Monitoring Battery Parameters
Monitoring critical battery parameters is one of the key functions of a BMS. It continuously monitors cell voltages, current, and temperature. Cell voltages are monitored to prevent overcharging or over-discharging individual cells. Overcharging and over-discharging can permanently damage battery cells and affect battery performance and lifespan. Current is monitored to calculate state of charge and estimate remaining battery capacity. Temperature is also closely monitored since most battery chemistries can be damaged if they get too hot or too cold.
Controlling Charging and Discharging
Based on parameter monitoring, the BMS controls charging and discharging of the battery. It ensures the battery is only charged within its maximum and minimum voltage levels. Similarly, it only allows discharging between cut-off voltage limits to prevent over-discharging. The BMS may reduce battery current or stop charging/discharging altogether if critical electrical or thermal limits are reached to protect the battery. Some BMS can communicate charging status to external chargers.
Balancing Battery Cells
Individual lithium-ion or lithium-polymer cells within a large battery module can have small variations in capacity or internal resistance. During charging, cells with less capacity will reach their maximum voltage before others. Similarly, during discharging, those cells will reach minimum voltage cutoff first. This can cause overcharging of some cells and over discharging of others if not managed properly. A Battery Management System balances cells by transferring charge from higher to lower cells through switching circuits. This helps to keep all cells at an equal voltage level for maximum efficient use of the battery.
Calculating Secondary Data
In addition to directly controlling and protecting the battery, a BMS also calculates and provides important secondary data. This includes state of charge (SOC), state of health (SOH), remaining capacity, current and power values. SOC indicates the percentage of charge remaining versus maximum capacity and is important for the user. SOH indicates battery degradation over time from wear and tear. These parameters help estimate remaining battery life and plan for replacement.
Ensuring Communication
Modern sophisticated battery management system can communicate critical battery data via a CAN bus or other protocol to external devices. This includes passing details like voltage, current, SOC, faults/errors and more. The communication allows integration with electric vehicles, energy storage units, consumer electronics and other systems using the battery. External devices like battery chargers, vehicle control modules or apps can then derive more value from this battery data. Communication also allows remote battery monitoring.
Battery Safety Functions
In addition to monitoring and control, BMS provide important battery safety functions. This includes short circuit, overcurrent and temperature protection. The BMS disconnects the battery in case of a critical short circuit to prevent fire or explosion risks. It also cuts power if current draw exceeds safe discharge limits of the battery. Temperature sensing and control prevents heat related issues. Isolation circuits electrically separate battery sections for additional safety during failures.
Types of BMS and Main Components
There are different types of BMS depending on battery chemistry, capacity, and end application. Some main types are lithium-ion, lithium iron phosphate, and lead-acid BMS. Key BMS components include a microcontroller unit, voltage sense/current sense circuits, temperature sensors, balancing/switching circuits, communication interfaces and safety circuits. The microcontroller runs BMS algorithms and controls other units. Sensing accurately monitors parameters. Switches balance cells. Interfaces link to external devices.
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