Lithium-ion batteries (LiBs) are extensively used in electric vehicles (EVs) because of their high energy density and long service life. Designing a battery thermal management system (BTMS) that prevents thermal runaway (TR) propagation in the event of abusive accidents is crucial. The goal of this study is to design a novel hybrid BTMS with both active liquid cooling (LC) and passive cooling for preventing TR propagation in the battery module. A numerical model for a battery module (16 cylindrical 18 650 cells) was developed in COMSOL multiphysics software to examine the TR propagation caused by a single cell. Copper foam and expanded graphite-paraffin (EG-PCM) composite material were used for passive cooling. In addition to the TR scenario, the thermal behaviors of the battery module with the hybrid BTMS were evaluated under the 3C discharging and driving cycle circumstances. A conventional BTMS with natural air cooling is chosen as the baseline. The findings reveal that the proposed hybrid BTMS, which uses EG-PCM with a melting temperature of 52 °C and thermal diffusivity of 9.68 mm2/s and copper foam with a porosity of 0.7–0.9, is capable of limiting the maximum cell temperature below the thermal safety threshold (80 °C) to prevent TR propagation. Under the New European Driving Cycle (NEDC) load cycle, the battery module can be maintained within an optimal working temperature range by passive cooling only. By applying active LC with a flow rate of 0.3 m/s for BTMS, the average temperature reduction of the battery module at a 3C discharging rate can be up to 72.5% and 52.7% compared to passive cooling with copper foam and EG-PCM, respectively. The study highlights that the combination of active LC and appropriate passive cooling is an efficient thermal management solution for Li-ion battery applications in EVs, notably in the consideration of thermal safety.