Cypress CY8C24794, AN2309 Cell-Balancing Foundation, Qcell 1 Qcell, Ccell 1 Vcell 1 Ccell 2 Vcell

Cell-Balancing Foundation

This section describes the fundamentals of cell-balancing techniques. Cells are considered balanced when:

The value QcellN is the charge of cell N. The equation for the charge is:

Therefore, Equation 1 can be transformed into the following equation:

The value VcellN is the electrochemical potential of the fully charged cell. The VcellN potential is fixed for a given set of

electrodes is fixed and does not change from cell to cell. When two cells are unbalanced, the following is true:

Equation 6 shows two cells that have different capacities, which is one cause of cell imbalance. A difference in cell- charge levels, which can be identified by using Equation 4, is the second cause of cell imbalance. For both kinds of mismatches in the battery pack – different cell capacities and difference cell charge levels – the highest voltage cell shows relative charge redundancy and must be shunted during the charging/discharging process. This is the heart of the cell-balancing issue.

The main reasons for variation in cell capacity are:

Variations in cell assembly. Today’s factory manufacturing of cells produces Li-Ion battery backs with cell capacity matched to three percent.

Different rates in cell degradation. The self-degradation rate is 30 percent at 500 cycles, which equals 0.06 percent per cycle. But individual cells degrade differently depending on temperature, charge voltage, and the particular self- degradation process. For example, a cell with a lower capacity is exposed to a higher charge voltage, which degrades it faster, further reducing its capacity and increasing the pack imbalance.