • UL 1741 SA (CA Rule 21) • UL 1741 SB • UL 9540 • UL 9540A • UN 38.3 • UL 67 Mechanical User Interface Mobile app, LED panel Dimensions 64.5 h × 28 w × 14 in. d (164 × 71 × 36 cm)7 ESS Disconnecting Means Integrated AC disconnect: • Rotary style • Open air • Lockable in OPEN position Weight • SV-BASE: 259 lb (117.5 kg) • SV-BASE13: 479 lb (217 kg) • SV-BASE19.5: 589 lb (267 kg) Mounting Options Wall or floor8 sunpower.com Datasheet Configurations and Specifications SunVault System Configuration 13-1 19.5-1 26-2 39-2 Included Component Model Numbers⁹ • One Hub+® • One SV-BASE13-C • One Hub+® • One SV-BASE19.5-C • One Hub+® • Two SV-BASE13-C • One Hub+® • Two SV-BASE19.5-C DC Rated Energy 13 kWh 19.5 kWh 26 kWh 39 kWh Max. Usable Energy (DC)1 12 kWh 18 kWh 24 kWh 36 kWh Max. AC Continuous Backup Output Current 28.3 A continuous 56.6 A continuous Max. AC Output Fault Current 35.0 A 70.0 A AC Overcurrent Protection Device One 40 A / two pole Two 40 A / two pole Rated Single-Phase Load Supported (120 V) 4.8 kW (up to 5 minutes) 9.6 kW (up to 5 minutes) Rated Continuous Charge Power (grid tied and backup) 6.4 kW AC 12.8 kW AC Rated Continuous Discharge Power (grid tied) 6.0 kW AC 12.0 kW AC Rated Continuous Discharge Power (backup) 6.8 kW AC 13.6 kW AC Rated AC Continuous Output Current (grid tied) 25.0 A 50.0 A Load Start Capability (LRA) 43 A 52 A 86 A 104 A Rated Backup Discharge Power (kW)5 30 minutes 7.5 8.0 15.0 16.0 10 seconds 8.5 12.0 17.0 24.0 1 second 10.0 12.0 20.0 24.0 1 Some energy reserved for internal consumption. 2 Tested at 6 kW, 25°C conditions. 3 SunVault Hub+ rating is 200 A. 4 208 VAC is not supported at this time. 5 Values are rated at 25°C ambient. 6 Extended exposure reduces battery performance. 7 Two ESS enclosures for 26 kWh and 39 kWh. 8 Additional hardware details in installation guide 9 SV-BASE13-C and SV-BASE19.5-C ship as the same item and are field marked for 13 kWh or 19.5 kWh; a BASE may be converted in the field to a BASE X. 10 SunVault is designed and intended for residential use only. Specifications included in this datasheet are subject to change. Some parameters can vary depending on site-specific conditions. See the SunVault Storage Installation Guide 6503770 for guidelines. See www.sunpower.com/facts for additional reference information. Specifications included in this datasheet are subject to change without notice. © 2023 SunPower Corporation. All Rights Reserved. SUNPOWER, the SUNPOWER logo, and SUNVAULT are trademarks or registered trademarks of SunPower Corporation in the U.S. and other countries as well. 1-800-SUNPOWER. 536812 RevH January 2024 1222 S Sycamore St - 201824905/3/2024 sunpower.com Datasheet SunPower® SunVault™ Hub+™ Electrical Model Number SV-HUB-01-B / SV-HUB-01-C Applications Self-supply, backup, and cost savings Special Features PCS, Remote Power Off Supported Backup Configurations •Whole home (up to 200 A service) •Partial home (up to 400 A service) Max. Allowed Service / Disconnect Rating 200 A Nom. Allowed Service Voltage 120 / 240 V 60 Hz, split phase Short Circuit Rating1 10 kA / 22 kA2 Overcurrent Protection Device Allowed3 100–200 A / service entrance rated AC Metering Solar meter: ANSI C12.20, < 0.5% RGM | Site meter: < 2% Connectivity Ethernet, WiFi, and cellular Backup Transition Seamless Load / Generation Breakers4 Refer to installation guide for available spaces Overvoltage Category OV IV Pollution Degree III Protection Class I Scalability5 Supports multiple storage and PV systems in parallel 1 Higher short circuit rating is compatible with external suitable rated equipment. 2 With external J-Class fuse or CSR breaker. See the SunVault Installation Guide for guidelines. 3 Recommended service-rated circuit breaker type must be installed. 4 See the SunVault Installation Guide for guidelines. 5 See the SunVault Installation Guide for guidelines. Refer to www.sunpower.com/facts for additional reference information. For more details, see extended datasheet www.sunpower.com/datasheets. Specifications included in this datasheet are subject to change without notice. ©2022 SunPower Corporation. All Rights Reserved. SUNPOWER, the SUNPOWER logo, SUNVAULT, and Hub+ are trademarks or registered trademarks of SunPower Corporation in the U.S. and other countries as well. 1-800-SUNPOWER. Environmental Ambient Operating Temp. −4°F to 122°F (−20°C to 50°C) Shelf Ambient Temp. −22°F to 140°F (−30°C to 60°C) Humidity 0–95% (non-condensing) Enclosure Type / Ingress Rating NEMA Type 3R / IP54 Max. Elevation 6560 ft (2000 m) Environment Indoor / Outdoor Mechanical Dimensions 17 w × 46 h × 6 in. d (43 × 117 × 15 cm) Weight 80 lb (36 kg) Mounting Options Indoor / Outdoor Conduit Entry Multiple; up to 3 in. (7.6 cm) Warranties, Certifications, and Compliance Warranty 10 years Certifications and Compliance •ANSI C12.20 (Class 0.5) •CSA C22.2 No. 107.1 •FCC Part 15 Subclass B •UL 67 •UL 869A •UL 1741 •UL 1741 CRD PCS 55 33 66 88 11 33 ReRe vv DD 1222 S Sycamore St - 201824905/3/2024 996.00±1.00Mounting Hole8Nos-8x12 ARKA SERIES WSMDi-395 to WSMDi-415 ELECTRICAL CHARACTERISTICS +VE TERMINAL 996.00±1.00 400.00±1.00 Mounting Hole 8Nos-8x12 Mounting Hole 4Nos-7x10 Ho l e Dr a i n i n g Better performance under all climatic conditions Split junction box Reduced power losses up to 1/4 times PID resistant with long term reliability Sustain heavy wind & snow loads (2400 pa & 5400 pa) I-V VARIATION WITH IRRADIANCE I-V VARIATION WITH TEMPERATURE The Graphs are for reference purpose only. Please consult Waaree technical team for further clarifications. ISO 9001:2015 l ISO 14001:2015 l ISO 45001:2018 Independent assessment of factories by BLACK & VEATCH 2 M6 Mono PERC cells 166 mm Highest reliability & enhanced crack tolerant 9BB module ARKA SERIES WSMDi-395 to WSMDi-415 Linear Performance Warranty Standard Performance Warranty 1 5 12 27 100% 98.00% 91.95% 83.70% INTERNATIONAL & NATIONAL CERTIFICATIONS^ IEC 61215 | IEC 61730 | UL61730 IEC TS 62804-1 • The electrical data given here is for reference purpose only. • Please confirm your exact requirements with the sales representative while placing your order. • Refer installation Manual instructions & Waaree warranty statement for terms & conditions. • Waaree Reserves the right to change the specifications without prior notice.z Temperature coefficient of Current (Isc), α (%/ºC) Temperature coefficient of Voltage (Voc), ß (%/ºC) Temperature coefficient of Power (Pm), γ (%/ºC) NOCT (ºC) Operating temperature range (ºC) 43 ± 2 -40 to 85 DESIGN SPECIFICATIONS MECHANICAL CHARACTERISTICS Length x Width x Thickness (L x W x T) Weight Solar Cells per Module (Units) / Arrangement Solar Cell Type & Size Front Glass Encapsulate Junction Box (Protection degree/ Material ) Cable & Connector (Protection degree / Type) Cable cross - section & Length 2 Waaree Energies Ltd. is amongst the top Solar Energy Companies and has the country's largest Solar PV Module manufacturing capacity of 5 GW. In addition, it is committed to provide top notch EPC services, project development, rooftop solutions, solar water pumps and also in an Independent Power Producer. Waaree has its presence in over 325+ locations nationally and 68 countries globally. *If you need specific product certificates, and if module installations are to deviate from our guidance specified in our installation manual, please contact your local Waaree sales and technical representatives. 0.055 -0.285 -0.365 12 Years Product Warranty • 27 Years Power Output Warranty Models Pmax (W) STC NOCT Vmp (V) STC NOCT Imp (A) STC NOCT Isc (A) STC NOCT Voc (V) STC NOCT Module Eff. (%) 34.70 34.90 35.10 WSMD-395 WSMD-400 WSMD-405 WSMD-410 WSMD-415 *Standard Test Conditions (STC) - 1000 W/m2 irradiance, Air Mass 1.5 and 25°C cell temperature. Nominal Operating Cell Temperature (NOCT) - 800 W/m2 irradiance, Air Mass 1.5, Ambient temperature 20°C and Wind speed 1 m/s. Average power reduction of 4.5% at 200 W/m2 as per IEC 60904-1. Measuring Uncertainty ± 3%. 19.78 20.03 20.28 20.53 20.78 45.00 45.22 45.44 45.66 45.88 42.10 42.30 42.50 42.70 42.90 11.24 11.32 11.40 11.48 11.57 9.08 9.14 9.21 9.27 9.34 10.47 10.54 10.61 10.68 10.75 8.55 8.62 8.68 8.74 8.81 37.77 38.00 38.22 38.44 38.66 35.30 35.40 395 400 405 410 415 296.8 300.6 304.4 308.2 312.1 ARKA SERIES WSMDi-395 to WSMDi-415 ELECTRICAL CHARACTERISTICS System Voltage 1500 V Series Fuse Rating 22 A VE TERMINAL-+VE TERMINAL996.00±1.001360.00±1.00860.00±1.00 400.00±1.00Mounting Hole 8Nos-8x12 Mounting Hole 4Nos-7x10Grounding Hole Ø4mm-2No's Hole Draining THERMAL CHARACTERISTICS Anodized Aluminium Alloy, Anodization thickness ≥15 micron 4 mm & 1200mm 1924 mm (L) x 1038 mm (W) x 35 mm (T) 22 kgs 132 cells / (11x6 || 11x6) Mono PERC, 83 x 166 mm 3.2 mm Low Iron and Tempered glass with ARC coating PID Free & UV Resistant IP68 / Weatherproof PPO IP68 rated / Staubli MC4 Connector WEL/E&PD/395-415/132/MP/HC/CMZ/01/27.07.2022 Frame Fire rating Type 2 1222 S Sycamore St - 201824905/3/2024 The high-powered smart grid-ready IQ7HS Microinverter with integrated MC4 connectors dramatically simplifies the installation process while achieving the highest system efficiency. The IQ Series Microinverters extend the reliability standards set forth by previous generations and undergo over a million hours of power-on testing, enabling Enphase to provide an industry-leading warranty of up to 25 years. IQ7HS Microinverter To learn more about Enphase offerings, visit enphase.com Data Sheet Enphase Microinverter Region: AMERICAS Easy to Install • Lightweight and simple • Faster installation with improved, lighter two-wire cabling • Built-in rapid shutdown compliant (NEC 2014, 2017 & 2020) Efficient and Reliable • Highest CEC efficiency of 97.0% • More than a million hours of power-on testing • Class II double-insulated enclosure • UL listed Smart Grid-Ready • Complies with advanced grid support, voltage and frequency ride-through requirements • Remotely updates and responds to changing grid-requirements • Configurable for varying grid profiles • Meets CA Rule 21 (UL1741-SA) and IEEE 1547:2018 (UL1741-SB) To learn more about Enphase offerings, visit enphase.com © 2022 Enphase Energy. All rights reserved. All trademarks or brands used are the property of Enphase Energy, Inc. 12-15-2022 INPUT DATA (DC)IQ7HS-66-M-US Commonly used module pairings¹320W - 460W Module compatibility²66 cell/120 half-cell/132 half-cell Maximum input DC voltage 59V Peak power tracking voltage 38V - 43V Operating range 20V - 59V Min/Max start voltage 30V/59V Max DC short circuit current (module Isc)15A Overvoltage class DC port II DC port backfeed current 0A PV array configuration 1 x 1 ungrounded array; No additional DC side protection required; AC side protection requires max 20A per branch circuit OUTPUT DATA (AC)@240 VAC @208 VAC Peak output power 384 VA 369 VA Maximum continuous output power 384 VA 369 VA Nominal (L-L) voltage/range³240V/211-264V 208V/183-229V Maximum continuous output current 1.60A (240V) 1.77A (208V) Nominal frequency 60 Hz 60 Hz Extended frequency range 47 Hz to 68 Hz 47 Hz to 68 Hz AC short circuit fault current over 3 cycles 4.82A 4.82 A Maximum units per 20 A (L-L) branch circuit4 10 9 Overvoltage class AC port III III AC port backfeed current 18 mA 18 mA Power factor setting 1.0 1.0 Power factor (adjustable)0.85 leading ...0.85 lagging 0.85 leading ...0.85 lagging EFFICIENCY @240V @208V CEC weighted efficiency 97.0 % 96.5 % MECHANICAL DATA Ambient temperature range Relative humidity range Connector type Dimensions (WxHxD) Weight Cooling Approved for wet locations Pollution degree Enclosure Environmental category/UV exposure rating Altitude -40ºC to +60ºC 4% to 100% (condensing) Staubli made MC4 212 mm x 175 mm x 30.2 mm (without bracket) 1.08 kg (2.38 lbs) Natural convection - No fans Yes PD3 Class II, corrosion resistant polymeric enclosure NEMA type 6/outdoor 2000 m FEATURES Communication Power Line Communication (PLC) Disconnecting means The AC and DC connectors have been evaluated and approved by UL for use as the load-break disconnect means required by NEC 690 and C22.1-2018 Rule 64-220. Compliance CA Rule 21 (UL1741-SA), IEEE 1547:2018 (UL1741-SB), UL 62109-1, FCC Part 15 Class B, HECO v1.1, ICES-0003 Class B, CAN/CSA-C22.2 NO. 107.1-01 This product is UL listed as PV Rapid Shutdown Equipment and conforms with NEC 2014, NEC 2017, and NEC 2020 section 690.12 and C22.1-2018 Rule 64-218 Rapid Shutdown of PV Systems, for AC and DC conductors, when installed according to manufacturer’s instructions. 