A main cause of fires and explosions in lithium-ion batteries is the generation of combustible gases by them, and whena large number of batteries are densely packed, like in an Energy Storage System, there is a high risk of thermal runawayand fire propagation. Currently, many studies are being conducted worldwide to predict and prevent the generation ofcombustible gases, and thermal runaway in lithium-ion batteries, but they are still in progress. Therefore, in this study, weanalyzed the gases generated before and after thermal runaway in lithium ion batteries, to prepare a basis for reducing therisk of thermal runaway. We aimed to establish the basis for prevention by early detection in the event of thermal runaway,by understanding the type and characteristics of the generated gases. For the experiment, lithium ion batteries were classifiedin terms of appearance (cylindrical, prismatic, pouch type), and cathode materials (NCM, NCA, LFP). The gases generatedwas measured against time. An FT-IR analyzer was used for gas measurement, and a separate hydrogen sensor was installedin the chamber to analyze changes in the types of gas, and measure the mass of the lithium ion battery over time. In theexperiment, CO2 and CO were generated the most during thermal runaway in all lithium-ion batteries. Thereafter, CO2increased, and CO decreased in the prismatic and pouch types, and both CO2 and CO increased in the cylindrical type. HF(a toxic gas), and H2 having a wide explosive range, were also generated, and the concentrations of these gases were inverselyproportional to each other.