Abstract: A power supply device including a plurality of battery cells electrically connected with each other by bus bar. The power supply device has a structure where bus bar includes: rod having conductivity and extending in an arrangement direction of the battery cells; and arm being elastically deformable and being connected to rod, arm is configured such that distal end of arm is welded to an electrode terminal of the battery cell, and rear end of arm is connected to rod so as to electrically connect the plurality of battery cells to each other via the rod, arm is formed of a conductive plate that is elastically deformable, deformation gap extending from rear end toward a distal end is formed between arm and rod, and arm is elastically deformable so as to displace distal end to be welded to the electrode terminal.

Abstract: Voltage detection line (6) includes: first flexible printed circuit board (36) including a plurality of first conductive wires (42) and first insulating film (44) covering the plurality of first conductive wires (42); second flexible printed circuit board (38) including a plurality of second conductive wires (46) and second insulating film (48) covering the plurality of second conductive wires (46); and connection part (40) that is soldered to each of first conductive wires (42) and each of second conductive wires (46) corresponding to each other to electrically connect the plurality of first conductive wires (42) and the plurality of second conductive wires (46), in which the plurality of first conductive wires (42) and the plurality of second conductive wires (46) are electrically connected to a plurality of batteries to detect voltages of the plurality of batteries.

Abstract: Provided is a voltage detection line including conductive wire and insulating film covering conductive wire, and detecting voltage of a battery in order to suppress reconduction of a disconnected voltage detection line. Conductive wire includes low-resistance part having a predetermined electrical resistance value, and high-resistance part having a higher electrical resistance value than an electrical resistance value of low-resistance part and fusing when an overcurrent flows through conductive wire. Insulating film includes high-strength part that covers low-resistance part and has a predetermined strength, and low-strength part that covers high-resistance part and has a strength lower than a strength of high-strength part.

Abstract: Voltage detection line includes conductive wire, and tab terminal that electrically connects bus bar electrically connected to output terminal of the battery and conductive wire. Support plate includes base plate on which voltage detection line is placed, and position restricting structure of tab terminal. Position restricting structure includes receiving surface part against which tab terminal abuts, and biasing part that pushes tab terminal toward receiving surface part.

Abstract: In a stack, a plurality of power storage cells are stacked. A resin plate is placed on the stack. A flexible printed circuit board is placed on the resin plate and has an electric circuit electrically connected to the plurality of power storage cells. A thermistor element is provided on the electric circuit and is in contact with one power storage cell of the plurality of power storage cells to detect a temperature of the power storage cell. A cover member is provided on the resin plate to cover the flexible printed circuit board. An elastic body is located between the cover member and the thermistor element to press the thermistor element toward the power storage cell. The cover member includes a protuberance that protrudes toward the resin plate side. The elastic body is disposed on the protuberance.

Abstract: A plate member is provided with a gas exhaust port, an opening, and a wall portion. The opening is formed in a bottom surface portion at a position facing an electrode terminal. The wall portion protrudes from the bottom surface portion at positions on outer sides with respect to the gas exhaust port in a width direction of the plate member, and discontinuously extends in a stacking direction of power storage cells. A flexible printed circuit board has a main body portion, and a connection piece portion that extends from the main body portion and is curved so as to be connected to a connection terminal. A first gap is formed between the main body portion and the connection piece portion. A first auxiliary wall portion is provided in the first gap, the first auxiliary wall portion protruding from the bottom surface portion and extending in the stacking direction.

Abstract: A power storage module includes: a stack in which a plurality of power storage cells are stacked in a stacking direction; a resin plate placed on the stack of the plurality of power storage cells; a flexible printed circuit board placed on the resin plate and having an electric circuit electrically connected to the plurality of power storage cells; and a cover member provided on the resin plate so as to cover the flexible printed circuit board. The resin plate includes a projection that extends through the flexible printed circuit board. The cover member includes a tubular protrusion that protrudes toward the flexible printed circuit board on the resin plate. The projection is accommodated in an inner periphery of the tubular protrusion. The tubular protrusion is in abutment with the flexible printed circuit board at a position to avoid the electric circuit.

Abstract: A flexible printed circuit board is placed on a bottom surface portion and has an electric circuit electrically connected to a plurality of power storage cells. A connection terminal is provided on the flexible printed circuit board and is electrically connected to an electrode terminal. The flexible printed circuit board has a main body portion, and a connection piece portion that extends from the main body portion and is curved so as to be connected to the connection terminal. The connection piece portion includes a first straight portion extending straightly in a stacking direction of the power storage cells, and a second straight portion extending in parallel with the first straight portion with a gap being interposed between second straight portion and the first straight portion. The second straight portion is longer than the first straight portion.

Abstract: A power storage module includes: a stack of a plurality of power storage cells; a resin plate placed on the stack of the plurality of power storage cells; a flexible printed circuit board placed on the resin plate and having an electric circuit electrically connected to the plurality of power storage cells; and an element provided on the electric circuit. The flexible printed circuit board is fixed to the resin plate at a fixation position including a first fixation portion and a second fixation portion. The first fixation portion and the second fixation portion are separated from each other by a first distance (L1) along the stacking direction, and the element is provided at a position separated from the first fixation portion or the second fixation portion by a second distance (L2) along the stacking direction, the second distance (L2) being less than or equal to ? of the first distance (L1).

Abstract: A power storage module includes: a stack in which a plurality of power storage cells are stacked in a stacking direction; a resin plate placed on the stack of the plurality of power storage cells; a flexible printed circuit board placed on the resin plate and having an electric circuit electrically connected to the plurality of power storage cells; a connector for the electric circuit, the connector being fixed to the flexible printed circuit board; and a substrate that supports the flexible printed circuit board and the connector, the substrate being fixed to the resin plate. The resin plate includes a projection that extends through the substrate and the flexible printed circuit board. A groove portion including a curved contour is formed in the resin plate at a root portion of the projection.

Abstract: A cover member is provided on a resin plate to cover a flexible printed circuit board. The resin plate is provided with an opening at a position at which a thermistor element and a power storage cell are in contact with each other. The flexible printed circuit board has an extension piece portion extending to above the opening of the resin plate, and a root portion adjacent to the extension piece portion and wider than the extension piece portion. The thermistor element is disposed on the extension piece portion. The cover member has a protuberance that protrudes toward the resin plate side and that presses and bends the extension piece portion so as to press the thermistor element toward the power storage cell. The root portion is fixed to the resin plate.

Abstract: A power storage module includes: a stack in which a plurality of power storage cells are stacked in a stacking direction; a resin plate having a bottom surface portion and placed on the stack of the plurality of power storage cells; a flexible printed circuit board placed on the bottom surface portion of the resin plate and having an electric circuit electrically connected to the plurality of power storage cells; a connector for the electric circuit, the connector being fixed to the flexible printed circuit board; and a substrate that supports the flexible printed circuit board and the connector, the substrate being fixed to the resin plate with the substrate being positioned in an extending direction of the bottom surface portion of the resin plate.

Abstract: To weld a bus bar and an electrode terminal with certainty by bringing the bus bar and the electrode terminal into close contact with each other without forming a gap between the bus bar and the electrode terminal, provided is a power supply device that is a power supply device including a plurality of battery cells electrically connected with each other by bus bar (3).

Abstract: A method for producing busbar includes a step of applying pressure to pressure-weld a plurality of electric wires in a plurality of first regions in a bundle of the plurality of electric wires, the first regions being arranged at a predetermined interval in the extending direction of the bundle, to form a plurality of terminal joints that are joined to the output terminals of the respective batteries.