LiftMaster CSL24VDC CSL24VDC Installation Manual - Page 44
Step 6 Solar Panel(s), Solar Usage Guide
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APPENDIX STEP 6 SOLAR PANEL(S) NOT PROVIDED. SEE ACCESSORIES. Solar Application requirements: • A minimum of two 10W solar panels in series (Model SOLPNL10W12V). • A maximum of six 10W solar panels (Model SOLPNL10W12V). • Solar Battery Harness (Model K94-37236). • Two 33AH batteries, the standard 7AH batteries cannot be used. • A heater cannot be used with a solar application. Disconnect the expansion board if it is not in use to improve performance. We recommend LiftMaster low power draw accessories to minimize power draw, refer to accessory page. Use the tables below to see performance trade-offs. NOTE: Input solar power is 24 Vdc at 60 watts maximum. The solar panel(s) must be located in an open area clear of obstructions and shading for the entire day. The gate operator is not supported in northern climates where temperatures reach below -4˚F. This is due to cold weather and a reduced number of hours of sunlight during the winter months. Cycle rate may vary from solar chart for areas that reach below 32˚F. Solar panels should be cleaned on a regular basis for best performance to ensure proper operation. SOLAR USAGE GUIDE The CSL24VDC has best in class solar performance due to highly efficient electronics that draw very little power while the gate is not in use (standby). Typical System Standby Battery Current Consumption (mA) 2.7 mA +1 mA +2.4 mA +11.1 mA +3.8 mA System Configuration Main control board draw with no remote controls programmed Low band radio receiver active (one or more wireless transmitters learned) High band radio active (MyQ device programmed) Expansion board Per loop detector (up to 3 loop detectors can be plugged into the expansion board) This low current draw drastically increases the number of days the operator can remain in standby. To determine your system's performance, reference the above table and determine how many milliamps (mA) your system will draw from the batteries. EXAMPLE 1: A system with only a main control board and one or more hand held remote controls programmed will draw 3.7 mA from the batteries while the system is in standby (2.7 mA + 1 mA = 3.7 mA). EXAMPLE 2: A system with only a main control board, one or more hand held remote controls programmed, and 20 mA of external accessories connected to the main control board's accessory power output will draw 23.7 mA from the batteries while the system is in standby (2.7 mA + 1 mA + 20 mA = 23.7 mA). EXAMPLE 3: A system with a main control board, expansion board, two loop detectors, and one or more hand held remote controls programmed will draw 18 mA from the batteries while the system is in standby (2.7 mA + 11.1 mA + 3.8 mA * 2 +1 = 18.6 mA). Operator performance with no sun or loss of AC power BATTERY CURRENT DRAW (mA) SYSTEM CONFIGURATION DAYS OF STANDBY 7AH batteries 33AH batteries 2.7 main control board only 133 180 3.7 remote controls programmed 6.1 remote controls and MyQ programmed 14.8 remote controls and expansion board 97 180 59 180 24 105 18.6 remote controls, expansion board, and one loop detector 19 84 26.2 remote controls, expansion board, and three loop detectors 14 60 30 12 52 40 9 39 60 6 26 100 4 16 200 2 8 300 1 5 500 1 3 All numbers are estimates. Actual results may vary. 42 GATE CYCLES ON BATTERY 7AH batteries 33AH batteries 208 1179 208 1179 208 1179 208 1179 208 1178 207 1178 207 1178 207 1177 207 1177 206 1175 204 1171 201 1167 197 1159