JP2015026424A - Power storage module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage module which improves heat radiation performance and prevents the deterioration.SOLUTION: A power storage module 10 includes: a lamination body 20 formed by laminating power storage units 21, each of which includes a power storage element 22 and a heat transfer member 30 on which the power storage element 22 is placed, the heat transfer member 30 conducting heat generated by the power storage element 22 to the exterior; and a case 11 in which the lamination body 20 is stored. The multiple power storage units 21 respectively have elastic members 50 made of an elastic material.

Description

  The present invention relates to a power storage module.

  Secondary batteries such as lithium ion batteries and nickel metal hydride batteries are known as examples of power storage elements in which power storage elements are housed. Secondary batteries, such as a lithium ion battery, comprise an electrical storage module by connecting two or more. As such a power storage module, for example, the one described in Patent Document 1 is known.

JP 2006-210312 A

  Patent Document 1 discloses a power storage module in which a plurality of power storage elements in which positive and negative lead terminals protrude from end portions are stacked. In this power storage module, adjacent power storage elements are connected in series by connecting lead terminals having different polarities (reverse polarities).

  In the power storage module described in Patent Document 1, in order to prevent a short circuit between the lead terminals, an insulating plate is disposed on both sides of the lead terminals and sandwiched. Therefore, in this power storage module, the power storage elements adjacent in the stacking direction are arranged apart from each other by the thickness dimension of the insulating plate.

  However, in a power storage module in which a plurality of power storage elements are stacked like this power storage module, the power storage elements may become hot due to repeated charge and discharge. When the power storage element becomes high temperature, there is a concern that the performance is lowered.

  This invention is completed based on the above situations, Comprising: It aims at providing the electrical storage module which improved heat dissipation.

  In a power storage module, as a method for improving heat dissipation, for example, it is conceivable to form a power storage module by stacking a plurality of power storage units each having a power storage element placed on a heat transfer member made of a heat conductive material. .

  Here, since there are manufacturing tolerances in the thickness dimension in the plurality of energy storage elements constituting the energy storage module, when the interval between the energy storage units adjacent in the stacking direction is set according to the energy storage element having the largest thickness dimension, the energy storage element And a gap between the power storage element and the heat transfer member of the power storage unit adjacent to the power storage element. In such a case, the contact area with the heat transfer member is reduced, so that sufficient heat dissipation cannot be obtained, or the stack formed by stacking the power storage units is not subjected to sufficient pressure, and the power storage module deteriorates. There is a concern about the progress.

  A structure in which a manufacturing unit of a power storage unit is absorbed while applying sufficient pressing force to the power storage module, and a multilayer body in which a plurality of power storage units each having a power storage element placed on a heat transfer member are stacked, and a case that houses the stack It is conceivable to arrange one elastic member between the two. However, in such a configuration, an elastic member having a large thickness dimension capable of absorbing the manufacturing tolerance of the thickness dimension of the plurality of power storage elements needs to be disposed between the laminate and the case, and thus is generated from the laminate. There was concern that it would be difficult to conduct heat to the case.

  As a result of intensive investigations in view of the above-mentioned circumstances, the plurality of power storage units each have an elastic member so that heat generated in the power storage element can be easily conducted and sufficient power is applied to the power storage module. I got the knowledge that I can do it. The present invention is based on such novel findings.

  That is, the present invention provides a stacked body in which a plurality of power storage units each including a power storage element and a heat transfer member that has the power storage element mounted thereon and conducts heat generated from the power storage element to the outside, and the stacked body A plurality of power storage units each having an elastic member made of an elastic material.

  According to the present invention, in each power storage unit, since the elastic member absorbs the variation in the thickness dimension of the power storage element, the elastic member having a smaller thickness dimension than the case where one elastic member is disposed between the laminate and the case. However, the variation in the thickness dimension of the electricity storage element can be sufficiently absorbed, and the heat generated from the laminate can be sufficiently dissipated. As a result, according to the present invention, a power storage module with improved heat dissipation can be provided.

  Further, according to the present invention, since the variation in the thickness dimension is absorbed in each power storage unit, a sufficient pressing force can be applied to the power storage module.

The present invention may have the following configuration.
The elastic member may be arranged between the power storage element and the heat transfer member of the power storage unit adjacent to the power storage element.
With such a configuration, the power storage element can be directly placed on the heat transfer member, and the contact area between the heat transfer member and the power storage element can be increased, so that heat dissipation is improved.

  ADVANTAGE OF THE INVENTION According to this invention, the electrical storage module which improved heat dissipation can be provided.

The top view of the electrical storage module of Embodiment 1 Sectional drawing in the AA line of FIG. Partial enlarged side view of power storage module Disassembled perspective view of power storage unit

<Embodiment 1>
A power storage module 10 according to Embodiment 1 will be described with reference to FIGS. 1 to 4. In the following description, the left side in FIG. 1 is the front, the right side is the rear, the upper side in FIG. 2 is the upper side, and the lower side is the lower side.
The power storage module 10 of the present embodiment is used as a power storage module 10 for, for example, Integrated Starter Generator (ISG).

(Power storage module 10)
As shown in FIG. 1, the power storage module 10 has a substantially rectangular parallelepiped shape as a whole. A plurality of electric wires 27 connected to the lead terminals 24 of the respective electric storage elements 22 are led out from the front side surface and the rear side surface (the surfaces arranged on the left and right in FIG. 1) of the electric storage module 10. Each of the plurality of electric wires 27 has one end connected to the lead terminal 24 of the storage element 22 via the voltage detection terminal 26 and the other end connected to the voltage detection connector 33.

