The invention provides a thermal runaway suppressant of lithium batteries and the related applications. The thermal runaway suppressant includes a passivation composition supplier, for releasing a metal ion (A), selected from a non-lithium alkali metal ion, an alkaline earth metal ion or a combination thereof, and an amphoteric metal ion (B), a polar solution supplier and an isolating mechanism, which is capable of separating the passivation composition supplier and the polar solution supplier within a predetermined temperature. When the isolating mechanism is failed and the polar solution supplier releases a polar solution to carry the metal ion (A) and the amphoteric metal ion (B) into the lithium battery and react with the positive active material and the negative active material to a state with lower energy. The voltage of the whole battery is decreased and the electrochemical reaction pathway is blocked to prevent the thermal runaway from occurring.

A battery module comprising at least one battery cell (2), wherein the battery module (1) further comprises a propagation protection element (3) which is connected in a thermally conductive manner to the battery cell (2) and which is designed in such a way that, when a specific value for a temperature of the at least one battery cell (2) is exceeded, an endothermic process which is being executed within the propagation protection element (3) absorbs heat which is given off by the at least one battery cell (2).

A battery module comprising at least one battery cell (2), wherein the battery module (1) further comprises a propagation protection element (3) which is connected in a thermally conductive manner to the battery cell (2) and which is designed in such a way that, when a specific value for a temperature of the at least one battery cell (2) is exceeded, an endothermic process which is being executed within the propagation protection element (3) absorbs heat which is given off by the at least one battery cell (2).

An emergency rapid cooling system configured to provide rapid cooling to an electric vehicle battery pack during a thermal event. The emergency rapid cooling system including at least one capsule filled with a fluid, the at least one capsule including at least one nozzle positioned in proximity to at least one battery cell, wherein the at least one nozzle is configured to open upon reaching at least one of a determined temperature or pressure, thereby enabling the fluid within the at least one capsule to rapidly decrease in pressure and accompanying temperature to provide cooling to the at least one battery cell.

An emergency rapid cooling system configured to provide rapid cooling to an electric vehicle battery pack during a thermal event. The emergency rapid cooling system including at least one capsule filled with a fluid, the at least one capsule including at least one nozzle positioned in proximity to at least one battery cell, wherein the at least one nozzle is configured to open upon reaching at least one of a determined temperature or pressure, thereby enabling the fluid within the at least one capsule to rapidly decrease in pressure and accompanying temperature to provide cooling to the at least one battery cell.

An aqueous battery system includes an electrode assembly, a recombination device, and a controller. The recombination device has a catalyst that combines hydrogen and oxygen produced by the electrode assembly to form water and generate heat via exothermic reaction. The controller, responsive to a detected temperature or change in temperature associated with the recombination device due to the heat, changes power supplied to the electrode assembly.

An aqueous battery system includes an electrode assembly, a recombination device, and a controller. The recombination device has a catalyst that combines hydrogen and oxygen produced by the electrode assembly to form water and generate heat via exothermic reaction. The controller, responsive to a detected temperature or change in temperature associated with the recombination device due to the heat, changes power supplied to the electrode assembly.

A temperature sensitive coating for application on a surface is provided. The temperature sensitive coating comprises an indicator component. The indicator component includes a carrier and a releasable compound that is held by the carrier. The releasable compound is in a gas state at a critical release temperature, and is released from the carrier at a temperature that is at or above the critical release temperature. A method of coating a surface of an energy storage system, and a method of detecting the approach of thermal runaway of an energy storage system, are also provided. The method includes coating a surface with the temperature sensitive coating, providing a gas sensor in the vicinity of the surface that is capable of detecting the presence of the releasable compound, monitoring the output of the sensor, and signaling an alarm when the sensor output indicates the presence of the releasable compound.

A temperature sensitive coating for application on a surface is provided. The temperature sensitive coating comprises an indicator component. The indicator component includes a carrier and a releasable compound that is held by the carrier. The releasable compound is in a gas state at a critical release temperature, and is released from the carrier at a temperature that is at or above the critical release temperature. A method of coating a surface of an energy storage system, and a method of detecting the approach of thermal runaway of an energy storage system, are also provided. The method includes coating a surface with the temperature sensitive coating, providing a gas sensor in the vicinity of the surface that is capable of detecting the presence of the releasable compound, monitoring the output of the sensor, and signaling an alarm when the sensor output indicates the presence of the releasable compound.

A battery module includes a cell stack having a plurality of battery cells; and a phase change preheater disposed on the cell stack. The phase change preheater contains a phase change material that causes a phase change as crystal nuclei are formed, and accordingly causes an exothermic reaction.