Heat Transfer and Entropy Generation in a Lithium-ion Battery Pack Against Battery Spacing and Discharge Rate

Three-dimensional continuity, momentum and energy equations have been solved in a battery pack of a unit module with 3×3×3 and 4×4×4 Li-ion cells to obtain the flow field and temperature distribution around the batteries. The battery spacings in ×, y and z directions (S×, Sy and Sz) have been varied in a wide range to obtain the optimum configuration for the maximum heat transfer and minimum entropy generation. Air is pumped through the battery pack with Reynolds number (Re) varying in the laminar range from 400 to 2000. The results are plotted in terms of average surface Nu over the battery surface and average volumetric temperature of the battery and air. It is found that the temperature of the battery pack remains almost constant against Sx. However, a significant rise in battery temperature is observed when we increase Sy. The scenario becomes different when spacing is varied in the z-direction. An optimum spacing for the minimum temperature of the battery pack is obtained at Sz/Dh = 0.03. In each case, the maximum temperature is seen on the batteries present at the top and bottom corners of the outlet. Among all the cases, the maximum temperature of 355 K has been found in 4×4×4 cells with a 3.6 C discharge rate at Sy/Dh of 0.07133. It is numerically and theoretically proved that Nu and the non-dimensional volumetric average temperature inside the pack are independent of the heat generation rate inside the battery pack.