The design goals of this circuit were efficiency, simplicity, reliability and the use of field replaceable parts. A medium power solar system can be built with the SCC3, a 12V (nominal) solar panel that is rated from 100 milliamps to 20 amps, and a lead acid or other rechargeable battery that is rated from 500 milliamp hours to 400 amp hours of capacity.
It is important to match the solar panel's current rating to the battery's amp-hour rating (C). A typical maximum battery charging current is C/20, so a 100 amp hour battery should have a solar panel rating of no greater than 5 amps. It is advisable to check the battery manufacturer's data sheets to find the maximum charge current. On the other hand, if the solar panel output current is too low, the battery may take too long to charge.
With a few parts changes, it is possible to modify this circuit to work as a 24V/15A solar charge controller. The 24V parts differences are shown on the schematic.
Maximum solar charging current: 20 Amps Nominal battery voltage: 12V. Night time battery current drain: 1.3ma
See the full SCC3 kit specifications for a more detailed list.
The float voltage comparator IC1a compares the battery voltage (divided by R1/VR1 and R3) to a reference voltage (divided by R5 and R6). The comparison point is offset by the thermistor TM1 for temperature compensation. The comparison point is also modified by the Equalize switch, S1 and R2. The output of IC1a goes high (+5V) when the battery voltage is below the float voltage setting. The output goes low when the battery voltage is above the float voltage setting. This provides the charge/idle signal that controls the rest of the circuit.
The charge/idle signal is sent to IC2a and b, a pair of D-type flip-flops. The flip-flops are clocked by the IC1b phase-shift clock oscillator. The clocking causes the flip-flop output to produce a square wave charge/idle signal that is synchronized with the frequency of the clock oscillator. The two halves of IC2 operate in synchronization, IC2a is used to drive the current switching circuitry, IC2b is used to drive the charging state indicator LED either red (charging) or green (floating).
The clocked charge/idle signal switches bipolar transistor Q1 on and off. The Q1 signal is used to switch power MOSFET Q2, which switches the solar current on and off through the battery. The solar charging current flows through the heavy lines on the schematic. Diode D1 prevents the battery from discharging through the solar panel at night. Fuse F1 prevents excessive battery current from flowing in the event of a short circuit. Transzorb TZ1 absorbs transient voltage spikes that may be caused by lightning.
[]CAUTION: Large batteries can produce dangerous currents that can cause burns and fire hazards. Remove loose metal jewelry when working with lead acid batteries. The circuit should be mounted on a panel or in a box using threaded standoffs. Wiring should be securely clamped and there should be no externally exposed bare wiring. []Connect the board's BAT - terminal to the battery - terminal. []Connect the board's BAT + terminal to the battery + terminal. []Connect the board's PV - terminal to the solar panel - terminal. []Connect the board's PV + terminal to the solar panel + terminal. []Point the solar panel toward the sun. []The bicolor LED should light up as the sun shines on the solar panel. The LED can be red, green, or alternating red and green. The LED must be shaded from direct sunlight to be visible. []Measure the connected solar panel's voltage with the meter. []Measure the battery voltage with the meter. The solar panel must be at a higher voltage than the battery for the circuit to charge the battery. []Turn the equalize switch off (closest to the board edge). []Turn the potentiometer, VR1 25 turns clockwise, The LED should be red. []Turn VR1 counter clockwise until the LED starts blinking red and green. The battery voltage is now at the float voltage setting. []While measuring the battery voltage, adjust VR1 clockwise to align the float voltage set point. If the LED turns red before it reaches the desired float voltage, the battery will need to charge for a while. []When the battery is fully charged, it should be at the float voltage and the led should show alternating colors. []The float voltage should be set when the board and battery are at room temperature. Typical 12V set points are 13.8V for a gell cell and 14.5V for a wet cell. Follow your battery manufacturer's recommendations for the optimal float voltage setting. []Adjust the float voltage again, after the battery has become fully charged and the LED is green with occasional red flashes.
Put the solar panel in the sun, the battery will charge up. In systems where the battery is frequently deep-discharged, the equalize switch should be occasionally turned on for a period of several hours to a full day.
When the battery is low and the sun is shining, the LED will be red. As the battery reaches the float voltage, the LED will alternate red/green. When the sun goes down, the LED will shut off.
The above circuit may be used if you wish to charge a remote secondary battery. The #1156 lamp limits the secondary battery's charge current to a maximum of 2 amps, it also protects the remote wiring from high currents in the event of a short circuit. The wiring should be rated to handle more than 2 amps of current, #16 or #14 gauge wire is recommended. Other lamps may be used for setting different maximum charge current values. The Schottky diode prevents a load on the main battery from discharging the secondary battery. The diode has a .5V drop, so the secondary battery will always stay .5V below the main battery's maximum (float) voltage setting. A wet cell lead acid main battery and a gell cell secondary battery will work well in this configuration. Float voltages for gell cell batteries are lower than for wet cell batteries.
For 12V systems, the dump load circuit should be adjusted so that it activates at a PV voltage of around 15V. The dump load resistor should be connected across the terminals labeled "Dump" in the schematic. For the optimal dump load power transfer, the value of the dump load resistor should be chosen so that it pulls the PV voltage down to the PV panel's rated maximum power point during full sun conditions. The dump load resistor should have a power rating that is greater than the PV panel's maximum output wattage rating. If a dump load other than a resistor is used, the load should be able to run with short pulses of DC energy. Dump load power is only available when the main battery becomes fully charged.
buying the kit saves you a lot of trouble locating parts and wiring the circuit.
