JP2016046233A - Battery system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a battery system compact while ensuring the insulation distance of an end plate and a square battery.SOLUTION: A battery system includes a battery block 2 laminating a plurality of square batteries 1 in the thickness direction, conductive end plates 4 arranged at the opposite ends of the battery block 2, a conductive restraint material 5 arranged on the opposite side faces of the battery block 2, and connected with the end plate 4, and an end face spacer 3 for insulating the end plate 4 and the battery block 2. The end plate 4 has a protrusion 4D protruding from a side face 4A facing the restraint material 5, and a step 4C provided on the side face 4A contiguously to the protrusion 4D. The protrusion 4D arranges the restraint material 5 separately from the step 4C, to form a space 4E between the step 4C and the restraint material 5. The end face spacer 3 has a plate 3X located between the end plate 4 and the battery block 2, and an insulating sidewall 3A arranged in the space 4E formed between the step 4C and the restraint material 5, and extending along the step 4C.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a battery system in which a plurality of rectangular batteries are stacked in the thickness direction, and more particularly to a battery system that is optimal as a power source for an electric vehicle or the like.

  A battery system has been developed in which a large number of prismatic batteries and insulating spacers are alternately stacked to form a battery block, end plates are arranged at both ends of the battery block, and the end plates are connected by a restraining material ( Patent Document 1). This battery system includes an end plate made of resin, and a restraint member is connected to a pair of end plates to restrain a square battery.

  Moreover, since a square battery is filled with a positive and negative electrode plate and an electrolyte solution in a conductive outer can, the outer can has a potential. Therefore, the restraining material needs to be insulated from the battery block. In the case where the outer can has a potential, the outer peripheral surface of the outer can can be covered with an insulating layer such as a heat-shrinkable tube, but the thin heat-shrinkable tube may be damaged when the rectangular battery comes into contact with the restraining material or the like.

  Therefore, in the battery system of Patent Document 1, an insulating wall interposed between the prismatic battery and the restraining material is provided in the spacer. According to this configuration, the rectangular battery and the restraining material can be insulated by the insulating wall. In particular, since the insulating wall is interposed between the prismatic battery and the restraint material, physical contact between the restraint material and the prismatic battery can be prevented.

  On the other hand, since the insulating wall does not cover the square battery in an airtight manner, it can be used in combination with an insulating layer such as a heat-shrinkable tube. Since this type of insulating layer is provided in close contact with the outer casing of the rectangular battery, it is possible to effectively prevent a short circuit through condensed water or the like.

JP 2010-157450 A

  In recent years, battery systems are required to be small and lightweight. For example, when used as a power source for an electric vehicle or the like, the weight and dimensions of the battery system affect the weight of the vehicle body and the space in the vehicle. In the battery system of Patent Document 1, a relatively large force is applied to the end plate. For this reason, it is necessary to provide a thick end plate so as not to break even with a large load.

  In order to reduce the size of the battery system of Patent Document 1, it is useful to form the end plate from metal. When the end plate is made of metal, the end plate can be made thinner due to the difference in material strength. In addition, since the metal end plate is less likely to deform than the resin end plate, the displacement of the restraint due to the deformation of the end plate and the contact between the restraint and the prismatic battery due to the displacement of the restraint are taken into consideration. There is no need. Therefore, the configuration of the insulating wall can be omitted, and the restraining material can be brought closer to the square battery than the configuration of Patent Document 1.

  On the other hand, when the end plate is made of metal, the rectangular battery needs to consider not only the restraining material but also the insulation with the end plate. In this type of battery system, an insulating end face spacer is provided between the end plate and the square battery. However, in order to reduce the size of the battery system, it is necessary to reduce the thickness of the end face spacer. Therefore, the insulation distance between the end plate and the square battery is shortened, and there is a possibility that a short circuit occurs due to condensed water or the like. In particular, since the terminal surface on which the positive and negative electrode terminals are provided cannot be provided with an insulating material such as a heat-shrinkable tube, there is a problem that the insulation distance between the end plate and the rectangular battery is short.

