JP2017130280A - Battery pack and power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery pack and a power supply device which can improve the positioning accuracy of a battery cell.SOLUTION: A battery pack according to the present invention comprises: a battery cell (150) having electrode terminals (152 and 153) on a cap surface (151); a lower case (110) which can house the battery cell (150); and a cell holder (120) which engages with the lower case (110) so as to hold, on the cap surface (151), the battery cell (150) inside the lower case (110). The cell holder (120) comprises: a holding lid (122) for holding the battery cell (150); and a vertical direction positioning rib (127b) having a predetermined height on a lower surface side of the holding lid (122).SELECTED DRAWING: Figure 7

Description

  The present invention relates to an assembled battery and a power supply device.

  Conventionally, an assembled battery in which a plurality of batteries are housed in a member such as a housing is known. For example, Patent Document 1 discloses an assembled battery configured by arranging a plurality of lithium ion cells on a frame member.

Special table 2014-504440 gazette

  However, in the assembled battery disclosed in Patent Document 1, the positioning of the lithium ion cell in the frame member is not considered. Therefore, for example, when the bus bar is attached to the electrode, stress may be applied to the bus bar depending on the position of the assembled battery arranged on the frame member.

  The objective of this invention made | formed in view of this viewpoint is providing the assembled battery and power supply device which can improve the positioning accuracy of a battery cell.

In order to solve the above problem, the assembled battery according to the first aspect is:
A battery cell having an electrode terminal on the cap surface;
A lower case capable of accommodating the battery cell;
A cell holder for holding the battery cell in the lower case on the cap surface by engaging with the lower case;
The cell holder includes a holding lid for holding the battery cell, and a vertical positioning rib having a certain height on a lower surface side of the holding lid.

The assembled battery according to the second aspect is
The cell holder includes a plurality of the vertical positioning ribs,
The plurality of vertical positioning ribs have the same height.

An assembled battery according to the third aspect is
The cell holder has an opening for exposing the electrode terminal to the upper surface side, and includes the vertical positioning rib at a position along the opening.

The assembled battery according to the fourth aspect is
The battery cell and the cell holder are bonded by an adhesive applied along a side surface of the vertical positioning rib that does not face the opening.

An assembled battery according to the fifth aspect is
The battery cell and the cell holder are bonded by an adhesive applied to the surrounding area formed on the lower surface side of the holding lid by being surrounded by a wall surface including at least a part of the vertical positioning rib. It is characterized by that.

An assembled battery according to the sixth aspect is
The wall surface includes at least one of a stacking direction positioning rib that defines a direction of the battery cell accommodated in the lower case and a side surface of the cell holder.

The assembled battery according to the seventh aspect is
The lower case includes a support rib for supporting the battery cell from the bottom surface side in a state where the battery cell is accommodated on the bottom surface.
It is characterized by having a filler in the surrounding area | region formed in the said bottom face by being surrounded by the 2nd wall surface which contains the said support rib at least in part.

The assembled battery according to the eighth aspect is
The filler is an adhesive.

The assembled battery according to the ninth aspect is
The filler is an elastic agent.

  Moreover, the power supply device which concerns on a 10th viewpoint is provided with the said assembled battery.

  According to the assembled battery according to the first aspect, the vertical position of the battery cell relative to the holding lid of the cell holder is determined by the cap surface of the battery cell coming into contact with the vertical positioning rib.

  Moreover, according to the assembled battery which concerns on a 2nd viewpoint, the battery cell contact | abutted to each up-down direction positioning rib uniquely determines the position of an up-down direction irrespective of the up-down direction positioning rib which contact | abuts.

  Moreover, according to the assembled battery which concerns on a 3rd viewpoint, the positioning accuracy of the up-down direction of the electrode terminal exposed from opening is improved.

  Moreover, according to the assembled battery which concerns on a 4th viewpoint, it becomes easy to prevent an adhesive from flowing into an opening, implement | achieving the adhesion state of a battery cell and a cell holder.

  Moreover, according to the assembled battery which concerns on a 5th viewpoint, since the adhesion area of a battery cell and a cell holder increases, a battery cell and a cell holder can adhere | attach more strongly.

  Moreover, according to the assembled battery which concerns on a 6th viewpoint, the mechanism with which a cell holder is equipped can be used together with a wall surface, and each mechanism can be utilized efficiently.

  Moreover, according to the assembled battery which concerns on a 7th viewpoint, since a lower case and a battery cell do not contact directly but contact via a filler, the contact state according to the property of the filler is implement | achieved.

  Moreover, according to the assembled battery which concerns on an 8th viewpoint, the adhesion state of a battery cell and a lower case is implement | achieved.

  Moreover, according to the assembled battery which concerns on a 9th viewpoint, since an elastic agent absorbs the vibration which arises when driving | running | working the vehicle provided with an assembled battery, a vibration becomes difficult to be transmitted to a battery cell.

  Moreover, according to the power supply device which concerns on a 10th viewpoint, when the cap surface of a battery cell contact | abuts to an up-down direction positioning rib, the position of the up-down direction of a battery cell with respect to the holding lid of a cell holder is decided.

It is an external appearance perspective view of the assembled battery which concerns on one Embodiment of this invention. It is a functional block diagram which shows the outline of the power supply system containing the assembled battery shown in FIG. It is an external appearance perspective view of the assembled battery which shows the lower case and cell holder of the assembled battery of FIG. 1 in a transparent state. It is a disassembled perspective view of the assembled battery of FIG. It is an external appearance perspective view of the lower case of FIG. FIG. 6 is a top view of the lower case of FIG. 5. It is an external appearance perspective view of the cell holder of FIG. It is an external appearance perspective view which shows the state which attached the cell holder of FIG. 7 to the lower case of FIG. It is an expansion appearance perspective view of a bus bar between cells attached to a cell holder. It is sectional drawing which shows typically the adhesion position of the battery cell in the assembled battery of FIG. 1, a lower case, and a cell holder. It is a figure which shows typically the state before and behind the engagement nail | claw of a cell holder and the engagement hole of a lower case. It is an external appearance perspective view of the auxiliary machine base of FIG. It is a side view at the time of seeing the auxiliary machine base of FIG. 1 from one side. It is an external appearance perspective view of the auxiliary machine base which shows the state which attached each component and the bus bar. It is a top view of the auxiliary machine base which shows the state which fixed each component and the bus bar with the nut. It is a figure which shows the mode of the assembly of the whole assembled battery. It is a figure for demonstrating the mode of an assembly | attachment of a battery module group and an auxiliary machine module group.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an external perspective view of an assembled battery according to an embodiment of the present invention, and is an external perspective view showing a state where an upper case of the assembled battery is removed. However, in FIG. 1, the depiction of each part is shown in a simplified manner. Refer to FIGS. 5 to 15 for details of each component. The assembled battery 100 includes a lower case 110 that houses battery cells, a cell holder 120 that holds battery cells housed in the lower case 110 on a side to which the upper case is attached (hereinafter also referred to as “upper surface side”), and a cell holder 120. 1 is provided with an auxiliary machine base 200 attached to the upper surface side, various parts attached to the auxiliary machine base 200, and an upper case (not shown in FIG. 1) for protecting the various parts.

