In this study, thermal runaway propagation characteristics and measures to prevent this phenomenon were analyzed byapplying abnormal thermal conditions to pouch-type lithium-ion batteries. Experiments were conducted in a 1.5 m × 1.5m × 1.5 m experimental chamber. During the experiment, pouch-type lithium-ion batteries were grouped according tocapacity, quantity, and the use of fire extinguishing agents. Experiments showed that when thermal runaway occurred ina cell, it propagated to the adjacent cell after a certain period. The surface temperature of the cell where thermal runawayfirst occurred was above 200 ℃, and thermal runaway propagated via heat transfer to the adjacent cell. In the case ofthermal runaway, when a fire extinguishing agent was applied, the propagation of thermal runaway to adjacent cells wasprevented due to a cooling effect. However, at a cell capacity of 100 Ah, flame generation persisted and thermal runawaywas unavoidable. To prevent thermal runaway propagation, it is necessary to select an extinguishing agent that exerts acooling effect. The capacity and structure of the model unit should be considered when installing fire extinguishing systems.