1. No enforced DC/AC ratio. See the compatibility calculator at https://enphase.com/en-us/support/module-compatibility. 2. Provided the module is compatible with all other parameters in the datasheet. 3. Nominal voltage range can be extended beyond nominal if required by the utility. 4. Limits may vary. Refer to local requirements to define the number of microinverters per branch in your area. IQ7HS Microinverter 1222 S Sycamore St - 201824905/3/2024 © 2022 Enphase Energy, Inc. enphase.com July 29, 2022 To whom it may concern, This letter confirms and attests that: SPWR-A5 is equivalent to Enphase Models: IQ7HS-66-ACM-US, 369 VA, 208Vac Grid Support Utility Interactive Inverter IQ7HS-66-E-ACM-US, 369 VA, 208Vac Grid Support Utility Interactive Inverter IQ7HS-66-M-US, 369 VA, 208Vac Grid Support Utility Interactive Inverter IQ7HS-66-ACM-US, 384 VA, 240Vac Grid Support Utility Interactive Inverter IQ7HS-66-E-ACM-US, 384 VA, 240Vac Grid Support Utility Interactive Inverter IQ7HS-66-M-US, 384 VA, 240Vac Grid Support Utility Interactive Inverter Regards, Aranjit Sangha Senior Staff Engineer Enphase Energy Inc. 1420 North McDowell Blvd. Petaluma, CA 94954 v: (707) 763-4784 x7098 asangha@enphaseenergy.com 1222 S Sycamore St - 201824905/3/2024 Unirac Technical Datasheets Delivering Value through Innovation 2-Piece Standoff Technical Datasheet Pub 101026-1td V1.0 October 2010 1 . . . . . . . . . . . . . . . . . . . 2 2-Piece Aluminum Standoffs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-Piece Aluminum Standoff with SolarMount-I 1-flange connection . 2-Piece Aluminum Standoff with L-foot connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 X Z Y Standoff and Base Material: •One of the following extruded aluminum alloys: 6005-T5, 6105-T5, 6061-T6 •Ultimate tensile: 38 ksi; Yeild: 35 ksi •Clear or Dark anodized Weight: •3” Standoff (as shown): 0 .522 pounds (237 g) •Add 0 .086 pounds per inch (39 g/ inch) Allowable and design loads are valid for a Unirac 2-piece aluminum standoff Attach with zinc plated carbon steel or stainless steel fasteners Resistance and safety factors are determined according to Part 1A section 9 of the 2005 Aluminum Design Manual NOTE: Loads are given for the standoff only. Check load limits for lag screw or other attachment method. Applied Load Direction Average Ultimate Load lbs (N) Allowable Load lbs (N) Safety Factor, W Design Load lbs (N) Resistance Factor, F Tension/ Compression, Y± 3266 (14528) 1089 (4844)3 .00 1633 (7264) 0 .500 Z Bending, Applied Moment* 559 ft lbs (758 Nm) 250 ft lbs (339 Nm)2 .24 378 ft lbs (512 Nm)0 .676 2-Piece Aluminum Standoffs Part No. 310503, 310504, 310506, 310507, 310553, 310554, 310556, 310557, 310603, 310604, 310606, 310607, 310653, 310654, 310656, 310657 Standoffs Dimensions specified in inches unless noted *Example: If the module is mounted 6” (0.5 ft) from the base of the standoff, the allowable side load is 250 ft*lbs/ 0.5 ft = 500 lbs 1 Unirac Technical Datasheets Delivering Value through Innovation R X Z Y X Z Y Reference the SolarMount-I series datasheet for 1-flange connection specifications . For the 1-flange connection to standoff: •Use included 1 ¾” EPDM washer between the 1-flange connection and standoff • Assemble with included 300 series stainless steel ⅜”-16 flanged hex head screw •Use anti-seize and tighten to 30 ft-lbs of torque Allowable and design loads are valid when components are assembled according to authorized Unirac documents . 1-Flange connections are compatible with SolarMount-I series beams . Resistance factors and allowable loads are determined according to part 1A section 9 of the 2005 Aluminum Design Manual . NOTE: Loads are for the connection and standoff only. Check load limits for the lag screw or other attachment method. Reference the SolarMount datasheet for L-foot specifications . For the L- foot to standoff connection: •Use included 1 ¾” EPDM washer between the L-foot and standoff • Assemble with included 300 series stainless steel ⅜”-16 flanged hex head screw •Use anti-seize and tighten to 30 ft-lbs of torque Allowable and design loads are valid when components are assembled according to authorized Unirac documents . L-feet are compatible with SolarMount, SolarMount Heavy Duty, and SunFrame rails . Resistance factors and allowable loads are determined according to part 1A section 9 of the 2005 Aluminum Design Manual . NOTE: Loads are for the connection and standoff only. Check load limits for the lag screw or other attachment method. Applied Load Direction Average Ultimate lbs (N) Allowable Load lbs (N) Safety Factor, FS Design Loads lbs (N) Resistance Factor, Φ Tension, Y+1415 (6294) 635 (2825) 2 .23 960 (4270) 0 .679 Compression, Y-1949 (8670) 873 (3883) 2 .23 1320 (5872) 0 .677 Transverse, X-, downhill 635 (2825) 313 (1392) 2 .03 473 (2104) 0 .745 Transverse, X+, uphill 42 (187) 20 (89) 2 .15 30 (133) 0 .705 Z Bending, Applied Moment 559 ft lbs (758 Nm) 250 ft lbs (339 Nm) 2 .24 378 ft lbs (512 Nm) 0 .676 Applied Load Direction Average Ultimate lbs (N) Allowable Load lbs (N) Safety Factor, FS Design Loads lbs (N) Resistance Factor, Φ Tension, Y+1859 (8269) 707 (3144) 2 .63 1069 (4755) 0 .575 Compression, Y-3258 (14492) 1325 (5893) 2 .46 2004 (8913) 0 .615 Sliding, Z±1766 (7856) 755 (3356) 2 .34 1141 (5077) 0 .646 Transverse, X±486 (2162) 213 (949) 2 .28 323 (1436) 0 .664 Z Bending, Applied Moment 559 ft lbs (758 Nm) 250 ft lbs (339 Nm) 2 .24 378 ft lbs (512 Nm) 0 .676 2-Piece Aluminum Standoff with SolarMount-I 1-flange connection Part No. 05013C, 05014C, 05016C, 05017C 2-Piece Aluminum Standoff with L-foot connection 2 1222 S Sycamore St - 201824905/3/2024 SunPower® InvisiMount™ | Residential Mounting System Simple and Fast Installation • Integrated module-to-rail grounding • Pre-assembled mid and end clamps • Levitating mid clamp for easy placement • Mid clamp width facilitates consistent, even module spacing • UL 2703 Listed integrated grounding Flexible Design • Addresses sloped and low-sloped residential roofs • Design in landscape and portrait with up to 8ʼ rail span • Pre-drilled rails and rail splice • Rails enable easy obstacle management Customer-Preferred Aesthetics • Best-in-class system aesthetics • Black anodized components • Low-profile mid clamps and capped, flush end clamps Part of Superior System • Best-in-class system reliability and aesthetics • Optional rooftop transition flashing, rail- mounted J-box, and wire management rail clips • Combine with SunPower modules and mySunPower® monitoring app Elegant Simplicity SunPower® InvisiMount™ is a SunPower-designed rail-based mounting system. The InvisiMount system addresses residential sloped roofs and combines faster installation time, design flexibility, and superior aesthetics. Classic InvisiMount is specifically envisioned and engineered to pair with SunPower modules; Universal InvisiMount is compatible with a wide range of modules. The resulting system-level approach amplifies the installation and aesthetic benefits—for homeowners and for installers. sunpower.com Datasheet SunPower® InvisiMount™ | Residential Mounting System InvisiMount Component Details Classic mid clamp Black oxide stainless steel 300 series 63 g (2.2 oz) Universal mid clamp Black anodized aluminum 6000 series 60 g (2.1 oz) Classic end clamp Black anodized aluminum 6000 series 110 g (3.88 oz) Universal end clamp Black anodized aluminum 6000 series 103 g (3.63 oz) Rail Black anodized aluminum 6000 series 830 g/m (9 oz/ft) Rail splice Aluminum alloy 6000 series 830 g/m (9 oz/ft) Rail bolt M10-1.5 × 25 mm; custom T-head SS304 18 g (0.63 oz) Rail nut M10-1.5; DIN 6923 SS304 nominal Ground lug assembly SS304; A2-70 bolt; tin-plated copper lug 106.5 g (3.75 oz) Row-to-row grounding clip SS 301 with SS 304 M6 bolts 75 g (2.6 oz) Row-to-row grounding jumper Stainless steel 300 series 10 g (0.35 oz) Row-to-row spacer Black POM-grade plastic 5 g (0.18 oz) Roof Attachment BOM • InvisiMount Comp Shingle Attachment with Pegasus • InvisiMount Flat Tile Replacement Attachment with Pegasus • InvisiMount S-Tile Replacement Attachment with Pegasus • InvisiMount W-Tile Replacement Attachment with Pegasus InvisiMount Operating Conditions Temperature −40°C to 90°C (−40°F to 194°F) Roof Attachment Hardware Warranties Refer to roof attachment hardware manufacturer’s documentation. InvisiMount Warranties And Certifications Warranties • 25-year product warranty • 5-year finish warranty Certifications • UL 2703 Listed • Class A Fire Rated Professional Engineer (PE) must then stamp all calculations. If you have any questions please contact SunPower Technical Support at 1-855-977-7867. © 2022 SunPower Corporation. All Rights Reserved. SUNPOWER, the SUNPOWER logo, EQUINOX, and INVISIMOUNT are trademarks or registered trademarks of SunPower Corporation. All other trademarks are the property of their respective owners. Specifications included in this datasheet are subject to change without notice. InvisiMount Components Mid Clamp End Clamp Rail and Rail SpliceGround Lug Assembly sunpower.com 509506 RevG ¹ With Classic InvisiMount, a module frame that is compatible with the InvisiMount system is required for hardware interoperability; modules without this frame may be used with Universal InvisiMount. ² SunPower recommends that all Equinox™, InvisiMount™, and AC module systems always be designed using the InvisiMount Span Tables #524734. If a designer decides to instead use the component capacities listed in this document to design a system, note that the capacities shown are Load and Resistance Factor Design (LRFD) design loads, and