  In the present embodiment, the assembled battery 100 includes a metal oxide semiconductor field effect transistor (MOSFET) 210, a relay 220, a current sensor 230, and a fusible link 240 as various components attached to the auxiliary machine base 200. The assembled battery 100 includes three terminals, that is, an SSG terminal 250, a LOAD terminal 260, and a GND terminal 270 that protrude to the outside of the upper case when the upper case is attached.

  In the present embodiment, the assembled battery 100 will be described as being used by being mounted on a vehicle such as a vehicle equipped with an internal combustion engine or a hybrid vehicle capable of traveling with the power of both the internal combustion engine and the electric motor. The use of the battery 100 is not limited to the vehicle.

  FIG. 2 is a functional block diagram showing an outline of a power supply system including the assembled battery 100 shown in FIG. The power supply system 400 includes an assembled battery 100, an alternator 410, a starter 420, a second secondary battery 430, a load 440, a switch 450, and a control unit 460. The assembled battery 100 includes a first secondary battery 130 housed in the lower case 110. The first secondary battery 130, the alternator 410, the starter 420, the second secondary battery 430, and the load 440 are connected in parallel.

  The assembled battery 100 includes a MOSFET 210, a relay 220, a current sensor 230, a fusible link 240, a first secondary battery 130, and a battery controller (LBC) 140. Relay 220, current sensor 230, fusible link 240, and first secondary battery 130 are connected in series in this order. MOSFET 210 is connected in series to second secondary battery 430 and load 440.

  In the assembled battery 100, the SSG terminal 250 is connected to the alternator 410, and the LOAD terminal 260 is connected to the load 440. The GND terminal 270 is used for grounding.

  The relay 220 functions as a switch that connects or disconnects the first secondary battery 130 in parallel with each component outside the assembled battery 100 in the power supply system 400.

  The current sensor 230 has an appropriate structure, and measures the current flowing through the circuit including the first secondary battery 130 by an appropriate method.

  The fusible link 240 includes a fuse body, a housing made of an insulating resin that accommodates and holds the fuse body, and a cover made of an insulating resin that covers the housing, and is blown when an overcurrent occurs.

  The first secondary battery 130 is configured by an assembly of battery cells 150 accommodated in the lower case 110 as shown in FIG. 3 in which the lower case 110 and the cell holder 120 are transparent. Each battery cell 150 constituting the first secondary battery 130 is a secondary battery such as a lithium ion battery or a nickel metal hydride battery. The first secondary battery 130 has a positive electrode side connected to the fusible link 240 and a negative electrode side grounded via a GND terminal 270.

  MOSFET 210 functions as a switch for connecting or disconnecting second secondary battery 430 and load 440 in parallel with other components in power supply system 400.

  The LBC 140 is connected to the first secondary battery 130 and estimates the state of the first secondary battery 130. The LBC 140 estimates a state of charge (SOC) of the first secondary battery 130, for example.

  Alternator 410 is a generator and is mechanically connected to the engine of the vehicle. Alternator 410 generates power by driving the engine. The power generated by the alternator 410 by driving the engine can be supplied to the first secondary battery 130, the second secondary battery 430, and the load 440 included in the assembled battery 100 by adjusting the output voltage with a regulator. The alternator 410 can generate power by regeneration when the vehicle is decelerated. The electric power regenerated by the alternator 410 is used to charge the first secondary battery 130 and the second secondary battery 430.

  The starter 420 includes, for example, a cell motor, and receives power supply from at least one of the first secondary battery 130 and the second secondary battery 430 to start the engine of the vehicle.

  The second secondary battery 430 is composed of, for example, a lead storage battery and supplies power to the load 440.

  The load 440 includes, for example, an audio, an air conditioner, and a navigation system provided in the vehicle, and operates by consuming the supplied power. The load 440 operates by receiving power supply from the first secondary battery 130 while the engine driving is stopped, and operates by receiving power supply from the alternator 410 and the second secondary battery 430 while driving the engine.

  Switch 450 is connected in series with starter 420. The switch 450 connects or disconnects the starter 420 in parallel with other components.

  The control unit 460 controls the overall operation of the power supply system 400. The control unit 460 is configured by, for example, an ECU (Electric Control Unit or Engine Control Unit) of the vehicle. The control unit 460 controls the operation of the switch 450, the MOSFET 210, and the relay 220, respectively, and supplies power by the alternator 410, the first secondary battery 130, and the second secondary battery 430, and the first secondary battery 130. The second secondary battery 430 is charged.

  Next, a detailed configuration of the assembled battery 100 will be described with reference to FIGS. 4 to 17. 4 is an exploded perspective view of the battery pack of FIG. However, in FIG. 4, as in FIG. 1, some parts are simplified. FIG. 5 is an external perspective view of the lower case 110, and FIG. 6 is a top view of the lower case 110. FIG. 7 is an external perspective view of the cell holder 120. 7A is an external perspective view from the upper surface side of the cell holder 120, and FIG. 7B is an external perspective view from the opposite side (hereinafter also referred to as “lower surface side”) of the cell holder 120. It is. FIG. 8 is an external perspective view showing a state where the cell holder 120 is attached to the lower case 110. FIG. 9 is an enlarged external perspective view of the inter-cell bus bar 160 attached to the cell holder 120. FIG. 10 is a diagram schematically illustrating the bonding positions of the battery cell 150, the lower case 110, and the cell holder 120 in the assembled battery 100. FIG. 11 is a diagram schematically showing a state before and after the engagement claw 128 of the cell holder 120 and the engagement hole 115 of the lower case 110 are engaged. FIG. 12 is an external perspective view of the auxiliary machine pedestal 200, and FIG. 13 is a side view of the auxiliary machine pedestal 200 viewed from one side. FIG. 13A is a side view of the auxiliary machine base 200 only, and FIG. 13B is a side view of the auxiliary machine base 200 with components such as the relay 220 mounted thereon. FIG. 14 is an external perspective view of the auxiliary machine base 200 showing a state in which the components and the bus bar are attached. FIG. 15 is a top view of the auxiliary machine base 200 showing a state in which the components and the bus bar are fixed by the nut 290. FIG. 16 is a diagram illustrating a state of assembly of the entire assembled battery, and FIG. 17 is a diagram for illustrating a state of assembly of the battery module group and the accessory module group.

  The assembled battery 100 according to the present embodiment is assembled by assembling the battery module group and the accessory module group, then assembling the battery module group and the accessory module group, and fixing the upper case.

