The battery rack includes a plurality of battery packs vertically arranged, each battery pack including a plurality of secondary batteries stacked in a direction, and a pack housing having an internal space to receive the plurality of secondary batteries and configured to be supplied with a fire extinguishing liquid when an internal temperature equals or rises above a predetermined temperature, and a rack case having a receiving space to receive the plurality of battery packs, and including a plurality of rack plates, each having a mounting surface on which the battery pack is mounted, the mounting surface sloping at a predetermined angle with declining height as it goes in any one direction, and an extension portion having an end of any one direction extending further outward than the lower battery pack.

An actuator assembly for use in fire suppression systems for use in vehicle and industrial fire protection systems. The actuator assembly engages a cartridge of pressurized gas and releases the gas contained therein with a puncturing assembly. The actuator assembly includes a receptacle that controls the manner in which the actuator assembly and cartridge engage one another. The actuator assembly is configured for electrical and pneumatic actuation for rupturing the seal of the cartridge of pressurized gas. The actuator assembly has a housing that includes at least one inlet port that is coupled to a pressurized gas source, which is formed between a first chamber for electrical components sealed from the operative environment of the actuator assembly and a second chambers for the puncturing assembly. The actuator assembly allows for serial interconnection of multiple actuator assemblies for operation by a as single source of pressurized gas.

An actuator assembly for use in fire suppression systems for use in vehicle and industrial fire protection systems. The actuator assembly engages a cartridge of pressurized gas and releases the gas contained therein with a puncturing assembly. The actuator assembly includes a receptacle that controls the manner in which the actuator assembly and cartridge engage one another. The actuator assembly is configured for electrical and pneumatic actuation for rupturing the seal of the cartridge of pressurized gas. The actuator assembly has a housing that includes at least one inlet port that is coupled to a pressurized gas source, which is formed between a first chamber for electrical components sealed from the operative environment of the actuator assembly and a second chambers for the puncturing assembly. The actuator assembly allows for serial interconnection of multiple actuator assemblies for operation by a as single source of pressurized gas.

The present invention generally provides systems and methods for autonomous space characterization, data analysis, anomaly detection, hazard probability assessment, and profile deviance assessment and incident response action, and firefighting employing robotically controlled firefighting equipment, autonomous selection and release of firefighting agent, and the autonomous prediction, detection, classification, and location of existing and impending threats and fire events.

The present invention generally provides systems and methods for autonomous space characterization, data analysis, anomaly detection, hazard probability assessment, and profile deviance assessment and incident response action, and firefighting employing robotically controlled firefighting equipment, autonomous selection and release of firefighting agent, and the autonomous prediction, detection, classification, and location of existing and impending threats and fire events.

The present invention generally provides systems and methods for autonomous space characterization, data analysis, anomaly detection, hazard probability assessment, and profile deviance assessment and incident response action, and firefighting employing robotically controlled firefighting equipment, autonomous selection and release of firefighting agent, and the autonomous prediction, detection, classification, and location of existing and impending threats and fire events.

The present invention generally provides systems and methods for autonomous space characterization, data analysis, anomaly detection, hazard probability assessment, and profile deviance assessment and incident response action, and firefighting employing robotically controlled firefighting equipment, autonomous selection and release of firefighting agent, and the autonomous prediction, detection, classification, and location of existing and impending threats and fire events.

An energy storage system according to one or more embodiments of the present disclosure includes: a container; a plurality of accommodation portions in the container and configured to accommodate a battery rack or an air conditioner; a partition wall between each pair of adjacent accommodation portions; a ventilation hole passing through the partition wall and connecting with the adjacent accommodation portions; and a blocking member configured to selectively open or close the ventilation hole.

An energy storage system according to one or more embodiments of the present disclosure includes: a container; a plurality of accommodation portions in the container and configured to accommodate a battery rack or an air conditioner; a partition wall between each pair of adjacent accommodation portions; a ventilation hole passing through the partition wall and connecting with the adjacent accommodation portions; and a blocking member configured to selectively open or close the ventilation hole.

The present invention generally provides systems and methods for autonomous space characterization, data analysis, anomaly detection, hazard probability assessment, and profile deviance assessment and incident response action, and firefighting employing robotically controlled firefighting equipment, autonomous selection and release of firefighting agent, and the autonomous prediction, detection, classification, and location of existing and impending threats and fire events.