are NOT to be used for Allowable Stress Design (ASD) calculations; and that a licensed InvisiMount Component LRFD Capacities² Classic Mid clamp Uplift 664 lbf Shear 540 lbf Universal Mid clamp Uplift 962 lb Shear 437 lb Classic End clamp Uplift 899 lbf Shear 220 lbf Universal End clamp Uplift 605 lb Shear 242 lb Rail Moment: upward 548 lbf-ft Moment: downward 580 lbf-ft Rail splice Moment: upward 548 lbf-ft Moment: downward 580 lbf-ft L-foot Uplift 1000 lbf Shear 390 lbf Datasheet Row-to-Row Spacer Row-to-Row Grounding Clip Universal End ClampRow-to-row Grounding Jumper (DynoBond) Universal Mid ClampRail and Rail SpliceGround Lug Assembly Universal InvisiMount Classic InvisiMount 1222 S Sycamore St - 201824905/3/2024 This Verification is for the exclusive use of Intertek's client and is provided pursuant to the agreement between Intertek and its Client. Intertek's responsibility and liability are limited to the terms and conditions of the agreement. Intertek assumes no liability to any party, other than to the Client in accordance with the agreement, for any loss, expense or damage occasioned by the use of this Verification. Only the Client is authorized to permit copying or distribution of this Verification. Any use of the Intertek name or one of its marks for the sale or advertisement of the tested material, product or service must first be approved in writing by Intertek. The observations and test/inspection results referenced in this Verification are relevant only to the sample tested/inspected. This Verification by itself does not imply that the material, product, or service is or has ever been under an Intertek certification program. Intertek Page 1 of 3 GFT-OP-11e (22-August-2019) Test Verification of Conformity Verification Number: 105370452-LAX-VOC1 Applicant Name & Address: Product Description: SunPower Corporation 1414 Harbour Way South Suite 1901 Richmond, CA 94804 USA Photovoltaic Racking System installed using the SunPower InvisiMount Installation Guide 508988 Rev O Ratings & Principle Characteristics: Fire Class Rating: Class A for Type 1 and Type 2 Fuse Rating: 20 A Mechanical Load Testing: Mechanical Load Rating: 10PSF Downward, 5PSF Upward, 5PSF Sloped Load Module Orientation: Portrait or Landscape Classic InvisiMount, Universal InvisiMount ; InvisiMount Models/Type References: Brand Name: Relevant Standards: Mounting Systems, Mounting Devices, Clamping/Retention Devices, and Ground Lugs for Use with Flat-Plate Photovoltaic Modules and Panels [UL 2703:2015 Ed.1+R:24Mar2021] Verification Issuing Office Name & Address: Date of Tests: Test Report Number(s): Intertek Testing Services NA, Inc. 25800 Commercentre Drive Lake Forest, CA 92630 USA September-27-2022 to October-11-2022 105208800LAX-001 Signature Name: Abdullah Alharbi Position: PV Engineer Date: 08 November 2023 On the basis of the tests undertaken, the samples of the below product have been found to comply with the requirements of the referenced specification/standard at the time the tests were carried out. This verification is part of the full test report 105208800LAX-001 and should be read in conjunction with it. This verification replaces previous verification number 105208800LAX-001-LAX-VOC1 dated: 30-12-2022. Additional information in Appendix. This Verification is for the exclusive use of Intertek's client and is provided pursuant to the agreement between Intertek and its Client. Intertek's responsibility and liability are limited to the terms and conditions of the agreement. Intertek assumes no liability to any party, other than to the Client in accordance with the agreement, for any loss, expense or damage occasioned by the use of this Verification. Only the Client is authorized to permit copying or distribution of this Verification. Any use of the Intertek name or one of its marks for the sale or advertisement of the tested material, product or service must first be approved in writing by Intertek. The observations and test/inspection results referenced in this Verification are relevant only to the sample tested/inspected. This Verification by itself does not imply that the material, product, or service is or has ever been under an Intertek certification program. Intertek Page 2 of 3 GFT-OP-11e (22-August-2019) APPENDIX: Test Verification of Conformity Approved Module list Module Manufacturer Model SunPower Corporation SPR-XYY-###-(COM), where X can be “E” or “A” denoting cell type, where YY represents numbers 18, 19, 20,21, or blanks and ### represents any number from 450 to 310 and 274 to 233; SPR-EYY-###, where YY represents numbers 18, 19, 20 or 21, and ### represents any number from 345 to 285 and 250 to 225. SPR-MXXX & SPR-MAX6-XXX, may be followed by -BLK, where XXX is 385-440. SPR-E or SPR-X followed by 18, 19, 20, 21, 22, followed by - XXX where XXX is 320-370, may be followed by -BLK, followed by C, D, E, may be followed by -AC SPR-XXXE/NE-WHT/BLK-U-YYYACPV and SPR-V-WW-XXX-Y-Z-G-AC, where "XXX" is the wattage of the panel and ranges from 250 to 225; and where "YYY" indicates the inverter voltage used in the module, and can be blank, 240 or 208/240. SPR-AXXX-G-AC or SPR-AXXXBLK-G-AC Where “XXX” denotes output power. “G” denotes inverters. “BLK” represents backsheet color. “AC” indicates AC module. SPR-AXXX-H-AC where “XXX” is the wattage range of 350 to 425, “H” Denotes the inverter, and “AC” indicates AC modules. SPR-MXXX-YYY-Z-AC, where XXX is 380-440 All models identified must have the Gen 5 frame and have a module fire performance: Type 2 SunPower Corporation 72-cell model with Gen 4.2 frame only: SPR-AXXX-COM or SPR-MAX5-XXX-COM, may be followed by BLK, where XXX is 380-460 66-cell model with Gen 4.2 frame only: SPR-AXXX, may be followed by -COM, and/or - 300V, followed by MLSD, where XXX is 350-425. 72-cell model with Gen 4.2 frame only: SPR-AXXX, may be followed by -COM, and/or - 300V, followed by MLSD, where XXX is 430-60 SPR-UXXX-BLK, where XXX is 395-415 Hanwha Q.PEAK DUO BLK ML-G10.a+ XXX, where XXX is 370-425 Q.PEAK DUO BLK-G10+ XXX, where XXX is 350–370 Q.PEAK DUO BLK ML-G10+ XXX, where XXX is 385-405 REC RECxxxNP2, may be followed by Black, where xxx is 350-380. RECxxxTP4, may be followed by Black, where xxx is 355-380. RECxxxAA Black, where xxx is 340-385. This is an Appendix to Test Verification of Conformity Number: 105370452-LAX-VOC1. 1222 S Sycamore St - 201824905/3/2024 This Verification is for the exclusive use of Intertek's client and is provided pursuant to the agreement between Intertek and its Client. Intertek's responsibility and liability are limited to the terms and conditions of the agreement. Intertek assumes no liability to any party, other than to the Client in accordance with the agreement, for any loss, expense or damage occasioned by the use of this Verification. Only the Client is authorized to permit copying or distribution of this Verification. Any use of the Intertek name or one of its marks for the sale or advertisement of the tested material, product or service must first be approved in writing by Intertek. The observations and test/inspection results referenced in this Verification are relevant only to the sample tested/inspected. This Verification by itself does not imply that the material, product, or service is or has ever been under an Intertek certification program. Intertek Page 3 of 3 GFT-OP-11e (22-August-2019) RECxxxAA PURE, where xxx is 380-415. RECxxxAA Pure-R, where xxx is 400–430. RECxxxAA Pure 2, where xxx is 400–430. RECxxxAA Pure-RX, where xxx is 450–470. Trina TSM-xxxDE06X.05(II), where xxx is 355-380 Canadian Solar CS3N-xxxMS, xxx is 375-435 Waaree WSMDi-XXX, XXX is 360-380, 395-415 WSMDiB-XXX, XXX is 360-380, 395-455 Jinko JKMxxxM-6RL3-B, where xxx is 365-400 Aptos Solar DNA-108-BF10-xxxW, xxx is 385-410. DNA-120-BF26-xxxW, where xxx is 350-370. DNA-120-MF26-xxxW, where xxx is 360-370 The Universal InvisiMount System was evaluated for fire rating with Type 1 and Type 2 modules. Signature Name: Abdullah Alharbi Position: PV Engineer Date: 08 November 2023 1222 S Sycamore St - 201824905/3/2024 Improve Support, Reduce Costs An intuitive monitoring website enables you to: • • • • See a visual map of customer sites Remotely manage hundreds of sites Remotely diagnose and troubleshoot system issues Drill down for the status of individual devices Add Value for Customers With mySunPower™ monitoring customers can: • • • • • Track their energy production by day, month, year and in different weather conditions See their energy use and estimated bill savings Maximize their savings with automatic system alerts and tips Customize storage settings and easily monitor and track available battery power Receive elective system reports SunPower® Monitoring — Plug-and-Play Installation This complete solution for residential monitoring and control includes the SunPower® PV Supervisor (PVS) which improves the installation process, overall system reliability, and customer experience: • • • • • • • • • Compact footprint for improved aesthetics Robust cloud connectivity and comprehensive local connectivity Flexible configuration of devices during installation Consumption metering Revenue-quality production metering Web-based commissioning Remote diagnostics of PVS and inverters Durable UL Type 3R enclosure helps reduce maintenance costs Easy integration with SunPower eBOS Robust Cloud Connectivity Multiple options to maintain optimal connectivity: • • • Hardwired Ethernet WiFi Cellular backup sunpower.com SunPower® Monitoring | Residential SunPower PV Supervisor Operating Conditions Temperature • −22°F to +140°F (−30°C to +60°C) Humidity (max.)• 95%, non-condensing Warranty and Certifications Warranty • 10-year Limited Warranty Certifications • UL, cUL, CE, UL 61010-1 and -2, FCC Part 15 (Class B) Mechanical Weight • 5.5 lb (2.5 kg) Dimensions • 11.8 × 8.0 × 4.2 in. (30.5 × 20.5 × 10.8 cm) Enclosure rating • UL 50E Type 3R Site Requirements Number of modules supported per PVS • 85 (SunPower AC modules) Internet access • High-speed internet access via accessible router or switch Power • 100–240 VAC (L–N), 50 or 60 Hz • 208 VAC (L–L in phase 3), 60 Hz Communication RS-485 • Supports string inverters, external meters, and other auxiliary devices Integrated metering • One channel of revenue-quality production metering • Two channels of consumption metering Ethernet • 1 LAN (or optional WAN) port PLC • Supports SunPower AC modules WiFi • 802.11b/g/n 2.4 GHz and 5 GHz Cellular • LTE Cat-M1/3G UMTS ZigBee • IEEE 802.15.4 MAC, 2.4 GHz ISM band Data storage • 60 days Upgrades • Automatic firmware upgrades Web and Mobile Device Support Customer site • mysunpower.com Partner site • monitor.sunpower.com Browsers • Firefox, Safari, and Chrome Mobile devices • iPhone®, iPad®, and Android™ Customer app 1 Create account online at mysunpower.com 2 On a mobile device, download the SunPower Monitoring app from Apple App Store or Google Play™ Store 3 Sign in using account email and password SunPower® AC ModulesPVSSunPower® Pro Fleet Management for Installers mySunPowerTM for Homeownes © 2020 SunPower Corporation. All Rights Reserved. SUNPOWER, the SUNPOWER logo and MYSUNPOWER are trademarks or registered trademarks of SunPower Corporation in the U.S. and other countries as well. All other logos and trademarks are the properties of their respective owners. 