  The battery module group includes a battery cell 150, a lower case 110 that houses the battery cell 150, a cell holder 120 that holds the battery cell 150, an inter-cell bus bar 160, a total positive terminal bus bar 164, and a total negative terminal bus bar 165. , And LBC 140 are assembled.

  In this embodiment, the battery cell 150 with which the assembled battery 100 is provided has a substantially rectangular parallelepiped shape. Although the assembled battery 100 of this embodiment accommodates five battery cells 150, the number of battery cells 150 that can be accommodated by the assembled battery 100 is not limited to five. The number of battery cells 150 that can be accommodated in the assembled battery 100 is appropriately determined according to the maximum output of the battery cells 150 and the power consumed by a driven device such as a vehicle.

  As shown in FIG. 5, the lower case 110 is a housing having a space 110 a that can accommodate the battery cells 150 from the upper surface side. That is, the lower case 110 has a bottom surface 111 and four side surfaces 112a, 112b, 112c, and 112d, and an opening 113 on the opposite side (that is, the top surface side) of the bottom surface 111. In the lower case 110, the side surfaces 112a and 112c face each other, and the side surfaces 112b and 112d face each other. Hereinafter, when the four side surfaces 112a, 112b, 112c, and 112d are not distinguished, they are collectively referred to as the side surface 112. The height of the side surface 112 is lower than the height of the battery cell 150 accommodated in the lower case 110.

  The side surfaces 112b and 112d include an attachment mechanism 114 for attaching the assembled battery 100 to the vehicle outside the lower case 110 (that is, on the opposite side of the space 110a). The attachment mechanism 114 is appropriately determined in shape and position on the side surfaces 112b and 112d in accordance with the attachment method with the vehicle.

  The side surface 112 has an engagement hole 115 for engagement with the cell holder 120 on the opening 113 side. In the present embodiment, each side surface 112 has three engagement holes 115 in the center on the opening 113 side and in the vicinity of both ends.

  The bottom surface 111 includes a guide 116a for indicating the position of the battery cell 150 to be accommodated and preventing the displacement of the battery cell 150 to be accommodated inside the lower case 110 (that is, on the space 110a side). The guide 116a also has a function of maintaining the space between the battery cells 150. For example, an insulating sheet or the like may be inserted in the space between the battery cells 150 formed by the guide 116a.

  The height of the guide 116 a is lower than the height of the side surface 112. In the present embodiment, four guides 116a are provided at equal intervals in parallel to the side surfaces 112b and 112d. That is, in the present embodiment, the lower case 110 accommodates five battery cells 150 arranged so as to be stacked from the side surface 112b to the side surface 112d along each region of the bottom surface 111 divided into five by the guide 116a. To do.

  Further, the bottom surface 111 includes a plurality of support ribs 116b in a direction orthogonal to the guide 116a. In the present embodiment, the bottom surface 111 includes two support ribs 116b. The support rib 116b contacts the battery cell 150 accommodated in the space 110a and supports the battery cell 150 from the bottom surface 111 side. The height from the bottom surface 111 of the support rib 116b is lower than the height from the bottom surface 111 of the guide 116a. As a result, each battery cell 150 is also in contact with the guide 116a in a state of being in contact with the support rib 116b, so that the position shift prevention function by the guide 116a is not impaired.

  In general, in the manufacture of the lower case 110, the side surfaces 112a and 112c without the attachment mechanism 114 are less likely to cause dimensional errors than the side surfaces 112b and 112d with the attachment mechanism 114. Therefore, the battery cells 150 accommodated in the lower case 110 are stacked in the lower case 110 by arranging the battery cells 150 so as to be stacked in the direction along the side surfaces 112a and 112c as in the present embodiment. It becomes difficult to slip.

  Note that the position, size, and the like of the guide 116a are appropriately determined according to the shape, quantity, and the like of the battery cell 150 that the lower case 110 houses.

  The battery cell 150 has a positive electrode terminal 152 and a negative electrode terminal 153 on one cap surface 151 having a substantially rectangular parallelepiped shape. Hereinafter, the positive electrode terminal 152 and the negative electrode terminal 153 are collectively referred to as “electrode terminals”. The cap surface 151 has a rectangular shape having a long side and a short side, and the positive electrode terminal 152 and the negative electrode terminal 153 are provided near both ends of the cap surface 151 in the long side direction. In addition, a safety valve that is opened at the center of the cap surface 151 to discharge gas to the outside when gas is generated inside the battery cell 150 due to aging, thermal runaway, or the like and the pressure inside the battery cell 150 exceeds a predetermined value. 154 is provided. The battery cell 150 is accommodated in the lower case 110 so that the cap surface 151 protrudes from the opening 113, that is, on the upper surface side. As shown in FIG. 4, in the lower case 110, the battery cell 150 is accommodated in the lower case 110 such that the arrangement of the positive electrode terminal 152 and the negative electrode terminal 153 of the battery cells 150 adjacent to each other is reversed. The

  The cell holder 120 is attached to the cap surface 151 side of the battery cell 150, that is, the opening 113 side of the lower case 110.

  The cell holder 120 is substantially rectangular in a top view, and holds the battery cell 150 from the upper surface side in a state where the cell holder 120 is engaged with the lower case 110 inside the outer peripheral frame 121 having a predetermined height and inside the outer peripheral frame 121. And a holding lid 122. The holding lid 122 holds the cap surface 151 of the battery cell 150 accommodated in the lower case 110 from the upper surface side.

  The outer peripheral frame 121 has four side surfaces 121a, 121b, 121c, and 121d. The four side surfaces 121a, 121b, 121c and 121d are arranged at positions corresponding to the four side surfaces 112a, 112b, 112c and 112d of the lower case 110, respectively, in a state where the outer peripheral frame 121 and the lower case 110 are engaged. The

  The outer peripheral frame 121 includes screw hole forming portions 123 having screw holes 123a for fixing the accessory base 200 to the cell holder 120 by screwing at the ends of the side surfaces 121b and 121d. The outer peripheral frame 121 is formed so as to protrude outward from the side surfaces 121b and 121d. In the screw hole forming portion 123, the screw hole 123a is formed so that a screw can be inserted from the upper surface side.

  In addition, the outer peripheral frame 121 is used for screwing bus bars (that is, total plus copper bus bars 285 and total minus copper bus bars 286 described later) to the cell holder 120 on the upper surfaces of the side surfaces 121b and 121d. It has a screw hole 123b. The screw holes 123b are preferably provided in the vicinity of an opening 124a to which a total plus terminal bus bar 164 and a total minus terminal bus bar 165 described later are attached.

  The holding lid 122 has an opening 124 a at a position corresponding to the positive terminal 152 and the negative terminal 153 of the battery cell 150 when the cell holder 120 and the lower case 110 are engaged. That is, as shown in FIG. 8, in the engaged state between the cell holder 120 and the lower case 110, the positive terminal 152 and the negative terminal 153 of the battery cell 150 are exposed from the opening 124 a to the upper surface side of the holding lid 122. .

