- Review Battery Specifications: Ensure you have the lead-acid battery's specifications, such as maximum charging current and voltage, to understand the limits for fast charging.
- Modify the Charging Algorithm: Adjust your simulation to increase the charging current within safe limits during the bulk phase of charging. This can be done by setting a higher current setpoint in the constant current (CC) phase until the battery reaches a certain voltage threshold.
- Implement Temperature Monitoring: Fast charging can lead to increased battery temperature. Incorporate temperature effects into your simulation, possibly using a thermal model of the battery, to prevent overheating.
- Adjust to Constant Voltage (CV) Phase Sooner: To protect the battery, switch from the CC phase to the CV phase at an earlier point before reaching the maximum voltage threshold. This helps in managing the battery's temperature rise during fast charging.
- Simulation of PV Array and Buck Converter: Ensure the PV array model and synchronous buck converter can handle the increased power demand for fast charging. You might need to adjust the PV array's maximum power point tracking (MPPT) algorithm and the converter's duty cycle to efficiently supply the higher current.
- For information on Simulink's battery models and how to parameterize them, refer to the documentation of Simscape Electrical: https://www.mathworks.com/help/physmod/sps/powersys/ref/battery.html.
- To understand how to model thermal effects in batteries, see the Simscape documentation for thermal modeling: https://www.mathworks.com/discovery/battery-thermal-management-system.html
- For guidelines on implementing MPPT algorithms for PV arrays in Simulink, visit: https://www.mathworks.com/discovery/mppt-algorithm.html
- To learn more about designing and simulating buck converters in Simulink, refer to: https://www.mathworks.com/help/physmod/sps/examples/synchronous-buck-converter.html.