Efficiency falls off rapidly when the input voltage from the solar panel falls below 6.5 V
| Authors | Ramesh Khanna, Frank Edrada |
| Main Document | Article «Solar panel powers two-stage lead-acid battery charger» |
| Description | Figure 11 |
| File Format / Size | PDF / 10 Kb |
| Document Language | English |
Other Materials from the Main Document
- Article «Solar panel powers two-stage lead-acid battery charger»
- Figure 1. A solar cell's current output decreases with a reduction in sunlight
- Figure 2. A solar cell's output voltage decreases with an increase in temperature
- Figure 3. The solar charger system uses an 18-cell, 3 W solar panel as the input source. The system comprises two stages, in which the first stage monitors the solar panel's voltages using a SEPIC topology and provides the output voltage, which tracks the input of
- Figure 4. A SEPIC is a dc/dc topology that allows the output voltage to be greater than, less than, or equal to the input voltage
- Figure 5. Replacing the inductor L2 of Figure 4 yields an isolated SEPIC
- Figure 6. The design incorporates an external soft-start circuit to extend the soft-start time and ensure that the solar panel does not become overloaded during turn-on
- Figure 7. Changing the value of RB adjusts the SEPIC voltage's setpoint to accommodate different solar panels' voltages. You can adjust a resistor divider comprising RT and RB to match the SEPIC's reference voltage, typically 1.34 V
- Figure 8. The second stage comprises a SEPIC that operates in boost mode with constant current-charge control and charges the 12 V battery
- Figure 9. The RBR/RTR divider that connects to the LM4041 in the first stage senses the solar panel's output voltage, which initiates a restart mode by disabling the second stage of the circuit by pulling down on the enable pin of LM5001
- Figure 10. The normal operating temperature for the charger is 60 °C
- Figure 11. Efficiency falls off rapidly when the input voltage from the solar panel falls below 6.5 V