  In addition, the holding lid 122 has an opening 124 b at a position corresponding to the safety valve 154 of the battery cell 150 when the cell holder 120 and the lower case 110 are engaged. That is, as shown in FIG. 8, in the engaged state between the cell holder 120 and the lower case 110, the gas discharged from the safety valve 154 is discharged from the opening 124a to the outside of the battery cell 150.

  The positive electrode terminal 152 and the negative electrode terminal 153 that are exposed from the opening 124 a and are aligned in a row are adjacent to each other except for the positive electrode terminal 152 connected to the fusible link 240 and the negative electrode terminal 153 connected to the GND terminal 270. Are electrically connected by the inter-cell bus bar 160. The inter-cell bus bar 160 is made of a conductive metal such as aluminum. The inter-cell bus bar 160 has a convex portion 161 for avoiding interference with the frame portion 122a of the holding lid 122 between the openings 124a in a state where the inter-cell bus bar 160 is connected to the positive electrode terminal 152 and the negative electrode terminal 153. Have. That is, the inter-cell bus bar 160 protrudes from the terminal connection part 162 connecting the two terminal connection parts 162 and the two terminal connection parts 162 connected to the positive electrode terminal 152 and the negative electrode terminal 153 to the upper surface side in a side view. And a convex portion 161.

  For example, as shown in FIG. 9, the terminal connecting portion 162 has a welding opening 162a at the center. The inter-cell bus bar 160 and the later-described total plus terminal bus bar 164 and total minus terminal bus bar 165 are connected to each terminal of the battery cell 150 by bead welding at the periphery of the welding opening 162a.

  Each terminal connection portion 162 has a voltage sensor attachment terminal 163 that protrudes toward the opening 124b when attached to the cell holder 120. Each voltage sensor attachment terminal 163 has a screw hole 163a. In the inter-cell bus bar 160, each voltage sensor mounting terminal 163 is arranged on a screw hole forming portion 126 described later when the terminal connection portion 162 of the inter-cell bus bar 160 is connected to the positive terminal 152 or the negative terminal 153. Is formed. The screw hole 163a overlaps with the screw hole 126a formed in the screw hole forming part 126 in a state where the voltage sensor mounting terminal 163 is disposed on the screw hole forming part 126, and the screw hole 126a and screw are screwed by the LBC 140. The holes 163a are screwed together. The voltage sensor attachment terminal 163 is connected to the voltage sensor and used to detect a voltage between the terminals.

  Further, the total positive terminal bus bar 164 is connected to the positive terminal 152 connected to the fusible link 240, and the total negative terminal bus bar 165 is connected to the negative terminal 153 connected to the GND terminal 270. The total plus terminal bus bar 164 and the total minus terminal bus bar 165 are made of a conductive metal such as aluminum. The total plus terminal bus bar 164 and the total minus terminal bus bar 165 include one terminal connection part 162 and an external connection part 166 for connecting to the total plus copper bus bar 285 and the total minus copper bus bar 286 provided in the auxiliary machine base 200, respectively. Have. The external connection portion 166 has a convex shape that protrudes to the upper surface side of the terminal connection portion 162 so as to sandwich the inner surface and the outer surface of the outer peripheral frame 121. In particular, as shown in FIG. 16, the external connection portion 166 is attached along a bus bar support portion 123 c formed from the inner surface to the outer surface of the outer peripheral frame 121. Moreover, the external connection part 166 has the screw hole 166a in the position corresponding to the screw hole 123b in the state attached to the outer periphery frame 121. As shown in FIG. Note that the terminal connection portions 162 of the total plus terminal bus bar 164 and the total minus terminal bus bar 165 also have a voltage sensor mounting terminal 163 that protrudes toward the opening 124b when mounted on the cell holder 120.

  The holding lid 122 prevents electrical connection between the bus bars between the inter-cell bus bars 160 attached to the cell holder 120 and between the inter-cell bus bar 160 and the total plus terminal bus bar 164 or the total minus terminal bus bar 165. And a bead 125 for positioning the bus bar. The bead 125 projects to the upper surface side of the holding lid 122.

  Further, the holding lid 122 includes a screw hole forming portion 126 for fixing the LBC 140 on the upper surface side. The screw hole forming portion 126 is formed between the opening 124 a and the opening 124 b on the upper surface side of the holding lid 122. That is, in the present embodiment, the holding lid 122 includes ten screw hole forming portions 126. The screw hole forming portion 126 has a substantially cylindrical shape, and a screw hole 126a is provided at the center. The LBC 140 is placed on the upper surface side of the cell holder 120 and is screwed to the cell holder 120 from the upper surface side using the screw holes 126a formed in the screw hole forming portion 126.

  In addition, the holding lid 122 includes a stacking direction positioning rib 127a for preventing the displacement of the battery cell 150 accommodated in the lower case 110 on the lower surface side. Four stacking direction positioning ribs 127a are provided at equal intervals in parallel to the side surfaces 121b and 121d. That is, the stacking direction positioning rib 127a of the holding lid 122 is provided in a direction and position corresponding to the guide 116a of the lower case 110 in a state where the cell holder 120 and the lower case 110 are engaged. The stacking direction positioning rib 127 a determines the position in the stacking direction of the battery cell 150 in the cell holder 120.

  In addition, the holding lid 122 includes a plurality of vertical positioning ribs 127b in the direction perpendicular to the stacking direction positioning rib 127a (that is, the stacking direction of the battery cells 150) along the opening 124a and the opening 124b on the lower surface side. . In the present embodiment, as shown in FIG. 7B, the vertical positioning rib 127b is provided in a direction orthogonal to the stacking direction positioning rib 127a around the opening 124a and the opening 124b. That is, in the bottom view of the holding lid 122, the stacking direction positioning ribs 127a and the vertical direction positioning ribs 127b are provided in a lattice shape. On the lower surface side of the holding lid 122, each of the regions partitioned in a lattice pattern by the stacking direction positioning ribs 127a and the vertical direction positioning ribs 127b includes an opening region 122b having an opening 124a or an opening 124b, and both the opening 124a and the opening 124b. It is divided into a covering region 122c that does not have.

  Each vertical positioning rib 127 b has a certain height from the lower surface side of the holding lid 122. In addition, the plurality of vertical positioning ribs 127 b are provided so as to have the same height from the lower surface side of the holding lid 122. The vertical positioning rib 127b contacts the cap surface 151 of the battery cell 150 in a state where the cell holder 120 holds the battery cell 150, and determines the position of the cell holder 120 in the vertical direction. Since the heights of the plurality of vertical positioning ribs 127b are the same, the vertical positions of the plurality of battery cells 150 are uniquely determined, and all the electrode terminals are uniformly exposed from the openings 124a.

