The invention provides an electrode assembly and its battery device thereof, which is composed of a first belt current collector and a second belt current collector, which a plurality of electrochemical systems are disposed therebetween. Also, the glue frame is utilized to completely enclose thereof. Therefore, each electrochemical system is an independent module and there only have charges transferred occurring rather than electrochemical reactions therebetween. The glue frame located between the electrochemical systems and the first belt current collector and the second belt current collector adhered by the glue frame can be folded to form a bending portion. By the bending portion, the electrochemical system would be folded to overlap the adjacent electrochemical system to achieve a z-axis stacking. It is easy to mass produce, and it can also reduce the amount of the tabs configured in series or parallel. Therefore, the energy density loss of the space configuration can be reduced.

A battery module including a battery cell stack, which includes a plurality of battery cells stacked in a stacking direction, a housing for the battery cell stack, a busbar that is connected with the electrode lead of the battery cell, a busbar frame that faces the front surface or rear surface of the battery cell stack and has the busbar mounted on a surface thereof, an end plate that is coupled with the housing and covers the busbar frame, and a cooling member that is located in a separation space between the busbar frame and the end plate. The cooling member includes a thermal conductive resin.

A battery system includes a battery frame, a battery module, and a polymeric seat. The battery frame includes a horizontal bottom plate and a plurality of members that extend in a vertical direction from the bottom plate. The battery module includes at least one battery cell enclosed inside body of the battery module. The battery module also includes an attachment surface fixedly attached to the body and one or more supports that extend downward from to the body. The attachment surface is fixedly attached to one or more of plurality of members to generate a force on the one or more supports in a direction of the bottom plate. The polymeric seat is fixedly attached to either the one or more supports or the battery frame and removably contacts the other of the one or more supports or the battery frame. The polymeric seat is compressed in response to the force.

A battery and a manufacturing method thereof are provided. The battery module includes: a battery cell group, in which a plurality of battery cells is laminated; a pair of end plates, which is arranged on two end portions of the battery cell group; and restraint members, which are disposed over the pair of end plates and restrain the battery cell group between the pair of end plates. The restraint members are coupled by grappling structures to the pair of end plates on two end portions along the lamination direction the battery cells, and the pair of end plates clamps the battery cell group in a state that the battery cell group is compressed and pulling forces toward opposite directions act on the two end portions of the restraint members by a restoration force when the battery cell group restores from the compression state.

A power storage device includes: a power storage module in which a plurality of power storage cells are stacked along a stacking direction; and a case that accommodates the power storage module, wherein each of the power storage cells in the power storage module has a main surface extending in a direction substantially orthogonal to the stacking direction, and the case includes a supporting portion that supports, along the stacking direction, the power storage module accommodated in the case, and the case is provided with a recess that is provided at a position different from the supporting portion and that opens toward the main surface.

A solid state battery cell has a frame formed by a non-electrically conductive material. The frame has a frame thickness (Tf). A cell core surrounded by and entirely within the frame has a cell-core thickness (Tc). The cell core includes at least one anode, at least one cathode and at least one electrolyte between the at least one anode and the at least one cathode. At least one cell-core swell-accommodating recess is surrounded by and entirely within the frame. The at least one cell-core swell-accommodating recess defines an internal cell volume into which the cell core is expandable and from which the cell core is contractible. The cell-core thickness (Tc) is less than or equal to the frame thickness (Tf) during cell-charge and/or cell-discharge cycling.

The invention relates to a method for installing battery modules in a container in such a way as to maximize the amount of energy installed, while providing modularity of the voltage delivered by the container. The invention also relates to a method for installing electrochemical elements of parallelepipedal format in a volume of parallelepipedal format, such as a module or a vertical volume of a container.

A battery structure is disclosed. The battery structure includes a first current collector layer, a first active material layer, a spacer layer, a first plastic frame, a second active material layer and a second current collector layer. The first active material layer is disposed on the first current collector layer. The spacer layer is disposed on the first active material and completely covers the top surface of the first active material layer. The first plastic frame is disposed on the side wall of the spacer layer and the top of the first plastic frame has a protruding part which extends to the top surface of the spacer. The second active material layer is disposed on the spacer layer and the protruding part. The second active material is isolated from the first active material via the space layer and the protruding part. The second current collector layer is disposed on the second active material layer.

A power storage device includes a case, an electrode body, and an electrolyte. The electrode body is located in the case and has a positive electrode, a negative electrode, and a separator located between the positive and negative electrodes. The electrolytefills the case 2. A principal surface of the electrode body is connected to an inner surface of the case.

A power generating element mounting board includes: a power generating element having a first terminal and a second terminal; and a board having a first board terminal connected with the first terminal, a second board terminal connected with the second terminal, and at least a first hole and a second hole. The first hole has a first conductive part provided on a surface of the first hole, the second hole has a second conductive part provided on a surface of the second hole. The first hole is provided between the first board terminal and a first outer edge of the board, and the second hole is provided between the second board terminal and a second outer edge of the board.