530536 Rev D 1222 S Sycamore St - 201824905/3/2024 Equinox Junction Boxes SunPower®Equinox™ Accessories SPECIFICATIONS Model RMJ v2 Comp Shingle Transition J-Box Kit Part Number 530167 530168 Max. Voltage Rating 600 V (AC or DC) Ambient Temp. Range −35°C to 75°C (−31°F to 167°F) Enclosure Material Flame-retardant, UV-resistant, high-impact resistant resin Attachment/Flashing Material 304 stainless steel Steel w/zinc-aluminum coating Cavity Dimensions 150 × 150 × 62 mm (5.91” × 5.91” × 2.13”) Enclosure Volume 1150 cc (70 in3) Attachment/Flashing Finish Black oxide Black powder coat Compatibility InvisiMount rail Comp shingle roofs Assembled Weight 0.78 kg (1.7 lb)1.27 kg (2.8 lb) Certifications & Ratings •Watertight, UL Type 4 •UL 94 5VA •UL 1741 •UL 2703 (with InvisiMount) •Watertight, UL Type 4 •UL 94 5VA •UL 1741 Additional Hardware Included •3/4″ cord grip •Lay-in lug •3/4″cord grip •#12 screws with EPDM washer Composition Shingle Roof Transition Junction Box Datasheet InvisiMount™ Rail-Mounted Junction Box (RMJ) v2 •70% larger than original InvisiMount J-box. •Integrated grounding to InvisiMount rail, replacing grounding lug assembly. •Snap-on attachment for fast and secure installation. •Enables transitioning conductors directly through the roof. •Integrated flashing for peace of mind. •Compatible with composition shingle roofs. COMPONENT DIMENSIONS J- Bo x E n c l o s u r e (us e d i n bo t h R M J a n d T r a n s i t i o n J- bo x ) Fl a s h i n g (u s e d o n l y w i t h T r a n s i t i o n J -Bo x ) Equinox Junction Boxes SunPower®Equinox™ Accessories Datasheet 539382 RevA 1222 S Sycamore St - 201824905/3/2024 1222 S Sycamore St - 201824905/3/2024 M08-0026-003 Q 08/08 Printed in Mexico IMPORTANT! PLEASE READ CAREFULLY AND SAVE. This user’s manual contains important information about your Heat Alarm’s operation. If you are installing this Heat Alarm for use by others, you must leave this manual—or a copy of it—with the end user. TABLE OF CONTENTS Basic Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Fire Safety Tips . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Before You Install This Heat Alarm ...............................1 How This Heat Alarm Works . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2 How To Install This Heat Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2-3 Locking Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 Weekly Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Regular Maintenance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 If You Suspect a Problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Understanding the Indicator Lights and Alarm Horn Patterns . . . . . . . . .5 If This Heat Alarm Sounds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 What To Do In Case Of Fire ..................................6 Using the Silence Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Latching Alarm Indicator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Recommended Locations For Heat Alarms . . . . . . . . . . . . . . . . . . . . . .6-7 Locations To Avoid For Heat Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 Special Compliance Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 Limitations of Heat Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Limited Warranty . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 ©2008 BRK Brands, Inc. All rights reserved. Distributed by BRK Brands, Inc. 3901 Liberty Street Road, Aurora, IL 60504-8122 Consumer Affairs: (800) 323-9005 www.brkelectronics.com • www.firstalert.com INTRODUCTION Thank you for choosing First Alert®for your Heat Alarm needs. You have purchased a state-of-the-art Heat Alarm designed to provide you with early warning of increased temperatures that may be the result a fire. Key features include: 135º F Fixed and 15º F/Minute Rate of Rise–Programmed to alarm when temperature reaches 135ºF or when the microprocessor senses a temperature rise of 15º F per minute. This allows the unit to sense a heat rise and alarm prior to reaching the fixed temperature of 135º F,providing a more rapid response to a potential fire. Exclusive IR* Remote Control Feature–Lets you Test or Silence the Heat Alarm using most commonly available remote controls. Latching Alarm Indicator–Microprocessor controlled feature automatically identifies and remembers which unit in an interconnected series initiated an alarm, even after the alarm condition has ended. Two Silence Features: 1. Temporarily silences the low battery chirp for up to 8 hours without removing the battery. 2. Temporarily silences an unwanted nuisance alarm for up to 15 minutes. Battery Compartment–swings out for quicker, easier battery installation even when unit is mounted. Interconnectable–Can be interconnected with BRK Smoke Alarms. *Infrared (IR) remote controls like those used for TV’s and VCRs. 1 USER’S MANUAL 120V AC/DC POWERED 135ºF FIXED AND 15ºF/MINUTE RATE-OF-RISE HEAT ALARM WITH BATTERY BACK-UP •This device is not intended to alert hearing impaired residents. Smoke Alarms specifically designed for the hearing impaired, which feature devices like flashing strobe lights, are available to alert the hearing impaired in case of fire. •Installation of this Heat Alarm must conform to the electrical codes in your area; Articles 210 and 300.3 (B) of the National Electrical Code (NFPA 70), NFPA 72, NFPA 101; SBC (SBCCI); NBC (BOCA); OTFDC (CABO), and any other local or building codes that may apply.Wiring and installation must be performed by a licensed electrician. Failure to follow these guidelines may result in injury or property damage. •This Heat Alarm is not a Smoke Alarm. This unit is not suitable protection when used alone. Do not use this unit as the only means of fire detection in a home. This unit is intended for use as a supplement to Smoke Alarms. •This Heat Alarm must have AC or battery power to operate. If the AC power fails, battery back-up will allow the alarm to operate for a limited time. If AC power fails and the battery is dead or missing, the alarm cannot operate. •This unit must be powered by a 24-hour, 120VAC 60Hz circuit. Be sure the circuit cannot be turned off by a switch, dimmer, or ground fault circuit interrupter. Failure to connect this unit to a 24-hour circuit and keeping fresh batteries installed, may prevent it from providing constant protection. •Never disconnect the power from an AC powered unit to stop an unwanted alarm. Doing so will disable the unit and remove your protection. In the case of a true unwanted alarm, use the Silence Feature by using an IR remote control or by pressing the Test/Silence button or fan the heat away from the unit. The alarm will reset automatically when it returns to normal operation. •NEVER ignore any alarm. Read “If Your Heat Alarm Sounds” for more information on how to respond to an alarm. Failure to respond can result in injury or death. •Test this Heat Alarm once a week. If it ever fails to test correctly, have it replaced immediately! If the Alarm is not working properly, it cannot alert you to a problem. •Connect this Heat Alarm ONLY to other compatible units. See “Special Requirements for Interconnected Heat Alarms” for details. Do not connect it to any other type of alarm or auxiliary device. Connecting anything else to this unit may damage it or prevent it from operating properly. •DO NOT stand too close to the unit when the alarm is sounding. It is loud to alert you in an emergency. Exposure to the horn at close range may harm your hearing. When testing the unit, step back when the horn starts sounding. •Do not paint over the Heat Alarm. Paint may clog the openings to the sensor and prevent the Heat Alarm from operating properly. 120V AC ~60 Hz 0.07Amps FIRE SAFETY TIPS Follow safety rules and prevent hazardous situations: 1) Use smoking materials properly. Never smoke in bed. 2) Keep matches or lighters away from children; 3) Store flammable materials in proper containers; 4) Keep electrical appliances in good condition and don’t overload electrical circuits; 5)Keep stoves, barbecue grills, fireplaces and chimneys grease- and debris- free; 6) Never leave anything cooking on the stove unattended; 7) Keep portable heaters and open flames, like candles, away from flammable materials; 8) Don’t let rubbish accumulate. Keep alarms clean, and test them weekly. Replace alarms immediately if they are not working properly. Heat and Smoke Alarms that do not work cannot alert you to a fire. Keep at least one working fire extinguisher on every floor, and an additional one in the kitchen. Have fire escape ladders or other reliable means of escape from an upper floor in case stairs are blocked. BEFORE YOU INSTALL THIS HEAT ALARM IMPORTANT! Read “Recommended Locations for Heat Alarms” and “Locations to Avoid for Heat Alarms” before beginning. This unit monitors the air, and when heat reaches its sensing chamber, it alarms. It can give you more time to escape before fire spreads. This unit can ONLY give an early warning of developing fires if it is installed, maintained and located where heat can reach it, and where all residents can hear it, as described in this manual. This unit will not sense gas, smoke, or flame. It cannot prevent or extinguish fires. Know Where To Install Your Heat Alarms See “Recommended Locations For Heat Alarms” and “Locations To Avoid For Heat Alarms” for details. Know What Heat Alarms Can and Can’t Do A Heat Alarm can help alert you to fire, giving you precious time to escape. It can only sound an alarm once heat reaches the sensor. See “Limitations of Heat Alarms” for details. Check Your Local Building Codes This Heat Alarm is designed to be used in a typical single-family home. It alone will not meet requirements for boarding houses, apartment buildings, hotels or motels. See “Special Compliance Considerations” for details. Model HD6135FB LISTED TO UL 539 STANDARD 1222 S Sycamore St - 201824905/3/2024 The Mounting Bracket: To remove the mounting bracket from the Heat Alarm base, hold the Heat Alarm base firmly and twist the mounting bracket counterclockwise. The mounting bracket installs onto the junction box. It has a variety of screw slots to fit most boxes. The Power Connector: The power connector plugs into a power input block on the Heat Alarm. It supplies the unit with AC power. •The black wire is “hot.” •The white wire is neutral. •The orange wire is used for interconnect. If you need to remove the power connector,disconnect AC power at the electrical panel; insert a flat screwdriver blade between the power connector and the security tab inside the power input block. Gently pry back the tab and pull the connector free. 1 2 3 2 9 8 7 3 5 6 4 The Parts of This Unit 1 Mounting Bracket 2 Mounting Slots and Screws 3 Locking