  As shown in FIG. 7B, the height of the vertical positioning ribs 127b is lower than the height of the stacking direction positioning ribs 127a. Accordingly, each battery cell 150 is also in contact with the stacking direction positioning rib 127a in a state of being in contact with the vertical positioning rib 127b, and thus the stacking direction positioning rib 127a and the vertical positioning rib in both the vertical direction and the stacking direction. The function of positioning by 127b is exhibited.

  The outer peripheral frame 121 has an engagement insertion portion 121e having a predetermined height over the entire circumference. The engagement insertion portion 121e is thinner than other portions of the outer peripheral frame 121. Therefore, the outer surface of the outer peripheral frame 121 has an engagement insertion portion 121e that is thinner than other portions of the outer peripheral frame 121. It is depressed. As shown in FIG. 11B, the engaging insertion portion 121 e is inserted inside the lower case 110 on the opening 113 side of the lower case 110 when the cell holder 120 is engaged with the lower case 110.

  In each of the side surfaces 121a, 121b, 121c, and 121d, the engagement insertion portion 121e includes three engagement claws 128 at the center and in the vicinity of both ends. The engagement claw 128 is provided at a position corresponding to the engagement hole 115 of the lower case 110. When the cell holder 120 and the lower case 110 are engaged, the engagement claw 128 of the cell holder 120 is fitted into the engagement hole 115 of the lower case 110 to be engaged, whereby the cell holder 120 and the lower case 110 are engaged. Combined. The positions and quantities of the engagement holes 115 and the engagement claws 128 are not limited to the examples shown in the present embodiment, and can be determined as appropriate positions and quantities.

  The outer peripheral frame 121 includes an engagement hole 129a on the upper surface side of the side surfaces 121a and 121c and in the vicinity of the screw hole 123b. The engagement hole 129a is provided so as to protrude outward from the outer peripheral frame 121, and is a substantially rectangular hole when viewed from above. The engagement hole 129a is used when the cell holder 120 and the auxiliary machine base 200 are assembled.

  Further, the outer peripheral frame 121 includes an engagement hole 129b on the upper surface side near the center of each of the side surfaces 121a, 121b, 121c and 121d. The engagement hole 129b is provided so as to protrude outward from the outer peripheral frame 121, and is a substantially rectangular hole in a top view. The engagement hole 129b is used when the cell holder 120 and the upper case are assembled. Note that the engagement hole 129b is not necessarily provided near the center of each of the side surfaces 121a, 121b, 121c, and 121d, and may be provided at any position as long as the upper case described later can be engaged. It may be.

  Here, the assembly of the battery module group will be described. First, with the cell holder 120 turned upside down, an adhesive is applied to the lower surface side of the holding lid 122 of the cell holder 120 and does not interfere with the openings 124a and 124b. The region that does not interfere with the opening 124a and the opening 124b is a region where the adhesive does not flow into the opening 124a and the opening 124b. For example, among the side surfaces formed by the vertical positioning ribs 127b, the region faces the opening 124a and the opening 124b. There is no side. Moreover, the area | region which does not interfere with the opening 124a and the opening 124b is the surrounding area | region formed in the lower surface side of the holding | maintenance lid | cover 122, for example by being surrounded by the wall surface which includes the vertical direction positioning rib 127b at least in part. For example, the covering region 122c corresponds to a surrounding region surrounded by the stacking direction positioning rib 127a, the vertical positioning rib 127b, and the side surfaces 121a, 121b, 121c, and 121d. In the present embodiment, the adhesive is applied to the entire region surrounded by the stacking direction positioning ribs 127a, the vertical positioning ribs 127b, and the side surfaces 121a, 121b, 121c, and 121d that define the covering region 122c. Thereby, the adhesive area between the cell holder 120 and the battery cell 150 is compared with the case where the adhesive is applied only to the side surface not formed facing the opening 124a and the opening 124b among the side surfaces formed by the vertical positioning ribs 127b. Is further increased, so that the cell holder 120 and the battery cell 150 are more strongly bonded to each other. The adhesive is an arbitrary adhesive capable of bonding the battery cell 150, the lower case 110, and the cell holder 120. For example, an epoxy adhesive can be used.

  Then, the battery cell 150 is inserted into the lower surface side of the holding lid 122 of the cell holder 120 according to the stacking direction positioning rib 127a with the cap surface 151 of the battery cell 150 facing downward. At this time, it is preferable to press the battery cell 150 against the cell holder 120 so that the cap surface 151 of the battery cell 150 is in contact with all the vertical positioning ribs 127b.

  Next, an adhesive is applied to the bottom surface 111 of the lower case 110. The adhesive is preferably applied along the support rib 116b so that the battery cell 150 and the bottom surface 111 are easily bonded in the space 110a. The adhesive may be applied to the surrounding area formed on the bottom surface 111 by being surrounded by a wall surface including at least a part of the support rib 116b. In the present embodiment, the adhesive is applied to the entire region surrounded by the two support ribs 116b and the side surfaces 112b and 112d as the surrounding region. As a result, the adhesive area between the lower case 110 and the battery cell 150 is further increased as compared with the case where the adhesive is applied only along the support rib 116b, and thus the lower case 110 and the battery cell 150 are more strongly bonded. It becomes easy to be done.

  Then, in a state where the lower case 110 to which the adhesive is applied is turned upside down, the lower case 110 is engaged with the cell holder 120 so as to cover the cell holder 120 into which the battery cell 150 is inserted. At this time, as shown in FIGS. 11A and 11B, the engagement claw 128 of the cell holder 120 is engaged with the engagement hole 115 of the lower case 110. An example of a state in which the cell holder 120 and the lower case 110 are engaged is shown in FIG.

  10 shows a surface of the battery cell 150 that contacts the bottom surface 111 when the battery cell 150 is inserted into the lower case 110 and a surface that contacts the holding lid 122 when the cell holder 120 holds the battery cell 150 from the upper surface side. It is a figure which shows typically the adhesion position when an adhesive agent is applied to (that is, cap surface 151). FIG. 10 is a cross-sectional view taken along the line AA in FIG. 8 and particularly shows a central battery cell 150 among the five stacked battery cells 150. Moreover, in FIG. 10, the area | region where an adhesive agent is apply | coated is shown with the hatching. In this case, as shown in FIG. 10, the battery cell 150 is applied between the two vertical positioning ribs 127b or the vertical positioning ribs 127b and the side surfaces in a cross-sectional view. The cell holder 120 is bonded with the adhesive. Further, the battery cell 150 is bonded to the lower case 110 with an adhesive applied between the two support ribs 166b in a cross-sectional view.

  As shown in FIG. 10, the vertical position of the battery cell 150 is determined by the position where the cap surface 151 of the battery cell 150 contacts the vertical positioning rib 127b. Since the plurality of vertical positioning ribs 127b have the same height, the positive terminal 152 and the negative terminal 153 are uniformly exposed from the opening 124a.