  The present invention has been made to solve such a problem, and its main object is to provide a technique capable of downsizing the battery system while ensuring an insulation distance between the end plate and the prismatic battery. There is to do.

  The battery system of the present invention includes a battery block 2 formed by stacking a plurality of rectangular batteries 1 in the thickness direction, conductive end plates 4 disposed at both ends of the battery block 2, and both side surfaces of the battery block 2. And a conductive restraint member 5 connected to the end plate 4 and an end face spacer 3 that insulates the end plate 4 and the battery block 2 from each other. The end plate 4 has a convex portion 4D protruding from the side surface 4A facing the restraint material 5 and a step portion 4C formed on the side surface 4A facing the restraint material 5 and provided adjacent to the convex portion 4D. ing. The convex portion 4D disposes the restraint material 5 away from the step portion 4C and forms a space 4E between the step portion 4C and the restraint material 5. The end surface spacer 3 is disposed in a plate portion 3X located between the end plate 4 and the battery block 2, and a space 4E formed between the step portion 4C and the restraining material 5, and extends along the step portion 4C. And an insulating side wall 3A.

  The battery system of the present invention is characterized in that the contact between the constraining material and the prismatic battery can be suppressed and the insulation distance between the end plate and the prismatic battery can be ensured without increasing the outer shape of the entire end plate. . This is because a convex portion and a step portion are formed on the surface of the end plate facing the restraining material. According to this configuration, when the convex portion comes into contact with the restraining material, the displacement of the restraining material in the direction approaching the rectangular battery can be restricted. In addition, a space is formed between the restraining material and the stepped portion, and an insulating distance between the end plate and the prismatic battery can be secured by disposing the insulating sidewall of the end face spacer in the formed space. That is, it is possible to form a space in which the insulating side walls that secure the insulating distance are arranged while the end plate is substantially the same as the outer shape of the rectangular battery.

It is a perspective view of the battery system concerning one embodiment of the present invention. It is a disassembled perspective view of the battery system shown in FIG. It is a disassembled perspective view which shows the laminated structure of a battery block. It is a disassembled perspective view which shows the laminated structure of an end plate and an end surface spacer. It is the disassembled perspective view seen from the end plate, the end surface spacer, and the back side. It is the perspective view which looked at the end surface spacer shown in FIG. 5 from the lower side. It is a principal part enlarged plan view of the battery system shown in FIG. It is the VII-VII sectional view taken on the line of the battery system shown in FIG.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment described below exemplifies a battery system for embodying the technical idea of the present invention, and the present invention does not specify the battery system as follows. Further, the present invention is not intended to limit the members shown in the claims to the members of the embodiments.

  The battery system shown in the following embodiments is mainly suitable for the power source of electric vehicles such as hybrid cars and plug-in hybrid cars that run on both the engine and motor, electric cars that run only on the motor, and electric motorcycles that run on the motor. It is. However, the battery system of the present invention can also be used for applications requiring high output other than electric vehicles.

  The battery system shown in FIGS. 1 and 2 includes a battery block 2 in which a plurality of rectangular batteries 1 are stacked in the thickness direction, and is disposed at both ends of the battery block 2 to press the rectangular batteries 1 in the stacking direction. A conductive end plate 4 fixed in a state, and a conductive restraining material 5 formed on both side surfaces of the battery block 2 and extending in the stacking direction of the rectangular battery 1 and having both ends connected to the end plate 4. And an end surface spacer 3 disposed between the end plate 4 and the battery block 2.

