A battery module has a structure capable of preventing spread of flames when fire breaks out in the battery module, and more particularly a battery module including a plurality of battery cell module assemblies, each of the battery cell module assemblies including battery cells arranged in tight contact with each other, a side plate electrically connected to electrode leads of the battery cell module assemblies, a duct disposed outside the side plate, and a gas cutoff structure disposed in the duct, wherein the plurality of battery cell module assemblies is disposed so as to have a space therebetween.

A battery module has a structure capable of preventing spread of flames when fire breaks out in the battery module, and more particularly a battery module including a plurality of battery cell module assemblies, each of the battery cell module assemblies including battery cells arranged in tight contact with each other, a side plate electrically connected to electrode leads of the battery cell module assemblies, a duct disposed outside the side plate, and a gas cutoff structure disposed in the duct, wherein the plurality of battery cell module assemblies is disposed so as to have a space therebetween.

An energy storage container ventilation system and an energy storage container are provided according to the present disclosure. The ventilation system includes an air conditioner, an air duct, and multiple columns of battery racks, and each battery rack includes multiple lines of battery boxes, and an air outlet of the air conditioner is communicated with the air duct, a communicating part of each battery box and the air duct is provided with a ventilation plate with the same structure or different structures. The energy storage container ventilation system of the present disclosure uses an air conditioner to dissipate heat. Ventilation plates are provided at communicating parts of the air duct and each battery box. The structure of each ventilation plate is the same or different, so as to control an air intake volume flowing into each battery box.

A battery module with air cooling capability that includes at least two battery blocks; the battery blocks each include a plurality of cylindrical round cells arranged in corresponding receptacles of a cell holder, wherein longitudinal axes of the cylindrical round cells lie parallel to one another; air passage openings are provided in the cell holders, through which air can flow through the battery blocks in parallel to the longitudinal axes of the round cells; the battery blocks are stacked on one another with spacing so that a stack intermediate space results between adjacent battery blocks in the stack; a housing, including the stack made up of the battery blocks, wherein the stack is spaced apart from walls of the housing so that two terminal free spaces result between terminal battery blocks of the stack and the walls; the housing has at least one air inlet and at least one air outlet; a fan is assigned to the battery module to generate an airflow between the air inlet and the air outlet, and guiding means that ensure that the airflow is guided starting from at least one stack intermediate space between two adjacent battery blocks through the air passage openings in the cell holders between the cylindrical round cells of the individual battery blocks and through the terminal free spaces in a direction of the air outlet.

A battery housing includes an electrical cavity configured to accommodate battery cells. At least one battery cell includes a pressure relief mechanism configured to be actuated in response to internal pressure or temperature of the at least one battery cell reaching a threshold to relieve the internal pressure. The housing further includes a collection cavity configured to collect emissions from the at least one battery cell in response to the pressure relief mechanism being actuated, a separation component configured to separate the electrical cavity and the collection cavity, a partition structure configured to partition the collection cavity into a first cavity and a second cavity, and a flow channel baffle arranged in the second cavity and configured to form a flow channel for guiding the emissions. The partition structure is provided with an exhaust vent configured to guide the emissions in the first cavity into the second cavity.

A battery housing includes an electrical cavity configured to accommodate battery cells. At least one battery cell includes a pressure relief mechanism configured to be actuated in response to internal pressure or temperature of the at least one battery cell reaching a threshold to relieve the internal pressure. The housing further includes a collection cavity configured to collect emissions from the at least one battery cell in response to the pressure relief mechanism being actuated, a separation component configured to separate the electrical cavity and the collection cavity, a partition structure configured to partition the collection cavity into a first cavity and a second cavity, and a flow channel baffle arranged in the second cavity and configured to form a flow channel for guiding the emissions. The partition structure is provided with an exhaust vent configured to guide the emissions in the first cavity into the second cavity.

A power supply device includes a plurality of rectangular battery cells stacked in the thickness direction, and a plurality of separators interposed between adjacent battery cells. The separator includes an insulating separator frame that forms a defined space surrounded in a frame shape, and a separator core that is inserted into the defined space surrounded by the separator frame and is disposed between the adjacent battery cells.

A power supply device includes a plurality of rectangular battery cells stacked in the thickness direction, and a plurality of separators interposed between adjacent battery cells. The separator includes an insulating separator frame that forms a defined space surrounded in a frame shape, and a separator core that is inserted into the defined space surrounded by the separator frame and is disposed between the adjacent battery cells.

The present invention relates to an arrangement for cooling of a plurality of electrical energy storage units. The arrangement comprises a tubular element forming a cooling channel for a cooling medium which has an extension between an inlet opening and an outlet opening. The tubular element comprises a first plane wall element and a second plane wall element arranged in parallel at a distance from each other which is smaller than the height of the electrical energy storage units and that the first plane wall element comprises through holes each configured to receive and define a mounting position of an electrical energy storage unit in the cooling channel.

The present invention relates to an arrangement for cooling of a plurality of electrical energy storage units. The arrangement comprises a tubular element forming a cooling channel for a cooling medium which has an extension between an inlet opening and an outlet opening. The tubular element comprises a first plane wall element and a second plane wall element arranged in parallel at a distance from each other which is smaller than the height of the electrical energy storage units and that the first plane wall element comprises through holes each configured to receive and define a mounting position of an electrical energy storage unit in the cooling channel.