A battery device includes: a battery stack including a plurality of battery cells arranged along a predetermined straight direction; a pair of end members that are spaced apart from each other in the straight direction and sandwich the battery stack to prevent battery cells from moving; a temperature adjusting part which includes a heat exchange part for exchanging heat with the battery stack and a flowing passage in which a fluid for exchanging heat with the heat exchange part is flowing; and an end member fixing part to which the end members are fixed. The temperature adjusting part and the end member fixing part are integrally united into a single piece structure made of metal.

A method produces a laminate-type battery which can suppress short-circuiting even when a positioning guide is used. The method for producing a laminate-type battery having a first current collector layer, a first active material layer, a solid electrolyte layer or a separator layer, a second active material layer, and a second current collector layer laminated in this order, the method includes arranging a first layer along a first contact surface of a positioning guide, rotating the positioning guide, and thereafter arranging a second layer on the arranged first layer along a second contact surface of the positioning guide. The first layer and the second layer are different from each other and include an arbitrary layer selected from the first current collector layer, the first active material layer, the solid electrolyte layer or the separator layer, the second active material layer, and the second current collector layer.

The present invention relates to a method for inspection of a multilayer electrode sheet for a battery cell, comprising at least the following steps: joining together at least two functional layers; connecting the functional layers to form an electrode-separator assembly; detecting at least part of a surface of the electrode-separator assembly by means of a detection device for generating a measurement result; evaluating the generated measurement result and generating an evaluation result; and outputting the evaluation result.

The disclosed embodiments relate to a battery cell which includes a first electrode sheet having a first area and a second electrode sheet having a second area. The second area may be less than the first area. The battery cell also includes a first conductive tab coupled to the first electrode sheet and a second conductive tab coupled to the second electrode sheet. An insulator is disposed between the second conductive tab and the first electrode sheet, the insulator configured to prevent electrical current from flowing between the first electrode sheet and the second conductive tab. The battery cell also includes a pouch that encloses the first and second electrode sheets and a first and second battery terminal extending through the pouch. The first battery terminal may be coupled to the first conductive tab, and the second battery terminal may be coupled to the second conductive tab.

A battery includes a first current collector, a first electrode layer, and a first counter electrode layer. The first counter electrode layer is a counter electrode of the first electrode layer. The first current collector includes a first electroconductive portion, a second electroconductive portion, and a first insulating portion. The first electrode layer is disposed in contact with the first electroconductive portion. The first counter electrode layer is disposed in contact with the second electroconductive portion. The first insulating portion links the first electroconductive portion and the second electroconductive portion. The first current collector is folded at the first insulating portion, whereby the first electrode layer and the first counter electrode layer are positioned facing each other.

Provided is a system for manufacturing a secondary battery including: a positive electrode cell manufacturing line having a positive electrode single cell, on which a positive electrode tab is processed on one end of a positive electrode and a first separator is combined on one surface of the positive electrode, is continuously manufactured; a negative electrode cell manufacturing line having a negative electrode single cell, on which a negative electrode tab is processed on one end of a negative electrode and a second separator is combined on one surface of the negative electrode, is continuously manufactured; and a stacking part alternately receiving positive electrode single cells and negative electrode single cells respectively from the positive electrode cell manufacturing line and the negative electrode cell manufacturing line to stack the positive electrode single cells and the negative electrode single cells up to a predetermined layer, thereby forming a stack cell.

Disclosed is a stacked battery that can flow a larger rounding current in a short-circuit current shunt part than in an electric element when a short circuit occurs in the short-circuit current shunt part and the electric element in nailing, the stacked battery in which an electrical resistance of a current collector tab of the short-circuit current shunt part is smaller than an electrical resistance of a current collector tab of the electric element.

The present disclosure relates to a battery, a method for preparing the same, an application method and an electronic device. The battery includes: a battery panel, in which the battery panel is capable of being switched between a first state and a second state, in the first state, the cation-transporting subunit is in contact with the ion-receiving subunit and one of the two ion-supplying subunits, and the anion-transporting subunit is in contact with the ion-receiving subunit and the other of the two ion-supplying subunits; in the second state, the cation-transporting subunit is not in contact with the ion-receiving subunit and one of the two ion-supplying subunits, and the anion-transporting subunit is not in contact with the ion-receiving subunit and the other of the two ion-supplying subunits.

Vehicle having a high-voltage battery which has a housing, wherein the housing has a housing floor which is essentially parallel to an underlying surface on which the vehicle is standing or travelling, a housing cover which is arranged spaced apart from the housing floor, housing walls via which the housing floor is connected to the housing cover. The housing has at least one housing structure plate which has a plane of maximum size which is perpendicular with respect to the housing floor and with respect to the housing cover, and an underside which faces the housing floor or is connected thereto, and an upper side which faces the housing cover or is connected thereto. In an interior space of the housing structure plate at least two parallel cooling ducts are provided, through which coolant or a cooling agent flows, and on a first side and a second side, lying opposite the first side, of the housing structure plate at least one electrical storage cell is respectively arranged, in particular a multiplicity of electrical storage cells are respectively arranged, wherein the storage cells each have a positive and a negative connecting pole. At least one connecting pole or both connecting poles of the storage cells is/are connected to the first and/or second side of the housing structure plate in a thermally conductive and electrically insulated fashion.

An objective of the present disclosure is to provide a stacked battery that suppresses sneak current caused by an unevenness of a short circuit resistance among a plurality of cells. The present disclosure provides a stacked battery comprising: a plurality of cells in a thickness direction, wherein the plurality of cells are electrically connected in parallel; the stacked battery includes a surface-side cell that is located on a surface side of the stacked battery, and a center-side cell that is located on a center side rather than the surface-side cell; wherein a resistance of the cathode current collecting tab in the surface-side cell is more than a resistance of the cathode current collecting tab in the center-side cell; or a resistance of the anode current collecting tab in the surface-side cell is more than a resistance of the anode current collecting tab in the center-side cell.