  In addition, what is apply | coated between the battery cell 150 and the bottom face 111 of the lower case 110 is not restricted to an adhesive agent. Another filler may be applied between the battery cell 150 and the bottom surface 111. The filler is particularly preferably elastic. By applying an elastic filler between the battery cell 150 and the bottom surface 111, the filler absorbs vibration generated when the vehicle including the assembled battery 100 travels, so that vibration is hardly transmitted to the battery cell 150.

  Next, the inter-cell bus bar 160, the total plus terminal bus bar 164, and the total minus terminal bus bar 165 are attached to each terminal of the battery cell 150 exposed from the opening 124a of the holding lid 122 by bead welding, and the LBC 140 is attached to the holding lid 122. Thus, the assembly of the battery module group is completed. At this time, since the positive electrode terminal 152 and the negative electrode terminal 153 of the battery cell 150 are uniformly exposed from the opening 124a as described above, stress is applied to the inter-cell bus bar 160 attached to the positive electrode terminal 152 and the negative electrode terminal 153 by bead welding. Therefore, the safety of the assembled battery 100 is increased. Note that, as described above, the LBC 140 is attached to the holding lid 122 by, for example, screwing.

  Next, the auxiliary machine module group of the assembled battery 100 according to the present embodiment will be described. The auxiliary equipment module group electrically connects the auxiliary equipment base 200, the MOSFET 210, the relay 220, the current sensor 230 and the fusible link 240 arranged on the auxiliary equipment base 200, and each component arranged on the auxiliary equipment base 200. It is configured by assembling a copper bus bar for connection to the cable.

  The auxiliary machine base 200 has four side surfaces 200a, 200b, 200c and 200d, and a placement surface 201. The four side surfaces 200a, 200b, 200c, and 200d are the four side surfaces 112a, 112b, 112c, and 112d (and the four side surfaces of the cell holder 120) of the lower case 110, respectively, in a state where the auxiliary machine base 200 is assembled to the battery module group. 121a, 121b, 121c and 121d).

  On the mounting surface 201, a current sensor 230 is mounted near the side surface 200a, a MOSFET 210 is mounted near the side surface 200b, a relay 220 is mounted near the side surface 200c, and a fusible link 240 is mounted near the side surface 200d. . As shown in FIG. 12, unevenness is formed on the mounting surface 201 according to the position where the MOSFET 210, the relay 220, the current sensor 230 and the fusible link 240 are mounted. The mounting surface 201 has higher rigidity due to the unevenness than when there is no unevenness.

  In the present embodiment, as shown in FIG. 12, the unevenness of the mounting surface 201 includes an area 201c on the mounting surface 201 where the relay 220 is mounted, an area 201a where the current sensor 230 is mounted, and a MOSFET 210. It is formed so as to be at a higher position when the assembled battery 100 is assembled as compared to the area 201b to be placed and the area 201d to which the fusible link 240 is placed. Further, the unevenness of the mounting surface 201 is formed so that the region 201d where the fusible link 240 is mounted is at a higher position when the assembled battery 100 is assembled than the regions 201a and 201b. Yes. That is, the unevenness of the placement surface 201 is formed such that the region 201a where the current sensor 230 is placed is at a lower position than the region 201c and the region 201d. Since the mounting surface 201 has such irregularities, the fusible link 240 is disposed at a position lower than the relay 220 in the auxiliary machine base 200, and the current sensor 230 thicker than the fusible link 240 is also connected to the relay 220. Can be arranged at a lower position.

  The current sensor 230, the MOSFET 210, the relay 220, and the fusible link 240 are respectively formed by standing walls formed by unevenness of the mounting surface 201 or ribs 202 formed on the mounting surface 201 in the regions 201a, 201b, 201c, and 201d. Is positioned.

  In the present embodiment, for example, as shown in FIGS. 12 and 14, the region 201 c is partially surrounded by a rib 202. That is, the relay 220 is positioned by the rib 202. The rib 202 also has a function of preventing rotation when the relay 220 is fixed to the auxiliary machine base 200 with the nut 290. The rib 202 also has an insulating function for preventing contact between copper bus bars, which will be described later.

  Further, the MOSFET 210, the relay 220, and the fusible link 240 are positioned by standing walls formed in parts around the areas 201a, 201b, and 201d, respectively. The standing wall on the mounting surface 201 also has a function of preventing rotation when the MOSFET 210, the relay 220, and the fusible link 240 are fixed to the auxiliary machine base 200 with the nut 290.

  The auxiliary machine base 200 includes a plurality of upward studs 203 on the mounting surface 201. The stud 203 is used to electrically connect the battery cells 150 of the battery module group, the MOSFET 210, the relay 220, the current sensor 230, and the fusible link 240 to each other. Further, the SSG terminal 250, the LOAD terminal 260, and the GND terminal 270 also extend upward from the placement surface 201 and function as studs.

  Each stud 203, the SSG terminal 250, the LOAD terminal 260, and the GND terminal 270 are provided at an appropriate height on the mounting surface 201 having unevenness. For example, each stud 203 has a height matching the terminals of the current sensor 230, the MOSFET 210, the relay 220, and the fusible link 240 placed on each of the regions 201 a, 201 b, 201 c, and 201 d on the placement surface 201. Provided. That is, the diameter of each stud 203 is sized according to the connection opening provided in each terminal of the current sensor 230, MOSFET 210, relay 220, and fusible link 240, and the current sensor 230, MOSFET 210, relay 220. The fusible link 240 is attached to the accessory base 200 by passing the stud 203 from the upper surface side to the terminal connection opening. Thus, by making the direction of each stud 203 upward, it is easy to attach each part to the auxiliary machine base 200, and thus the productivity of the auxiliary machine module and the assembled battery 100 is improved.

  In the present embodiment, the GND terminal 270 is provided at a position lower than the SSG terminal 250 and the LOAD terminal 260. In this way, by changing the height of the GND terminal 270, the SSG terminal 250, and the LOAD terminal 260, the GND terminal 270 can be identified more easily, thereby preventing erroneous wiring when the assembled battery 100 is mounted on a vehicle. It becomes easy.

  Here, wiring of each component using a copper bus bar on the auxiliary machine base 200 will be described. As shown in FIGS. 14 and 15, the copper bus bars 280 to 284 have various shapes according to the positions where they are arranged along the unevenness of the mounting surface 201 of the auxiliary machine base 200.

  Terminal 240 b of fusible link 240 is electrically connected to terminal 230 a of current sensor 230 via copper bus bar 280. The other terminal 230 b of the current sensor 230 is electrically connected to the terminal 220 a of the relay 220 via the copper bus bar 281. The other terminal 220 b of the relay 220 is electrically connected to the terminal 210 a of the MOSFET 210 via the copper bus bar 282. The other terminal 220 b of the relay 220 is further electrically connected to the SSG terminal 250 via the copper bus bars 282 and 283. The terminal 210 b of the MOSFET 210 is electrically connected to the LOAD terminal 260 via the copper bus bar 284.