Pins (break out of bracket) 4 Hot (Black) AC Wire 5 Neutral (White) AC Wire 6 Interconnect (Orange) Wire 7 Latch to Open Battery Compartment 8 Swing-Out Battery Compartment 9 Quick-Connect Power Connector HOW TO INSTALL THIS HEAT ALARM THE PARTS OF THIS HEAT ALARM This Heat Alarm is designed to be mounted on any standard wiring junction box to a 4-inch (10 cm) size, on either the ceiling or wall (if allowed by local codes). Read “Recommended Locations For Heat Alarms” and “Locations to Avoid For Heat Alarms” before you begin installation. Tools you will need: • Needle-nose pliers or utility knife •Standard Flathead screwdriver. Fixed Temperature and Rate-of-Rise. This Heat Alarm monitors the air and when heat reaches the sensor, it alarms. The unit will alarm either when the temperature reaches a fixed 135º F (57º C) or the microprocessor detects a 15º F (8.3º C) per minute rate of rise temperature change. This allows the unit to sense a heat rise and alarm prior to reaching the fixed temperature of 135º F (57º C), providing quicker response to a potential fire. Heat Alarms are intended for use as supplemental safety devices with Smoke Alarms. Heat Alarms are designed for use in areas where Smoke Alarms cannot be installed due to temperature and environmental conditions, as in unheated garages and crawl spaces. A Heat Alarm can only give early warn- ing of a developing fire if it is properly installed and maintained and located where heat can reach it. The unit will not sense gas, smoke or flame. Heat Alarms cannot prevent or extinguish fires. This Heat Alarm is approved for use in single-family residences. It is NOT designed for marine or RV use. THE COVER OF YOUR HEAT ALARM 1. Power Light, Test/Silence Button 2. Remote Control “Eye”: Aim an infrared remote control at the “Eye” on the Alarm to test or silence the unit. (Works with most infrared remote controls.) 3. Air Vents 4. (Behind the Cover) Alarm Horn: 85 dB audible alarm for test, alarm, and unit malfunction warning. 5.Heat Sensor 1 2 3 4 5 HOW THIS HEAT ALARM WORKS Make sure the Alarm is not receiving excessive noisy power. Examples of noisy power could be major appliances on the same circuit, power from a generator or solar power, light dimmer on the same circuit or mounted near fluorescent lighting. Excessive noisy power may cause damage to your Alarm. 2 1222 S Sycamore St - 201824905/3/2024 The basic installation of this Heat Alarm is the similar whether you want to install one Heat Alarm, or interconnect more than one Heat Alarm. If you are interconnecting more than one Heat Alarm, you MUST read “Special Requirements for Interconnected Heat Alarms” below before you begin installation. ELECTRICAL SHOCK HAZARD. Turn off power to the area where you will install this unit at the circuit breaker or fuse box before beginning installation. Failure to turn off the power before installation may result in serious electrical shock, injury or death. 1. Remove the mounting bracket from the base. Position the screw slots on the mounting bracket over the screws in the junction box. Tighten the screws. 2. Using wire nuts, connect the power connector to the household wiring. Improper wiring of the power connector or the wiring leading to the power connector will cause damage to the Alarm and may lead to a non-functioning Alarm. 3.Plug the power connector into the back of the Heat Alarm. 4.Position the base of the Alarm over the mounting bracket and turn. The Alarm can be positioned over the bracket every 60°. Turn the Alarm clockwise (right) until the unit is in place. 5. Check all connections. ELECTRICAL SHOCK HAZARD. Do not restore power until all Heat Alarms are completely installed. Restoring power before installation is complete may result in serious electrical shock, injury or death. 6. Make sure the Heat Alarm is receiving AC power. Under normal operation, the green light (LED) will shine continuously. 7. If the green power indicator light does not light, TURN OFF POWER TO THE JUNCTION BOX and recheck all connections. If all connections are correct and the power indicator still does not light when you restore the power, the unit should be replaced immediately. 8. Test each Heat Alarm. Press the Test/Silence button until you hear a brief acknowledge (or feedback) chirp. The alarm will sound: 3 beeps, pause, 3 beeps, pause. When testing a series of interconnected units you must test each unit individually. Make sure all units alarm when each one is tested. If any unit in the series does not alarm, TURN OFF POWER and recheck connections. If it does not alarm during testing when you restore power, replace it immediately. SPECIAL REQUIREMENTS FOR INTERCONNECTED HEAT ALARMS •Failure to meet any of these requirements could damage the units and cause them to malfunction, removing your protection. Interconnected units can provide earlier warning of fire than stand-alone units, especially if a fire starts in a remote area of the dwelling. If any unit in the series senses heat, all units will alarm. Interconnect units within a single family residence only. Otherwise all house- holds will experience unwanted alarms when you test any unit in the series. Interconnected units will only work if they are wired to compatible units and all requirements are met. This unit is designed to be compatible with: First Alert®Smoke Alarm Models SA4120, SA4121B, SA4919B, SA100B and BRK Electronics®Smoke Alarm Models 100S, 2002RAC, 4120, 4120B, 4120SB, 4919, 5919, 5919TH; BRK Electronics®Smoke/CO Alarm Model SC6120B. Interconnected units must meet ALL of the following requirements: •A maximum of 18 compatible Smoke, Heat or CO Alarms may be interconnected. To comply with NFPA limits, no more than 12 of the 18 alarms may be Smoke Alarms. •The same fuse or circuit breaker must power all interconnected units. •All wiring must conform to all local electrical codes and NFPA 70 (NEC). Refer to NFPA, Chapter 2 and/or your local building code for further connection requirements. FOLLOW THESE INSTALLATION STEPS STAND-ALONE ALARM ONLY: •Connect the white wire on the power connector to the neutral wire in the junction box. • Connect the black wire on the power connector to the hot wire in the junction box. •Tuck the orange wire inside the junction box. It is used for interconnect only. INTERCONNECTED UNITS ONLY: Strip off about 1/2” (12 mm) of the plastic coating on the orange wire on the power connector. • Connect the white wire on the power connector to the neutral wire in the junction box. •Connect the black wire on the power connector to the hot wire in the junction box. •Connect the orange wire on the power connector to the interconnect wire in the junction box. Repeat for each unit you are interconnecting. Never connect the hot or neutral wires in the junction box to the orange interconnect wire. Damage may result. • Never cross-connect hot and neutral wires between interconnected Alarms. Damage will result. STAND-ALONE ALARM ONLY: • If you are only installing one Heat Alarm, restore power to the junction box. INTERCONNECTED UNITS ONLY: • If you are interconnecting multiple Heat Alarms, repeat steps 1-5 for each Heat Alarm in the series. When you are finished, restore power to the junction box. 6 7 8 4 3 1 5 4 3 1 5 2 A B}} A. Unswitched 120VAC 60 Hz source B. To additional units; Maximum = 18 total (Maximum 12 Smoke Alarms) 1. Heat Alarm 2. Ceiling or Wall 3. Power Connector 4. Wire Nut 5. Junction Box 6. Neutral Wire (Wht) 7. Interconnect Wire(Orange) 8. Hot Wire (Blk) 3 1222 S Sycamore St - 201824905/3/2024 4 LOCKING FEATURES The locking features are designed to discourage unauthorized removal of the battery or alarm. It is not necessary to activate the locks in single-family households where unauthorized battery or alarm removal is not a concern. These Heat Alarms have two separate locking features: one to lock the battery compartment, and the other to lock the Heat Alarm to the mounting bracket. You can choose to use either feature independently, or use them both. Tools you will need:•Needle-nose pliers or utility knife • Standard Flathead screwdriver. Both locking features use locking pins, which are molded into the mounting bracket. Using needle nose pliers or a utility knife, remove one or both pins from the mounting bracket, depending on how many locking features you want to use. To permanently remove either lock insert a flathead screwdriver between the locking pin and the lock, and pry the pin out of the lock. Locking Pin TO LOCK THE BATTERY COMPARTMENT Do not lock the battery compartment until you have activated the battery and tested the battery back-up. 1. Activate the battery back-up by removing the “Pull to Activate Battery Back-Up” tab. DO NOT remove the battery activation until AC power is turned on to conserve battery power. 2. Press the Test/Silence button until you hear a brief acknowledge (or feedback) chirp. The alarm will sound: 3 beeps, pause, 3 beeps, pause. If the unit does not alarm during testing, DO NOT lock the battery compartment! Install a new battery and test again. If the Heat Alarm still does not alarm, replace it immediately. 3. Using needle-nose pliers or a utility knife, detach one locking pin from the mounting bracket. 4. Push the locking pin through the black dot on the label on the back of the Heat Alarm. TO UNLOCK THE BATTERY COMPARTMENT Once the Heat Alarm is installed, you must disconnect it from the AC power before unlocking the battery compartment. ELECTRICAL SHOCK HAZARD. Turn off the power to the area where the Heat Alarm is installed before removing it from the mounting bracket. Failure to turn off the power first may result in serious electrical shock, injury or death. Turn off the AC power at the circuit breaker or fuse box. 1. Remove the Heat Alarm from the mounting bracket. If the unit is locked to the bracket, see the section “To Unlock the Mounting Bracket.” 2. Disconnect the power connector by gently prying it away from the back of the Heat Alarm. 3. Insert a flathead screwdriver under the head of the locking pin, and gently pry it out of the battery compartment lock. (If you plan to relock the battery compartment, save the locking pin.) 4. To relock the battery compartment, close the battery door and reinsert locking pin in lock. 5.Reconnect the power connector to the back of the Alarm, reattach the Heat Alarm to the mounting bracket, and restore the power. When replacing the battery, always test the Heat Alarm before relocking the battery compartment. TO UNLOCK THE MOUNTING BRACKET ELECTRICAL SHOCK HAZARD. Turn off the power to the area where the Heat Alarm is installed before removing it from the mounting bracket. Failure to turn off the power first may result in serious electrical shock, injury or death. Always discharge the branch circuit before servicing an AC or AC/DC Heat Alarm. First, turn off the AC power at the circuit breaker or fuse box. Next, remove the battery from Alarms with battery back-up. Finally, press the test button to discharge the branch circuit. 