A battery module is described herein. The example battery module incldues a housing, a pluarlity of battery cells, and at least one cell-swelling restraint feature. The example cell-swelling restraint feature includes a cradle, side walls, and heat-staking features. The example battery module also includes an isolation feature positioned between the restraint feature and the battery cells to provide electrical insulation.

A battery module is described herein. The example battery module incldues a housing, a pluarlity of battery cells, and at least one cell-swelling restraint feature. The example cell-swelling restraint feature includes a cradle, side walls, and heat-staking features. The example battery module also includes an isolation feature positioned between the restraint feature and the battery cells to provide electrical insulation.

The present invention relates to a battery module comprising a particulate metal-dispersed thermal conductive resin, and a method and a system for inspecting same. The present invention can effectively inspect the degree of dispersion in the resin in a nondestructive manner and can detect a defect.

The present invention relates to a battery module comprising a particulate metal-dispersed thermal conductive resin, and a method and a system for inspecting same. The present invention can effectively inspect the degree of dispersion in the resin in a nondestructive manner and can detect a defect.

A structured battery having a battery core disposed between two carbon fiber layers. The battery core includes one or more layers of graphene battery sheets configured to store electricity. The structured battery also includes a honeycomb layer configured to transfer heat from the one or more layers of graphene battery sheets to the carbon fiber layers. The structured battery can be used as a structural component such as components of an electric vehicles, components of a building, or components of an appliance.

A structured battery having a battery core disposed between two carbon fiber layers. The battery core includes one or more layers of graphene battery sheets configured to store electricity. The structured battery also includes a honeycomb layer configured to transfer heat from the one or more layers of graphene battery sheets to the carbon fiber layers. The structured battery can be used as a structural component such as components of an electric vehicles, components of a building, or components of an appliance.

A resin composition, a flame-resistant structure and a battery package are provided. The resin composition includes a resin, a crystalline hydrate, and urea, wherein the weight ratio of crystalline hydrate to resin to urea is 6:1.5-5:1.2-3. The flame-resistant structure includes a body. The body includes a cured resin composition. The resin composition includes a resin, a crystalline hydrate, and urea, wherein the weight ratio of crystalline hydrate to resin to urea is 6:1.5-5:1.2-3. The battery package includes a battery and the flame-resistant structure.

A resin composition, a flame-resistant structure and a battery package are provided. The resin composition includes a resin, a crystalline hydrate, and urea, wherein the weight ratio of crystalline hydrate to resin to urea is 6:1.5-5:1.2-3. The flame-resistant structure includes a body. The body includes a cured resin composition. The resin composition includes a resin, a crystalline hydrate, and urea, wherein the weight ratio of crystalline hydrate to resin to urea is 6:1.5-5:1.2-3. The battery package includes a battery and the flame-resistant structure.

A multi-module battery pack includes a battery tray defining multiple battery tray compartments, battery modules each disposed within a corresponding one of the compartments, and a thermal barrier arranged in a predefined heat transfer path through the tray between an adjacent pair of the battery modules. The thermal barrier has a thickness of at least about 1 mm and a thermal conductivity of less than about 4 W/m-K, such that the thermal barrier blocks the heat transfer path to mitigate a thermal runaway event of one of the adjacent pair of battery modules. An electric powertrain system includes a rotary electric machine having phase leads and an output member, a driven load coupled to the output member, and the multi-module battery pack. A method includes providing the tray, identifying the heat transfer path, and arranging the thermal barrier in the heat transfer path.

Disclosed is a battery pack including plurality of battery cells; a bus bar assembly having a first side and a second side, the second side of the bus bar assembly provided to a first side of the plurality of battery cells and electrically connected to the plurality of battery cells; a cooling unit disposed at the second side of the bus bar assembly and arranged between the plurality of battery cells along a longitudinal direction of the battery pack; and a side structure unit configured to accommodate the cooling unit and the plurality of battery cells and configured to form a first section of an outer surface of the battery pack.