  The terminal 240a of the fusible link 240 is connected to a total plus copper bus bar 285 for electrical connection to the total plus terminal bus bar 164 of the battery module group. The GND terminal 270 is connected with a total minus copper bus bar 286 for electrically connecting to the total minus terminal bus bar 165 of the battery module group. The total plus copper bus bar 285 and the total minus copper bus bar 286 extend to the lower surface side along the side surfaces 200b and 200d, respectively, and the tips of the total plus copper bus bar 286 and the auxiliary base 200 and the cell holder 120 are assembled to the total plus terminal, respectively. Contact with the bus bar 164 and the total negative terminal bus bar 165 ensures electrical connection. The total plus copper bus bar 285 and the total minus copper bus bar 286 are respectively screw holes at positions corresponding to the screw holes 123b provided in the cell holder 120 in a state where the auxiliary machine base 200 and the cell holder 120 are assembled at the tips. 285a and 286a.

  The copper bus bars 280 to 284 and the total plus copper bus bar 285 are fixed to the auxiliary machine base 200 together with the MOSFET 210, the relay 220, the current sensor 230 and the fusible link 240 by a nut 290 screwed to the stud 203 from the upper surface side. . The relay 220 can also be attached to the auxiliary machine base 200 by passing an opening 221 provided at a position different from the terminals 220a and 220b through the stud 203 and screwing the nut 290 into the stud 203 from the upper surface side. Fixed.

  Note that, as described above, the copper bus bars are arranged so as not to contact each other by the ribs 202 provided on the auxiliary machine base 200. Moreover, the partition 222 provided in the terminal 220a and the terminal 220b of the relay 220 also has a function of insulating the copper bus bars so that they do not contact each other.

  The auxiliary machine pedestal 200 includes a screw hole forming part 204 having screw holes 204a for fixing the cell holder 120 and the auxiliary machine pedestal 200 by screwing at the ends of the side surfaces 200b and 200d. The screw hole 204a is provided at a position corresponding to the screw hole 123a provided in the cell holder 120 in a state where the cell holder 120 and the auxiliary machine base 200 are assembled.

  The auxiliary machine base 200 includes engagement claws 205 in the vicinity of the stud 203 to which the total plus copper bus bar 285 on the side surface 200a is attached and in the vicinity of the GND terminal 270 to which the total minus copper bus bar 286 on the side surface 200c is attached. The engagement claw 205 is provided at a position corresponding to the engagement hole 129a in a state where the cell holder 120 and the auxiliary machine base 200 are assembled. The engaging claw 205 extends from the outside of the side surfaces 200a and 200c toward the lower surface, and the front end of the engaging claw 205 has a wedge shape when viewed from the side. When the tip of the engagement claw 205 is fitted into the engagement hole 129a, the engagement claw 205 and the engagement hole 129a are engaged.

  Here, the assembly of the accessory module group will be described. In the assembly of the accessory module group, first, each component (ie, MOSFET 210, relay 220, current sensor 230, fusible link 240) and copper bus bar (ie, copper bus bar 280 to 284, total plus copper bus bar 285, and total minus copper). The bus bar 286) is disposed through the stud 203, the SSG terminal 250, the LOAD terminal 260, and the GND terminal 270 of the mounting surface 201 of the auxiliary machine base 200. Then, the auxiliary machine module group is assembled by screwing the nut 290 into the stud 203, the SSG terminal 250, the LOAD terminal 260, and the GND terminal 270 from the upper surface side.

  Next, the upper case will be described. As shown in FIG. 16, the upper case 300 has three openings 310a and 310b for exposing the SSG terminal 250, the LOAD terminal 260, and the GND terminal 270 from the upper case 300 when the assembled battery 100 is assembled. And 310c.

  Further, the upper case 300 includes engagement claws 320 for engaging with the cell holder 120 on the lower surfaces of the four side surfaces. The engagement claw 320 is provided at a position corresponding to the engagement hole 129b in a state where the cell holder 120 and the upper case 300 are assembled. The engaging claw 320 extends in the lower surface direction from the outer side of each side surface, and the front end portion of the engaging claw 320 has a wedge shape in a side view. When the tip of the engagement claw 320 is fitted into the engagement hole 129b, the engagement claw 320 and the engagement hole 129b are engaged.

  Further, the upper case 300 includes a bus bar protection unit 330 for protecting the total plus copper bus bar 285 and the total minus copper bus bar 286 in a state where the cell holder 120 and the upper case 300 are assembled.

  Next, assembly of the assembled battery 100 as a whole will be described. First, assembly of the battery module group and the accessory module group will be described. The assembly of the battery module group and the accessory module group is realized by the assembly of the cell holder 120 and the accessory base 200.

  The cell holder 120 and the auxiliary machine base 200 are assembled by fitting the engaging claws 205 into the engaging holes 129a and engaging them. In addition, the cell holder 120 and the auxiliary machine pedestal 200 are configured such that, in a state where the auxiliary machine pedestal 200 is placed on the cell holder 120, the bolt 340 is screwed into the screw hole 285a or the screw hole 286a from the outside of the side surfaces 200b and 200d It is assembled by passing through the hole 166a and screwed into the screw hole 123b. That is, the cell holder 120 and the auxiliary machine base 200 are indirectly assembled by the bolt 340 via the total plus copper bus bar 285 and the total minus copper bus bar 286. At this time, the support portion 206 provided along the total plus copper bus bar 285 and the total minus copper bus bar 286 has a function of preventing rotation.

  In this way, by performing assembly by both means of assembly by engagement and assembly by the bolt 340, a more robust assembly can be realized as compared with the case of assembly by one side.

  In addition, the cell holder 120 and the auxiliary machine base 200 are formed in such a manner that, in the state where the cell holder 120 is placed on the auxiliary machine base 200, as shown in FIG. It is assembled by screwing to 123a.

  Since the battery module group and the auxiliary machine module group of the present embodiment are assembled as described above, the battery module group and the auxiliary machine module group are fixed at the four corners of the substantially rectangular auxiliary machine base 200 in a top view. . Thereby, a robust assembly can be realized.

  Next, assembly of the upper case 300 will be described. The upper case 300 is engaged with the cell holder 120 by engaging the engagement claw 320 with the engagement hole 129 b of the cell holder 120. Thus, the assembly of the assembled battery 100 is completed by engaging the upper case 300 with the cell holder 120.

  Thus, according to the assembled battery 100 according to the present embodiment, the cell holder 120 includes the vertical positioning ribs 127b having a certain height on the lower surface side of the holding lid 122. Therefore, when the cap surface 151 of the battery cell 150 contacts the vertical positioning rib 127b, the vertical position of the battery cell 150 with respect to the holding lid 122 of the cell holder 120 is determined. Therefore, even when the inter-cell bus bar 160 is attached to the electrode terminal by bead welding, the inter-cell bus bar 160 is less likely to be stressed, and the safety of the assembled battery 100 is increased.