1. Insert a flathead screwdriver between the mounting bracket pin and the mounting bracket. 2. Pry the Heat Alarm away from the bracket by turning both the screw- driver and the Heat Alarm counterclockwise (left) at the same time. TO LOCK THE MOUNTING BRACKET 1. Using needle-nose pliers, detach one locking pin from mounting bracket. 2. Insert the locking pin into the lock located on the pivoting hinge of the battery door. 3. When you attach the Alarm to the mounting bracket, the locking pin’s head will fit into a notch on the bracket. 1222 S Sycamore St - 201824905/3/2024 WEEKLY TESTING • NEVER use an open flame of any kind to test this unit. You might accidentally damage or set fire to the unit or to your home. The built- in test switch accurately tests the unit’s operation as required by Underwriters Laboratories, Inc. (UL). •If the Alarm ever fails to test properly, replace it immediately. Products under warranty may be returned to the manufacturer for replacement. See “Limited Warranty” at the end of this manual. •DO NOT stand close to the Alarm when the horn is sounding. Exposure at close range may be harmful to your hearing. When testing, step away when horn starts sounding. It is important to test this unit every week to make sure it is working properly.Press and hold the test button until the alarm sends a test command acknowledge “chirp” just before it sounds continuously (the unit will continue to alarm for a few seconds after you release the button). If it does not alarm, make sure it is receiving power and has a fresh battery, and test it again. If it still does not alarm, it should be replaced immediately. When testing one unit, all interconnected alarms will sound. If they don’t, check the connection with power to the units turned off, restore power and try again. Test all units in a series, not just one. Using the test button is the ONLY correct way to test the Heat Alarm. USING THE REMOTE CONTROL WEEKLY TEST/SILENCE FEATURE Using the VOLUME or CHANNEL buttons on most remote controls, you can test or silence this Alarm from up to 12 feet (3.7 meters) away. To Test (or Silence) the Alarm: 1.Make sure you have a clear path between you and the alarm, free of any obstructions. 2. Point the remote at the front of the Alarm. 3.Press the VOLUME or CHANNEL button for at least 2 seconds. You will hear a brief acknowledge “chirp” when the Alarm receives the test (or silence) command. If the Alarm does not respond to your remote control: •You may be standing too far away. •Your remote may not be compatible. •You did not hold the button on your remote for at least 2 seconds. REGULAR MAINTENANCE This unit has been designed to be as maintenance-free as possible, but there are a few simple things you must do to keep it working properly. Use only the replacement batteries listed below.The unit may not operate properly with other batteries. Never use rechargeable batteries since they may not provide a constant charge. • Test it at least once a week. • Clean the Heat Alarm at least once a month; gently vacuum the outside of the Heat Alarm using your household vacuum’s soft brush attachment. Test the Heat Alarm. Never use water, cleaners or solvents since they may damage the unit. • If the Heat Alarm becomes contaminated by excessive dirt, dust and/or grime, and cannot be cleaned to avoid unwanted alarms, replace the unit immediately. • Relocate the unit if it sounds frequent unwanted alarms. See “Locations to Avoid for Heat Alarms” for details. • When the battery becomes weak, the Heat Alarm unit will “chirp” about once a minute (the low battery warning). You should replace the battery immediately to continue your protection. Choosing a replacement battery: Your Heat Alarm’s battery back-up requires one standard 9V battery. The following batteries are acceptable as replacements. This list supplements the list on the Heat Alarm battery door: Eveready #522 (Energizer); Duracell #MN1604, MX1604 (Ultra). You may also use a Lithium battery like the Ultralife U9VL-J for longer service life between battery changes. These batteries are available at many local retail stores. Actual service life depends on the Heat Alarm and the environment in which it is installed. Constant exposures to high or low temperatures or high humidity may reduce battery life. All the batteries specified above are acceptable replacement batteries for this unit. Use of a different battery may have a detrimental effect on Alarm operation. Regardless of the manufacturer’s suggested battery life, you MUST replace the battery immediately once the unit starts “chirping” (the “low battery warning”). IF YOU SUSPECT A PROBLEM Heat Alarms may not operate properly because of dead, missing or weak batteries, a build-up of dirt, dust or grease on the Heat Alarm cover, or installation in an improper location. Clean the Heat Alarm as described in “Regular Maintenance,” and install a fresh battery, then test the Heat Alarm again. If it fails to test properly when you use the test button, or if the problem persists, replace the Heat Alarm immediately. • If you hear a “chirp” once a minute, replace the battery. • If you experience frequent non-emergency alarms try relocating the Heat Alarm. •If the alarm sounds when no smoke is visible, try cleaning or relocating the Heat Alarm. The cover may be dirty. •If the alarm does not sound during testing, make sure it is receiving AC power from the household current. Always discharge the branch circuit before servicing an AC or AC/DC Heat Alarm. First, turn off the AC power at the circuit breaker or fuse box. Next, remove the battery from Heat Alarms with battery back-up. Finally, press the test button to discharge the branch circuit. If the Heat Alarm is still not operating properly, and it is still under warranty, please see “How to Obtain Warranty Service” in the Limited Warranty. Do not try fixing the alarm yourself – this will void your warranty! 5 MALFUNCTION (Unit MUST be replaced) LED flashes RED rapidly three times, in sync with three horn “chirps”, once every minute Horn “chirps” three times, in sync with three LED flashes ALARM CONDITION* (Initiating Unit) LED flashes RED, the same pattern as the horn Audible alarm: 3 beeps, pause, repeating horn pattern AC POWER ON (Normal operation) LED shines GREEN continuously Silent; no audible alarm RESUME AC POWER GREEN LED turns ON Horn “chirps” one time to signal resumption of AC power Condition LED Horn LATCHING ALARM ACTIVE**(Under AC or DC Power) LED flashes RED once every 5 seconds Silent; no audible alarm ALARM SILENCE LED flashes RED once every 5 seconds No signal LOW BATTERY GREEN LED flashes once every minute Horn “chirps” once per minute, in sync with LED. NOTE: If the battery is VERY LOW, the horn may either chirp once per second, or sound continuously DC POWER (Battery back-up active) LED flashes GREEN once per minute while battery powers unit One horn “chirp” to signal loss of AC power DURING TESTING (Under AC or DC power) LED flashes RED, the same pattern as the horn Audible alarm: 3 beeps, pause, repeating horn pattern UNDERSTANDING THE INDICATOR LIGHTS AND ALARM HORN PATTERNS *When any Heat Alarm in an interconnected series triggers an alarm, its red LED will flash rapidly.The red LEDs will not flash on any remaining alarms in the series. This feature helps responders identify which unit(s) triggered the alarm. **The Latching Alarm indicator is activated after an Alarm is exposed to alarm levels of heat. After heat levels drop below alarm levels, the LED begins to flash RED once every 5 seconds. See “The Latching Alarm Indicator” for details. 1222 S Sycamore St - 201824905/3/2024 6 IF THIS HEAT ALARM SOUNDS RESPONDING TO AN ALARM During an alarm, you will hear a loud, repeating horn pattern: 3 beeps, pause, 3 beeps, pause. •If the unit alarms and you are not testing the unit, it is warning you of a potentially dangerous situation that requires your immediate attention. NEVER ignore any alarm. Ignoring the alarm may result in injury or death. •Never disconnect the AC power or remove the battery back-up to quiet an unwanted alarm. Disconnecting the power disables the alarm so it cannot sense heat. This will remove your protection. •If the unit alarms and you are not absolutely certain of the source of the heat, get everyone out of the house immediately. •ELECTRICAL SHOCK HAZARD: Attempting to disconnect the power connector from the unit when the power is on may result in electrical shock, serious injury or death. When an interconnected system of units is in alarm, the Red LED on the unit(s) that initiated the alarm will flash in sync with the horn. The LED will not flash on any remaining units. WHAT TO DO IN CASE OF FIRE •Don’t panic; stay calm. Follow your family escape plan. •Get out of the house as quickly as possible. Don’t stop to get dressed or collect anything. •Feel doors with the back of your hand before opening them. If a door is cool, open it slowly. Don’t open a hot door. Keep doors and windows closed, unless you must escape through them. •Cover your nose and mouth with a cloth (preferably damp). Take short, shallow breaths. • Meet at your planned meeting place outside your home, and do a head count to make sure everybody got out safely. •Call the Fire Department as soon as possible from outside. Give your address, then your name. • Never go back inside a burning building for any reason. •Contact your Fire Department for ideas on making your home safer. USING THE SILENCE FEATURES If you are absolutely certain the alarm is caused by a non-emergency, non-fire situation, you may use the Silence Feature to silence the Alarm. The Silence Feature on this unit can temporarily quiet an unwanted alarm for up to 15 minutes. The Silence Feature is for your convenience only and will not correct a problem. The Silence Feature is intended to temporarily silence the Alarm horn. It will not extinguish a fire. To temporarily silence the alarm: 1.Option 1:Press the Test/Silence button on the cover of the Heat Alarm that initiated the alarm.