  As shown in FIG. 3, the prismatic battery 1 is a secondary battery that is wider than the thickness, in other words, thinner than the width, and is stacked in the thickness direction to form a battery block 2. The prismatic battery 1 is a lithium ion secondary battery. However, the prismatic battery 1 can be any rechargeable secondary battery such as a nickel metal hydride battery or a nickel cadmium battery. The prismatic battery 1 has positive and negative electrode plates placed in a sealed outer can and is further filled with an electrolytic solution so as to immerse the electrode plates. The outer can is formed by press-molding a metal plate such as aluminum or aluminum alloy into a square shape, and the opening is hermetically sealed with a sealing plate. The sealing plate is made of the same aluminum or aluminum alloy as the outer can and fixes the positive and negative electrode terminals 13 in an insulated state. This rectangular battery 1 is provided with positive and negative electrode terminals 13 with a sealing plate as a terminal surface 10. Furthermore, the prismatic battery 1 is provided with an insulating layer such as a heat shrinkable tube to cover the surface of the outer can. The heat-shrinkable tube is in close contact with the outer peripheral surface and the bottom surface excluding the terminal surface 10 to insulate the surface of the outer can.

  The prismatic battery 1 is a prismatic battery having a rectangular opposing surface located on both sides, and is laminated to form a battery block 2 so that both sides are opposed. The rectangular battery 1 has a rectangular outer peripheral surface as a terminal surface 10 on which positive and negative electrode terminals 13 are provided, the terminal surface 10 is arranged on the same plane, and a plurality of rectangular batteries 1 are stacked to form a battery block 2. It is said.

As shown in FIG. 3, the battery block 2 has an insulating spacer 15 sandwiched between the stacked rectangular batteries 1. The insulating spacer 15 insulates the adjacent rectangular batteries 1 more reliably. As shown in FIG. 3, the insulating spacer 15 can be stacked so that the adjacent rectangular batteries 1 are not displaced as a shape in which the rectangular batteries 1 are stacked on both surfaces and arranged in a fixed position. Furthermore, the insulating spacer 15 can be formed of an insulating plastic to insulate the adjacent rectangular batteries 1 . The battery block can cool the prismatic battery by disposing a cooling plate in a thermally coupled state on the bottom surface of the prismatic battery and forcibly cooling the cooling plate. Although not shown, the insulating spacer may be provided with a cooling gap for forcibly blowing cooling air. For example, a groove can be formed on the surface of the insulating spacer facing the rectangular battery, and a cooling gap can be formed between the insulating spacer and the rectangular battery. The square battery can be cooled by blowing cooling air into the cooling gap.

  In the battery block 2, a metal plate bus bar 14 is connected to the positive and negative electrode terminals 13 of the adjacent rectangular batteries 1, and the rectangular batteries 1 are connected in series with the bus bar 14. The bus bar 14 is provided with a through hole, the electrode terminal 13 is inserted into the through hole, and a nut 16 is screwed into a male screw provided in the electrode terminal 13 to be connected to the electrode terminal 13. However, although not shown, the bus bar can be welded to the electrode terminal by irradiating the boundary between the electrode terminal and the through hole with a laser beam. Further, a female screw hole can be provided in the electrode terminal, and a bus bar can be connected by screwing a set screw into the female screw hole.

  The battery system in which the adjacent rectangular batteries 1 are connected in series can increase the output voltage and increase the output. However, the battery system can increase the output current by connecting adjacent rectangular batteries 1 in parallel, and can increase the output voltage and output current by connecting them in series and in parallel.

  The battery block 2 has end plates 4 disposed on both end faces with an end face spacer 3 interposed therebetween. The end plate 4 is connected to a restraining material 5 to fix the stacked rectangular batteries 1 in a pressurized state. In the battery system of FIG. 2, the restraining material 5 is disposed on both side surfaces of the battery block 2. The restraining material 5 is made of a conductive metal plate or the like. The constraining material 5 in the figure is bent inward from the side surfaces 4 </ b> A on both sides of the end plate 4, and the bent portion 5 </ b> A is fixed to the outer surface of the end plate 4. The bent portion 5 </ b> A is fixed to the end plate 4 by screwing a set screw 19 penetrating the bent portion 5 </ b> A into the female screw hole 4 a of the end plate 4.