  Moreover, according to the assembled battery 100 which concerns on this embodiment, the several vertical direction positioning rib 127b has the same height, respectively. Therefore, the position of the battery cell 150 in contact with each vertical positioning rib 127b is uniquely determined regardless of the vertical positioning rib 127b in contact.

  Moreover, according to the assembled battery 100 which concerns on this embodiment, it has the opening 124a which exposes an electrode terminal to the upper surface side, and is equipped with the up-down direction positioning rib 127b in the position along the opening 124a. Thereby, the accuracy of the vertical positioning of the electrode terminal exposed from the opening 124a is improved.

  Moreover, according to the assembled battery 100 which concerns on this embodiment, the battery cell 150 and the cell holder 120 are adhere | attached with the adhesive agent applied along the side surface which does not face the opening 124a among the up-down direction positioning ribs 127b. . Thereby, it becomes easy to prevent the adhesive from flowing into the opening 124 a while realizing the adhesion state between the battery cell 150 and the cell holder 120. In particular, the battery cell 150 and the cell holder 120 are bonded by an adhesive applied to a surrounding region formed on the lower surface side of the holding lid 122 by being surrounded by a wall surface including at least a part of the vertical positioning rib 127b. In this case, since the bonding area between the battery cell 150 and the cell holder 120 increases, the battery cell 150 and the cell holder 120 can be bonded more strongly.

  Further, according to the assembled battery 100 according to the present embodiment, the wall surface is configured to include at least one of the stacking direction positioning rib 127 a that defines the direction of the battery cell 150 accommodated in the lower case 110 and the side surface of the cell holder 120. The Thereby, the mechanism with which the cell holder 120 is equipped can be used together with a wall surface, and each mechanism can be utilized efficiently.

  Further, according to the assembled battery 100 according to the present embodiment, the lower case 110 includes the support rib 116b on the bottom surface 111, and is formed on the bottom surface 111 by being surrounded by a wall surface including at least a part of the support rib 116b. With filler in the surrounding area. Thereby, since the lower case 110 and the battery cell 150 do not contact directly but contact via a filler, the contact state according to the property of the filler is implement | achieved. When the filler is an adhesive, an adhesion state between the battery cell 150 and the lower case 110 is realized. Further, when the filler is an elastic agent, the elastic agent absorbs vibration generated when the vehicle including the assembled battery 100 travels, so that vibration is not easily transmitted to the battery cell 150.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions included in each means can be rearranged so as not to be logically contradictory, and a plurality of means can be combined into one or divided.

  For example, in the above-described embodiment, the vertical positioning rib 127b has been described as being disposed along the opening 124a and the opening 124b in a direction perpendicular to the stacking direction positioning rib 127a. However, the vertical positioning rib 127b is disposed in this direction. Not limited to. The vertical positioning ribs 127b may be disposed at any position where the battery cell 150 can be positioned in the vertical direction. For example, the vertical positioning rib 127b may be provided on the lower surface side of the holding lid 122 so as to form a rectangular shape when viewed from below. In this case, the vertical positioning ribs 127 b provided in a rectangular shape form an encircling region of the cell holder 120. That is, in this case, the adhesive between the battery cell 150 and the cell holder 120 is realized by applying an adhesive to the wall surface of the vertical positioning rib 127b provided in a rectangular shape.

100 assembled battery 110 lower case 110a space 111 bottom surface 112, 112a, 112b, 112c, 112d, 121a, 121b, 121c, 121d, 200a, 200b, 200c, 200d side surface 113, 124a, 124b, 221, 310a, 310b, 310c opening 114 Mounting mechanism 115, 129a, 129b Engagement hole 116a Guide 116b Support rib 120 Cell holder 121 Outer frame 121e Engagement insertion part 122 Holding lid 122a Frame part 122b Opening area 122c Covering area 123, 126, 204 Screw hole forming part 123a, 123b 126a, 163a, 166a, 204a, 285a, 286a Screw hole 123c Bus bar support part 125 Bead 127a Lamination direction positioning rib 127b Vertical direction positioning Bed 128,205,320 engagement claw 130 of the first secondary battery 140 LBC (battery controller)
150 battery cell 151 cap surface 152 positive terminal 153 negative terminal 154 safety valve 160 inter-cell bus bar 161 convex part 162 terminal connection part 162a welding opening 163 voltage sensor mounting terminal 164 total positive terminal bus bar 165 total negative terminal bus bar 166 external connection part 200 complement Machine base 201 Placement surface 201a, 201b, 201c, 201d Area 202 Rib 203 Stud 206 Support part 210 MOSFET
210a, 220a, 230a, 240a, 210b, 220b, 230b, 240b Terminal 220 Relay 222 Bulkhead 230 Current sensor 240 Fusible link 250 SSG terminal 260 LOAD terminal 270 GND terminal 280, 281, 282, 283, 284 Copper bus bar 285 Total plus Copper bus bar 286 Total minus copper bus bar 290 Nut 300 Upper case 330 Bus bar protection unit 340, 350 volts 400 Power supply system 410 Alternator 420 Starter 430 Second secondary battery 440 Load 450 Switch 460 Control unit

Claims (10)

A battery cell having an electrode terminal on the cap surface;
A lower case capable of accommodating the battery cell;
A cell holder for holding the battery cell in the lower case on the cap surface by engaging with the lower case;
The cell holder includes a holding lid that holds the battery cell, and a vertical positioning rib having a certain height on a lower surface side of the holding lid. The cell holder includes a plurality of the vertical positioning ribs,
The assembled battery according to claim 1, wherein each of the plurality of vertical positioning ribs has the same height.   The assembled battery according to claim 1, wherein the cell holder has an opening that exposes the electrode terminal to the upper surface side, and the vertical positioning rib is provided at a position along the opening.   The assembled battery according to claim 3, wherein the battery cell and the cell holder are bonded by an adhesive applied along a side surface of the vertical positioning rib that does not face the opening.   The battery cell and the cell holder are bonded by an adhesive applied to the surrounding area formed on the lower surface side of the holding lid by being surrounded by a wall surface including at least a part of the vertical positioning rib. The assembled battery according to claim 3.   The assembled battery according to claim 5, wherein the wall surface includes at least one of a stacking direction positioning rib that defines a direction of the battery cell accommodated in the lower case and a side surface of the cell holder. The lower case includes a support rib for supporting the battery cell from the bottom surface side in a state where the battery cell is accommodated on the bottom surface.
The assembled battery according to any one of claims 1 to 6, further comprising a filler in a surrounding region formed on the bottom surface by being surrounded by a second wall surface including at least a part of the support rib.   The assembled battery according to claim 7, wherein the filler is an adhesive.   The assembled battery according to claim 7, wherein the filler is an elastic agent.   A power supply device comprising the assembled battery according to any one of claims 1 to 9.