* 2.Option 2:Point a universal IR remote control at the Heat Alarm that initiated the alarm* and press the channel or volume button until the alarm is silent. (See “Using the Remote Control Weekly Test/Silence Feature” for details). An acknowledge tone will be issued by the Alarm to let you know that the silence command has been received. *To silence Heat Alarms in an interconnected series: To silence multiple Alarms in an interconnected series, you must press the Test/Silence button on the unit(s) that triggered the alarm. Pressing the Test/ Silence button on a unit that did not trigger the alarm will only silence that Alarm. NOTE:The red light under the Silence button on the initiating alarm will flash in sync with the horn. The red light will be off on all other Heat Alarms. If any unit will not silence and no heat is present install a new battery and re-test it. If it still will not silence, the unit should be replaced immediately. LOW BATTERY SILENCE FEATURE If AC power is on, briefly press the Test/Silence button or use a Remote Control to silence the low battery “chirp” for up to 8 hours. A brief “chirp” will let you know that the Alarm has accepted the Low Battery Silence command. The Alarm will continue to operate as long as AC power is supplied. However, replace the battery as soon as possible, to maintain protection in event of a power outage. “LATCHING ALARM” INDICATOR GARAGE BEDROOMBEDROOM HALLLIVING ROOM KITCHEN BASEMENT BEDROOM LATCHING ALARM: Unit was exposed to alarm levels of Smoke or Heat LATCHING NOT ACTIVATED: Unit was not exposed to alarm levels of Smoke or Heat KEY: The Latching Alarm Indicator is activated after an Alarm is exposed to alarm levels of heat. After heat levels drop below alarm levels, the red LED will begin to flash once every 5 seconds. It will continue to flash or “latch” until you clear it using the Test/Silence button. Press and hold the Test/Silence button until the horn sounds. This feature helps emergency responders, investigators, or service technicians identify which unit(s) in your home were exposed to alarm levels of heat. This can help investigators pinpoint the initiating alarm. RECOMMENDED LOCATIONS FOR HEAT ALARMS In Single-Family Residences. For minimum coverage, BRK Brands, Inc. recommends you install Heat Alarms in any area not suitable for smoke alarms such as garages, kitchens, utility/laundry rooms, furnace rooms and crawl spaces. Install where tempera- tures normally remain between –10º F and 100º F (–23º C and 38º C). For National Fire Protection Association (NFPA) information, see “Agency Placement Recommendations for Heat Alarms and Smoke Alarms.” RECOMMENDED PLACEMENT Heat Alarms Recommended in New Home Construction •The recommended location for a Heat Alarm is at the center of the ceil- ing. At this location, the Heat Alarm is closest to all areas of the room. •If it is not practical to install the Heat Alarm in the center of the room, use an off-center location not less than 4 inches (102 mm) from the sidewall. •If it is not practical to install the Heat Alarm on the ceiling, the next logical location is on a sidewall. A Heat Alarm mounted on a sidewall should have the top of the unit between 4 and 12 inches (102 mm and 305 mm) from the ceiling. •The smooth ceiling distance between Heat Alarms shall not exceed spacings as determined by UL fire tests. This Heat Alarm has a 50 foot (15 meter) spacing. •Reduced spacing may be required due to factors such as exposed joists, drafts, ceiling heights greater than 10 feet (3 meters), and other structural characteristics that may affect Heat Alarm operation. Walls, partitions, doorways, and joists interrupt the normal flow of heat creating new areas to be protected. Continued... GARAGE BEDROOMBEDROOM HALLLIVING ROOM KITCHEN BASEMENT BEDROOM INTERCONNECTED HEAT ALARMS IN GARAGES, KITCHENS, UTILITY/LAUNDRY ROOMS, FURNACE ROOMS AND CRAWL SPACES AND ONLY AS A SUPPLEMENT TO SMOKE ALARMS. FOR MAXIMUM PROTECTION USE INTERCONNECTED SMOKE ALARMS WITH BATTERY BACK-UP AS SHOWN. 25 ft. (7.8 m) 25 ft. (7.8 m) 25 ft. (7.8 m) 50 ft. (15 m) 25 ft. (7.8 m) 12.5 ft. (3.8 m) 12.5 ft. (3.8 m) Heat Alarms should be mounted on the bottom of the joists and not up in the joist channels. 1222 S Sycamore St - 201824905/3/2024 AGENCY PLACEMENT RECOMMENDATIONS FOR HEAT AND SMOKE ALARMS NFPA Appendix A-2-5.2.2: While Chapter 2 does not require heat detectors as part of the basic protection scheme, it is recommended that the householder consider the use of additional heat detectors...The additional areas lending themselves to protection with heat detectors are: kitchen, dining room, attic (finished or unfinished), furnace room, utility room, basement and integral or attached garages. For bedrooms, the installation of a smoke detector is preferable to the installation of a heat detector. The following recommendations reference location and usage of Smoke Alarms. Heat Alarms are intended as supplemental safety devices. Do not rely solely on Heat Alarms to alert you to fire. NFPA 72 (National Fire Code) Smoke Alarms shall be installed in each separate sleeping room, outside each sleeping area in the immediate vicinity of the bedrooms and on each additional story of the family living unit, including basements and excluding crawl spaces and unfinished attics. In new construction, Alarms shall be so arranged that operation of any one Alarm shall cause the operation of all Alarms within the dwelling. Smoke Detection-Are More Smoke Alarms Desirable? The required number of Smoke Alarms might not provide reliable early warning protection for those areas separated by a door from the areas protected by the required Smoke Alarms. For this reason, it is recommended that the householder consider the use of additional Smoke Alarms for those areas for increased protection. The additional areas include the basement, bedrooms, dining room, furnace room, utility room, and hallways not protected by the required Smoke Alarms. The installation of Smoke Alarms in kitchens, attics (finished or unfinished), or garages is not normally recommended, as these locations occasionally experience conditions that can result in improper operation. California State Fire Marshal (CSFM) Early warning detection is best achieved by the installation of fire detection equipment in all rooms and areas of the household as follows: A Smoke Alarm installed in each separate sleeping area (in the vicinity,but outside bedrooms), and Heat or Smoke Alarms in the living rooms, dining rooms, bedrooms, kitchens, hallways, finished attics, furnace rooms, closets, utility and storage rooms, basements, and attached garages. Additional local building and regulatory codes may apply in your area. Always check compliance requirements before beginning any installation. Specific requirements for Heat or Smoke Alarm installation vary from state to state and from region to region. Check with your local Fire Department for current requirements in your area. If you install AC or AC/DC units, it is recom- mended they be interconnected for added protection. Interconnect Smoke and Heat Alarms for added protection. RECOMMENDED PLACEMENT, Continued NFPA Standard 72 Appendix A-2-5.2.2.2 part c-d (c) The Spacing of Detectors: Where a room is too large for protection by a single detector, several detectors should be used. It is important that they be properly located so all parts of the room are covered. (d) Where the Distance Between Detectors Should Be Further Reduced: The distance between detectors is based on data obtained from the spread of heat across a smooth ceiling. Where the ceiling is not smooth, the placement of the detector should be tailored to the situation. For instance, with open wood joists, heat travels freely down the joist channels so that the maximum distance between detectors [50 ft (15 m)] may be permitted to be used. However, heat has trouble spreading across the joists, so the distance in this direction should be 1/2 the distance allowed between detectors, as shown in the illustration above (“Heat Alarms Recommended in New Home Construction”) and the distance to the wall is reduced to 12-1/2 ft. (3.8 m). Since 1/2 x 50 ft. (15 m) is 25 ft. (7.6 m), the distance between detectors across open wood joists should not exceed 25 ft. (7.6 m), as shown in “Heat Alarms Recommended in New Home Construction,” and the distance to the wall is reduced [1/2 x 25 ft. (7.6 m)] to 12.5 ft. (3.8 m). Paragraph 2-5.2.2.4 requires that detectors be mounted on the bottom of the joists and not up in joist channels. Walls, partitions, doorways, ceiling beams, and open joists interrupt the normal flow of heat, thus creating new areas to be protected. LOCATIONS TO AVOID FOR HEAT ALARMS This unit works best when it’s clean and nothing interferes with the sensor. If exposed to dirt, grease, extreme temperatures not caused by fire (especially in attics where daily temperatures can exceed the 135º F (57º C) alarm level or high humidity, it may sound “unwanted” alarms. If Heat Alarms are installed where heat can’t reach them–like in “dead air spaces” or near fans–they may not be able to provide an early enough warning in case of fire. For best performance, do not install the Heat Alarm: In a location where it could be easily triggered when using your remote to operate your TV, VCR, or other remote controlled appliances. • Where temperatures are regularly below –20º F (–29º C) or above 115º F (46º C), including unheated buildings, outdoor rooms, or porches. •Do not install a Heat Alarm directly over the stove or range. Clean a laundry room unit frequently to keep it free of dirt or lint. •Near fresh air vents, ceiling fans, or in very drafty areas. Drafts can blow heat away from the unit, preventing it from reaching the sensing chamber. • In “dead air” spaces. Install units according to “Avoiding Dead Air Spaces”. • Less than 12 inches (305 mm) away from fluorescent lights. Electrical “noise” can interfere with the sensor. SPECIAL COMPLIANCE CONSIDERATIONS The following recommendations reference location and usage of Smoke Alarms. Heat Alarms are only intended as supplemental safety devices. Do not rely solely on Heat Alarms to alert you to fire. This unit alone is not a suitable substitute for complete fire detection systems in places housing many people—like apartment buildings, condominiums, hotels, motels, dormitories, hospitals, long-term health care facilities, nursing homes, day care facilities, or group homes of any kind—even if they were once single-family homes. It is not a suitable substitute for complete fire detection systems in warehouses, industrial facilities, commercial buildings, and special-purpose non-residential buildings which require special fire detection and alarm systems. Depending on the building codes in your area, this unit may be used to provide additional protection in these facilities. For your reference: The following is information on Smoke Alarm usage in various residences and institutions. The following information applies to all five types of buildings listed below: In new construction, most building codes require the use of AC or AC/DC powered Smoke Alarms only.AC, AC/DC, or DC powered Smoke Alarms can be used in existing construction as specified by local building codes. Refer to NFPA 72 (National Fire Alarm Code) and NFPA 101 (Life Safety Code), local building codes, or consult your Fire Department for detailed fire protection requirements in buildings not defined as “households.” 1. Single-Family Residence: Single family home, townhouse. It is recommended Smoke Alarms be installed on every level of the home, in every bedroom, and in each bedroom hallway. 2. Multi-Family or Mixed Occupant Residence: Apartment building, condominium. This Smoke Alarm is suitable for use in individual apartments or condos, provided a primary fire detection system already exists to meet fire detection requirements in common areas like lobbies, hallways, or porches. Using this Smoke Alarm in common areas may not provide sufficient warning to all residents or meet local fire protection ordinances/regulations. 