  The end plate 4 is made of a conductive metal such as aluminum or an aluminum alloy. The end plate 4 made of aluminum or aluminum alloy is manufactured by die casting or extrusion molding. The end plate 4 has the same quadrangle as the outer shape of the rectangular battery 1, and is provided with a convex portion 4 </ b> D that protrudes from the side surface 4 </ b> A facing the restraint material 5 toward the inner surface of the restraint material 5. The end plate 4 of FIGS. 4 and 5 is provided with rib-like convex portions 4D extending in the longitudinal direction (vertical direction in the drawing) on the side surfaces 4A on both sides. Further, the end plate 4 is formed on the side surface 4A facing the restraining material 5 and has a step portion 4C provided adjacent to the convex portion 4D. In the end plate 4, the constraining material 5 is disposed away from the stepped portion 4 </ b> C by the convex portion 4 </ b> D, and a space 4 </ b> E is formed between the stepped portion 4 </ b> C and the constraining material 5.

  As shown in FIGS. 4 to 8, the end surface spacer 3 includes a plate portion 3X disposed between the battery block 2 and the end plate 4, and the conductive end plate 4 is connected to the battery by the plate portion 3X. Insulate from block 2. The end surface spacer 3 is disposed in a space formed between the step portion 4C of the end plate 4 and the restraining material 5, and has an insulating side wall 3A extending along the step portion 4C. The insulating side wall 3A is a plate. It is connected to the part 3X. The end surface spacer 3 is formed by integrally molding an insulating plastic, and connects the insulating side wall 3A to the plate portion 3X. The plate portion 3X is sandwiched between the battery block 2 and the end plate 4, and the insulating side wall 3A is disposed on the side surface 4A of the end plate 4. Accordingly, the insulating side wall 3A is connected to the plate portion 3X at a right angle. The insulating side wall 3 </ b> A is disposed in the step 4 </ b> C of the side surface 4 </ b> A of the end plate 4 and is disposed in a space 4 </ b> E formed between the step 4 </ b> C and the restraining material 5.

  The end face spacer 3 shown in FIGS. 4 to 6 is provided with an insulating side wall 3A over substantially the entire upper and lower sides of both side edges of the plate portion 3X. The insulating side wall 3A is arranged on a step portion 4C formed over the entire upper and lower sides of the side surface 4A of the end plate 4 so that the insulating distance between the side surface of the prismatic battery 1 and the side surface 4A of the end plate 4 can be increased. However, the insulating side wall does not necessarily need to be provided over the entire upper and lower sides of the side surface of the end plate, and may be provided partially. For example, in a rectangular battery in which an outer can is covered with a heat-shrinkable tube and insulated, an insulating structure in the vicinity of a sealing plate serving as a terminal surface is important. Therefore, the end face spacer can also be provided with an insulating side wall only at the upper end on the terminal face side of the rectangular battery.

  Further, the end surface spacer 3 in FIGS. 4 to 6 and 8 includes a terminal surface cover portion 3C that covers the terminal surface 10 of the rectangular battery 1 and an outer peripheral cover portion 3B that covers the outer peripheral surface 4B on the upper surface of the end plate 4. Are connected to the upper edge of the plate portion 3X. Since the terminal surface cover portion 3C covers the terminal surface 10 on the upper surface of the prismatic battery 1 and the outer peripheral cover portion 3B covers the outer peripheral surface 4B on the upper surface of the end plate 4, the terminal surface cover portion 3C and the outer peripheral cover portion 3B Projecting in opposite directions to each other.

