A power storage device includes a plurality of power storage modules laminated, a conductive plate and a sealing member. The conductive plate and the sealing member are provided between the power storage modules adjacent to each other in a laminating direction of the power storage modules. The plurality of power storage modules each have an electrode laminate, an electrolytic solution, and a sealing body. The electrode laminate has electrode exposed portions exposed from the sealing body at one end and the other end in the laminating direction. Between the power storage modules adjacent to each other in the laminating direction, the conductive plate is disposed between the electrode exposed portions opposing each other to be in contact with the electrode exposed portions, and at least a portion between the sealing bodies opposing each other is filled with the sealing member.

A battery assembly according to an exemplary aspect of the present disclosure includes, among other things, a first cell stack including a plurality of battery cells and a structural assembly including a first pocket sized and shaped to receive the first cell stack. The structural assembly is configured to assert a compressive load on the first cell stack and at least partially enclose the first cell stack.

A battery assembly according to an exemplary aspect of the present disclosure includes, among other things, a first cell stack including a plurality of battery cells and a structural assembly including a first pocket sized and shaped to receive the first cell stack. The structural assembly is configured to assert a compressive load on the first cell stack and at least partially enclose the first cell stack.

A battery cooler comprises a refrigerant filling chamber, a refrigerant inflow passage, and a refrigerant outflow passage. The refrigerant filling chamber is sandwiched between opposed battery unit cells and is arranged at a position for receiving heat of the unit cells. The refrigerant inflow passage is connected to a lower portion of the refrigerant filling chamber. The refrigerant outflow passage is connected to an upper portion of the refrigerant filling chamber. The refrigerant filling chamber has at least one joint part joining partially and mutually opposed wall surfaces so as to suppress expansion and deformation of these surfaces caused by the pressure of the refrigerant. An outflow side wall surface rises from a bottom surface of the refrigerant filling chamber toward a connection part of the refrigerant outflow passage. The outflow side wall surface is provided with an inclined surface directed downward from a horizontal direction.

A battery cooler comprises a refrigerant filling chamber, a refrigerant inflow passage, and a refrigerant outflow passage. The refrigerant filling chamber is sandwiched between opposed battery unit cells and is arranged at a position for receiving heat of the unit cells. The refrigerant inflow passage is connected to a lower portion of the refrigerant filling chamber. The refrigerant outflow passage is connected to an upper portion of the refrigerant filling chamber. The refrigerant filling chamber has at least one joint part joining partially and mutually opposed wall surfaces so as to suppress expansion and deformation of these surfaces caused by the pressure of the refrigerant. An outflow side wall surface rises from a bottom surface of the refrigerant filling chamber toward a connection part of the refrigerant outflow passage. The outflow side wall surface is provided with an inclined surface directed downward from a horizontal direction.

A liquid-cooled motor vehicle traction battery module with a rigid and fluid-tight module housing in which a plurality of plate-like identical battery cells are accommodated. A plurality of identical deformable compression elements are provided between the battery cells and the battery cells are cooled by module-internal liquid cooling. Rigid cooling plates, which have cooling ducts for cooling liquid, are arranged between two mutually adjacent battery cells. Either a cooling plate or a compression element, against which the battery cells respectively directly bear, is in each case alternately arranged between two mutually adjacent battery cells.

A liquid-cooled motor vehicle traction battery module with a rigid and fluid-tight module housing in which a plurality of plate-like identical battery cells are accommodated. A plurality of identical deformable compression elements are provided between the battery cells and the battery cells are cooled by module-internal liquid cooling. Rigid cooling plates, which have cooling ducts for cooling liquid, are arranged between two mutually adjacent battery cells. Either a cooling plate or a compression element, against which the battery cells respectively directly bear, is in each case alternately arranged between two mutually adjacent battery cells.

Systems and methods are described for thermal management, detection of abnormal cell heating, prevention of thermal runaway in the failing battery as well as the prevention of thermal runaway propagation and fire spread in battery systems. Battery systems and modules under the present disclosure can comprise deformation elements that deform when heated by a battery experiencing some type of failure. The deformation can be used to puncture a coolant tube, activate a nozzle, or otherwise release coolant onto the failing battery. The direct contact heat transfer, such as under boiling conditions, can quickly dissipate the heat using less coolant than prior art systems. Electrical circuits can automatically detect the deformation and disconnect the failing module or battery from a larger system.

A battery system includes a power cell and a heat exchanger abutting the power cell. The heat exchanger includes a cooling medium reservoir, a heat exchange member, and a wicking structure disposed between the cooling medium reservoir and the heat exchange member. The wicking structure provides a fluid pathway from the cooling medium reservoir to the heat exchange member and from the heat exchange member to the cooling medium reservoir.

A battery system includes a power cell and a heat exchanger abutting the power cell. The heat exchanger includes a cooling medium reservoir, a heat exchange member, and a wicking structure disposed between the cooling medium reservoir and the heat exchange member. The wicking structure provides a fluid pathway from the cooling medium reservoir to the heat exchange member and from the heat exchange member to the cooling medium reservoir.