3. Institutions: Hospitals, day care facilities, long-term health care facilities. This Smoke Alarm is suitable for use in individual patient sleeping/resident rooms, provided a primary fire detection system already exists to meet fire detection requirements in common areas like lobbies, hallways, or porches. Using this Smoke Alarm in common areas may not provide sufficient warning to all residents or meet local fire protection ordinances/regulations. 4. Hotels and Motels: Also boarding houses and dormitories. This Smoke Alarm is suitable for use inside individual sleeping/resident rooms, provided a primary fire detection system already exists to meet fire detection requirements in common areas like lobbies, hallways, or porches. Using this Smoke Alarm in common areas may not provide sufficient warning to all residents or meet local fire protection ordinances/regulations. 5. Warehouses/Commercial Buildings: DO NOT use this Alarm in warehouses, industrial or commercial buildings, special-purpose non-residential buildings, RVs, boats, or airplanes. This Alarm is specifically designed for residential use, and may not provide adequate protection in non-residential applications. AVOIDING DEAD AIR SPACES “Dead air” spaces may prevent heat from reaching the Heat Alarm. To avoid dead air spaces, follow installation instructions in the “Recommended Locations for Heat Alarms” (refer to NFPA72 for details). For wall mounting (if allowed by building codes), the top edge of Heat Alarms should be placed between 4 inches (102 mm) and 12 inches (305 mm) from the wall/ceiling line, below typical “dead air” spaces. 7 1222 S Sycamore St - 201824905/3/2024 LIMITATIONS OF HEAT ALARMS This Heat Alarm is not a Smoke Alarm. This unit is not suitable protection when used alone. Do not use this unit as the only means of fire detection in a home. This unit is intended for use as a supplement to Smoke Alarms. Heat Alarms are not life safety devices. Heat Alarms are intended for use as supplements to Smoke Alarms. Because this unit cannot detect smoke, carbon monoxide or other toxic gases, do not rely solely on this Heat Alarm in a fire emergency. Slow developing fires may produce smoke and toxic gasses without a significant increase in room temperatures. For this reason, Heat Alarms are only to be installed as supplementary protection with Smoke Alarms. Heat Alarms cannot work without power.AC powered Heat Alarms and Smoke Alarms cannot work if the AC power is cut off for any reason (open fuse or circuit breaker, failure along a power line or at a power station, electrical fire that burns the electrical wires, etc.). AC units with battery (DC) back-up: will operate if electricity fails, provided the batteries are fresh and correctly installed. AC and AC/DC units must be installed by a qualified electrician. Heat Alarms for Solar or Wind Energy users and battery backup power systems:AC powered Heat Alarms should only be operated with true or pure sine wave inverters. Operating this Heat Alarm with most battery-powered UPS (uninterruptible power supply) products or square wave or “quasi sine wave” inverters will damage the Alarm.If you are not sure about your inverter or UPS type, please consult with the manufacturer to verify. Heat Alarms cannot sense fires if the heat does not reach them.Heat from fires in chimneys or walls, on roofs, or on the other side of closed doors may not reach the sensing chamber and set off the alarm. That is why one unit should be installed on every floor, in the attic, basement and garage and only as a supplement to Smoke Alarms. Heat Alarms may not sense heat from a fire on another level of the home. Example: a stand-alone unit on the second floor may not detect heat from a fire in a crawl space until the fire spreads. This may not give you enough time to escape safely. That is why recommended minimum protection is at least one Smoke Alarm on every level of your home and Heat Alarms in any areas not suitable for Smoke Alarms. Even with a unit on every floor, stand-alone units may not provide as much protection as interconnected units, especially if the fire starts in a remote area. Interconnected units may provide earlier warning than stand-alone units since all units alarm when one senses heat or smoke. Heat Alarms may not be heard. The alarm horn loudness meets or exceeds the current UL standard. However, if the device is installed outside the bed- room, it may not wake up a sound sleeper or one who has recently used drugs or has been drinking alcoholic beverages. This is especially true if the door is closed or only partly open. Even persons who are awake may not hear the alarm horn if the sound is blocked by distance or closed doors. Noise from traffic, stereo, radio, television, air conditioner, or other appliances may also prevent alert persons from hearing the alarm horn. This alarm device is not intended for people who are hearing impaired. Heat Alarms may not have time to alarm before the fire itself causes damage, injury, or death, since heat from some fires may not reach the unit immediately. Examples of this include persons smoking in bed, children playing with matches, or fires caused by violent explosions resulting from escaping gas. This Heat Alarm is not foolproof.Like any electronic device, Heat Alarms are made of components that can wear out or fail at any time. You must test the unit weekly to ensure your continued protection. Heat Alarms cannot prevent or extinguish fires. They are not a substitute for property or life insurance. Heat Alarms have a limited life.The unit should be replaced immediately if it is not operating properly. In no case should it be used for more than 10 years. 8 Printed in Mexico M08-0026-003 Q 08/08 BRK®is a registered trademark of BRK Brands, Inc. First Alert®is a registered trademark of the First Alert Trust. LIMITED WARRANTY BRK Brands, Inc., ("BRK") the maker of BRK®brand and First Alert®brand products warrants that for a period of ten years from the date of purchase, this product will be free from defects in material and workmanship. BRK, at its option, will repair or replace this product or any component of the product found to be defective during the warranty period. Replacement will be made with a new or remanufactured product or component. If the product is no longer available, replacement may be made with a similar product of equal or greater value. This is your exclusive warranty. This warranty is valid for the original retail purchaser from the date of initial retail purchase and is not transferable. Keep the original sales receipt. Proof of purchase is required to obtain warranty performance. BRK dealers, service centers, or retail stores selling BRK products do not have the right to alter, modify or any way change the terms and conditions of this warranty. This warranty does not cover normal wear of parts or damage resulting from any of the following: negligent use or misuse of the product, use on improper voltage or current, use contrary to the operating instructions, disassembly,repair or alteration by anyone other than BRK or an authorized service center.Further, the warranty does not cover Acts of God, such as fire, flood, hurricanes and tornadoes or any batteries that are included with this unit. BRK shall not be liable for any incidental or consequential damages caused by the breach of any express or implied warranty. Except to the extent prohibited by applicable law,any implied warranty of merchantability or fitness for a particular purpose is limited in duration to the duration of the above warranty.Some states, provinces or jurisdictions do not allow the exclusion or limitation of incidental or consequential damages or limitations on how long an implied warranty lasts, so the above limitations or exclusion may not apply to you. This warranty gives you specific legal rights, and you may also have other rights that vary from state to state or province to province. How to Obtain Warranty Service Service:If service is required, do not return the product to your retailer. In order to obtain warranty service, contact the Consumer Affairs Division at 1-800-323-9005, 7:30 AM - 5:00 PM Central Standard Time, Monday through Friday. To assist us in serving you, please have the model number and date of purchase available when calling. For Warranty Service return to:BRK Brands, Inc., 25 Spur Drive, El Paso, TX 79906 Battery:BRK Brands, Inc. make no warranty, express or implied, written or oral, including that of merchantability or fitness for any particular purpose with respect to battery. Please record Date and Where Purchased: ________________________________________________________________ 1222 S Sycamore St - 201824905/3/2024 1222 S Sycamore St - 201824905/3/2024 October 25, 2023 Sunpower Corporation 77 Rio Robles San Jose, CA 95134 Attn.: To whom it may concern, Subject: Job 17-041869 PH25 : InvisiMount Solar PV Module Mounting System – 3 rd Party Attachment Compatibility PZSE, Inc.-Structural Engineers has evaluated the SunPower InvisiMount Solar PV Mounting System and Unirac Flashloc Comp and Flashloc Duo roof attachments and certifies that these roof attachments are compatible with the InvisiMount Solar PV Mounting System. This assumes that the connections and associated hardware are installed per the manufacturer’s installation specifications (except as noted below). All information, data, and analysis contained within are based on, and comply with, the following building codes and typical specifications: Building Codes: 1. Minimum Design Loads for Buildings and other Structures, ASCE 7-10 & ASCE 7-16 2. 2012, 2015, & 2018 International Building Code, by International Code Council, Inc. 3. 2010 & 2015 Aluminum Design Manual, by The Aluminum Association 4. CPP Wind Tunnel report number 9790, dated 16 February 2017. 5. SEAOC PV-2, 2017 6. 2012, 2015 & 2018 NDS, National Design Specification for Wood Construction, by the American Wood Council 7. UL 2703 Testing report for PV solar panels. 8. AC428, Acceptance Criteria for Modular Framing Systems Used to Support Photovoltaic (PV) Panels, November 1, 2012 by ICC-ES Attachment Compatibility: 1. The Unirac Flashloc Comp and Flashloc Duo attachments are confirmed to be compatible with the InvisiMount system. 2. The InvisiMount rail attaches to the vertical of the approved roof attachment. The aforementioned attachments must be installed with the following: M10 hex bolt. (or) the 3/8”- 16 T-Bolt supplied with Unirac Flashloc. 1222 S Sycamore St - 201824905/3/2024 Notes: 1. This certification excludes checks for the attachment to building and the building structure to support the loads imposed by the array, such as bending strength of roof rafters spanning between supports. This requires additional knowledge of the building and is outside the scope of this review. If you have any questions on the above, do not hesitate to call. Prepared By: PZSE, Inc. - Structural Engineers Roseville, CA EXP. 11/30/2024 PAUL K. ZACHER 081.007690 DIGITALLY SIGNED 1222 S Sycamore St - 201824905/3/2024