Rechargeable high-efficiency lithium-ion battery (LIB) has major characteristics of high energy density and long charge-cycle life. It is widely used in daily life or industrial applications, such as 3C electronic products, home appliances, electric vehicles, etc. However, it may cause some safety concerns due to module defects, punctures, short circuits, and other abnormal electrochemical reactions for a LIB. Furthermore, it may also cause operational fire or explosive risks for large-scale energy storage systems (ESS). The A123 lithium iron phosphate (LiFePO_4, LFP) and the Panasonic lithium nickel cobalt manganese oxide (LiNi_xCo_yMn_(1-x-y)O_2, NCM) cells were selected as experimental samples. Use a modified adiabatic calorimeter with an adjustable DC power supply to test their thermal runaway data caused by the overheating mode that NCN LIB has a runaway reaction at 166℃, but LFP LIB did not cause a runaway reaction. Then, evaluate the thermophysical parameters in an adiabatic surrounding that can calculate a LIB's enthalpy and energy release mode. Furthermore, a dry gas flow meter measures the amount of gas production after LIB thermal runaway that can provide battery heat release hazard and relief safety design.