  The end surface spacer 3 in FIG. 6 is provided with a terminal surface cover portion 3C that protrudes toward the prismatic battery 1 over the entire upper edge of the plate portion 3X. The terminal surface cover portion 3C in the figure is provided extending to the insulating side wall 3A. Thus, the structure in which the terminal surface cover portion 3C is provided over the entire upper edge of the plate portion 3X can ensure the insulation distance between the end plate 4 and the battery block 2 and improve the insulation characteristics. This is because the surface distance from the exposed portion of the terminal surface 10 of the rectangular battery 1 to the outer peripheral surface 4 </ b> B can be increased along the surface of the end surface spacer 3. Further, the end surface spacer 3 in FIGS. 4 to 6 has an enlarged cover portion 3C ′ in which the protruding amount at the center portion of the terminal surface cover portion 3C is made larger than both side portions, and both end portions of the terminal surface cover portion 3C. In FIG. 2, a holder cover portion 3D that extends further upward and covers the holder 17 that supports the electrode terminal 13 is provided. As described above, the structure in which the protruding amount of the terminal surface cover portion 3C is increased to provide the enlarged cover portion 3C ′, or the holder cover portion 3D extended from the terminal surface cover portion 3C is provided with an end plate at these portions. Insulation characteristics can be further improved by lengthening the insulation distance between 4 and the square battery 1. Here, the enlarged cover portion 3C ′ formed at the center portion has a shape and a protruding amount so as not to block the gas discharge port 12 of the gas discharge valve 11 provided at the center portion of the terminal surface 10 of the rectangular battery 1. Adjusted. Furthermore, the holder cover portions 3D provided on both sides of the end surface spacer 3 are connected to the upper end portion of the insulating side wall 3A, and the strength of the end surface spacer 3 as a whole is improved by integrally forming these. .

  Further, the end face spacer 3 in FIG. 4 is an upper edge portion of the plate portion 3X, and is provided with an outer peripheral cover portion 3B that is separated from the center portion on both sides. The end face spacer 3 shown in the drawing partially has a plurality of outer peripheral cover portions 3B. In particular, the end face spacer 3 shown in the drawing is provided with an outer peripheral cover portion 3B facing the region where the above-described enlarged cover portion 3C 'and holder cover portion 3D are not provided. As shown in FIG. 8, this structure can increase the insulation distance between the end plate 4 and the prismatic battery 1 between the terminal surface cover portion 3C and the outer peripheral cover portion 3B, thereby improving the insulation characteristics. However, the end face spacer can be provided with an outer peripheral cover portion over the entire upper edge portion of the plate portion, or can be provided with one outer peripheral cover portion that covers the entire central portion. Further, the length and the protrusion amount of the outer peripheral cover portion can be variously adjusted in consideration of the insulation characteristics.

  As shown in FIGS. 4 to 7, the end plate 4 is provided with a step 4 </ b> C by providing a protrusion 4 </ b> D on a part of the side surface 4 </ b> A. Accordingly, the protrusion height (H) of the convex portion 4D is a difference in height from the step portion 4C. In the end plate 4, the insulating side wall 3A is disposed on the stepped portion 4C, and the restraint material 5 is brought into contact with the convex portion 4D to specify the position of the restraint material 5. Therefore, the protrusion height (H) of the convex portion 4D, that is, the height difference from the stepped portion 4C is set to be equal to or greater than the thickness of the insulating side wall 3A, preferably higher than the thickness of the insulating side wall 3A. The end plate 4 of FIG. 7 is provided with a convex portion 4D along the outer edge of the side surface 4A. This structure is characterized in that the insulation distance can be increased by widening the lateral width (W) of the insulating sidewall 3A. However, although not shown, the convex portion can be provided along the central portion of the side surface of the end plate, for example.

  The lateral width (T) including the convex portion 4D of the end plate 4 is larger than the lateral width (S) of the prismatic battery 1. Thereby, the side surface of the rectangular battery constituting the battery block is prevented from colliding more strongly than necessary with the inner surface of the restraining material 5 positioned by the convex portion 4D of the end plate 4. In this battery system, the rectangular battery 1 does not collide with the restraining material 5 to be deformed or damaged, so that the outer can of the square battery 1 and the restraining material 5 are electrically contacted to cause a short circuit. To prevent and improve safety. In particular, even if the rectangular battery 1 has a dimensional error in the square outer shape, it can be stably held at a fixed position without being damaged by being strongly collided with the restraint material 5.

  The battery system described above identifies the position of the restraining material 5 by bringing the inner surface of the restraining material 5 into contact with the convex portion 4 </ b> D of the end plate 4. Although not shown, if the restraining material is connected to the end plate across the insulating side wall, the plastic insulating side wall is crushed by the restraining material and deformed. When the insulating side wall is crushed, the position of the restraining material is displaced, and the side surface of the rectangular battery is pressed to be deformed or damaged. In the battery system shown in FIG. 7, the position of the restraint member 5 is specified by the convex portion 4 </ b> D of the end plate 4, and the insulating side wall 3 </ b> A is disposed in the space 4 </ b> E formed between the stepped portion 4 </ b> C and the restraint member 5. Therefore, the restraint material 5 does not crush the insulating side wall 3 </ b> A and is not displaced, and deformation or damage of the rectangular battery 1 due to the displacement of the restraint material 5 is prevented.

  The battery system of the present invention is optimally used for a power supply device that supplies electric power to a motor of a vehicle that requires a large amount of power, or a power storage device that stores natural energy or midnight power.

DESCRIPTION OF SYMBOLS 1 ... Rectangular battery 2 ... Battery block 3 ... End surface spacer 3X ... Plate part 3A ... Insulating side wall 3B ... Outer peripheral cover part 3C ... Terminal surface cover part 3C '... Enlarged cover part 3D ... Holder cover part 4 ... End plate 4A ... Side face 4B ... outer peripheral surface 4C ... stepped portion 4D ... convex portion 4E ... space 4a ... female screw hole 5 ... constraining material 5A ... bent portion 10 ... terminal surface 11 ... gas exhaust valve 12 ... gas exhaust port 13 ... electrode terminal 14 ... bus bar 15 ... Insulating spacer 16 ... Nut 17 ... Holder 19 ... Set screw

Claims (4)

A battery block formed by laminating a plurality of rectangular batteries in the thickness direction;
Conductive end plates disposed at both ends of the battery block;
Conductive restraint material disposed on both side surfaces of the battery block and connected to the end plate;
An end face spacer for insulating the end plate and the battery block;
The end plate is
A convex portion protruding from a side surface facing the restraint material;
A step portion formed on a side surface facing the restraining material and provided adjacent to the convex portion;
The convex portion is arranged to dispose the restraint material away from the step portion, and forms a space between the step portion and the restraint material,
The end face spacer is
A plate portion located between the end plate and the battery block;
A battery system comprising: an insulating sidewall disposed in the space formed between the stepped portion and the restraining material and extending along the stepped portion. The battery system according to claim 1,
The plurality of prismatic batteries each have a terminal surface provided with positive and negative electrode terminals, and the terminal surfaces are laminated in the same plane,
The battery system according to claim 1, wherein the end surface spacer is provided by connecting a terminal surface cover portion that covers a terminal surface of the rectangular battery to the plate portion. The battery system according to claim 1 or 2,
The plurality of prismatic batteries each have a terminal surface provided with positive and negative electrode terminals, and the terminal surfaces are laminated in the same plane,
The end plate has an outer peripheral surface disposed in a plane parallel to the terminal surface,
The battery system according to claim 1, wherein the end surface spacer is provided by connecting an outer peripheral cover portion that covers an outer peripheral surface of the end plate to the plate portion. A battery system according to any one of claims 1 to 3,
The battery system, wherein the convex portion is provided along an outer edge of a side surface of the end plate.

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