  As illustrated in FIG. 2, the power storage module 10 includes a plurality of power storage units 21 including a power storage element 22 and a heat transfer member 30 that has the power storage element 22 mounted thereon and conducts heat generated from the power storage element 22 to the outside. And a case 11 that houses the laminate 20. Each of the plurality of power storage units 21 has an elastic member 50 made of an elastic material. First, the case 11 that houses the laminate 20 will be described.

(Case 11)
The case 11 includes a case main body 12 that houses the stacked body 20, and a lid portion 13 that covers the upper surface of the case main body 12. The case body 12 has an upper surface and a front side surface that are open. Although not shown in detail in the upper end of the rear side surface of the case body 12, a wire outlet hole for leading out the plurality of wires 27 to the outside of the case 11 is formed. An insulating lid member 17 is attached to the front opening of the case body 12.

  At the center position of the upper surface of the lid portion 13, a protruding surface 13 </ b> A that protrudes inward (downward direction) is formed. On the upper surface of the lid portion 13, a fixing hole (not shown) in which a fixing member 18 for fixing the lid portion 13, the laminate 20, and the case main body 12 is disposed outside the protruding surface 13 </ b> A. It is formed through.

  Further, on the upper surface of the lid portion 13, a rectangular lid locking hole 15 is formed penetratingly formed on the front end side. The lid locking hole 15 has a function of locking the insulating lid member 17 attached to the front side.

  As shown in FIG. 1, positive and negative bus bars 28 are led out from the insulating lid member 17 attached to the front opening of the case body 12. Further, a notch (not shown) for leading out the plurality of electric wires 27 is provided at the lower end portion of the edge lid member 17. The insulating lid member 17 not only covers the opening of the case body 12 but also has a function of insulating and protecting the lead terminals 24 arranged on the front end face side of the stacked body 20.

(Laminated body 20)
As shown in FIG. 2, the case 11 accommodates the stacked body 20. In the present embodiment, the stacked body 20 is formed by stacking six (plural) power storage units 21 each having the power storage element 22 mounted on the heat transfer member 30 to which the holding member 40 is attached.

(Power storage unit 21)
Each power storage unit 21 constituting the stacked body 20 includes a power storage element 22, a heat transfer member 30, and an elastic member 50.

(Storage element 22)
In the power storage unit 21, the power storage element 22 having a substantially rectangular shape when viewed from above has a pair of edges in the short side direction held by the holding member 40 and heat transfer attached to the holding member 40, as shown in FIG. 4. It is mounted on the mounting surface 30 </ b> A of the member 30.

  As shown in FIG. 4, each power storage element 22 is arranged substantially in parallel with the surface of the outer surface having a large area arranged vertically. As a result, the surface having a large area comes into contact with the heat transfer member 30 and is excellent in heat dissipation. The storage elements 22 adjacent in the stacking direction are arranged so that the lead terminals 24 having different polarities are arranged at positions facing each other.

  Each power storage element 22 is a laminate type battery. Each power storage element 22 includes a power generation element (not shown), a laminate film 23 that encloses the power generation element and has a side edge welded thereto, and is connected to the power generation element and from the opposite end to which the laminate film 23 is welded in an outward direction. Projecting lead terminals 24.

  The lead terminals 24 having different polarities of the adjacent power storage elements 22 are not shown in detail, but are bent in opposite directions except for the positive electrode lead terminal 24 and the lowermost negative electrode lead terminal 24 of the uppermost power storage element 22. At the same time, the ends are connected so as to be in contact with each other so as to be in contact with each other.

  The positive electrode lead terminal 24 of the uppermost power storage element 22 and the negative electrode lead terminal 24 of the lowermost power storage element 22 are directly overlapped and connected to the voltage detection terminal 26 and the bus bar 28.

  The region on the end side of the laminate film 23 of the lead terminal 24 is a wide region 23A that is wider than the region on the end side, and the corner 23B of the wide region 23A is fitted into the power storage element holding part 42 of the holding member 40. Thus, the movement of the electricity storage element 22 is regulated.

(Bus bar 28)
The bus bar 28 (first bus bar 28A) connected to the uppermost power storage element 22 is a terminal that functions as the positive electrode of the power storage module 10, and the bus bar 28 connected to the lowermost power storage element 22 is connected to the power storage module 10. This is a terminal (second bus bar 28B) that functions as a negative electrode. Each bus bar 28 is made of a conductive material such as pure aluminum, aluminum alloy, copper or copper alloy, and a portion led out from the bus bar lead-out port of the insulating lid member 17 is a terminal portion 29 connected to an external device.

(Heat transfer member 30)
The heat transfer member 30 is a member made of a heat conductive material. In the present embodiment, aluminum or aluminum alloy having excellent heat conductivity is used as the heat conductive material. On the pair of side edges in the longitudinal direction of the heat transfer member 30, as shown in FIG. 4, four heat conduction walls 31 erected upward are formed at intervals. The heat conducting wall 31 is disposed so as to be in contact with the case inner wall surface 12 </ b> A when the laminated body 20 is accommodated in the case 11, and has a function of conducting heat generated from the power storage element 22 to the case 11. Heat generated from the storage element 22 is transmitted to the case 11 through the heat conducting wall 31 and is radiated to the outside of the case 11.

  Holding members 40 made of an insulating resin material are attached to both ends of the heat transfer member 30 in the longitudinal direction.

(Holding member 40)
As shown in FIG. 4, each holding member 40 is provided with two through holes 41 through which the fixing member 18 can be inserted. Here, the power storage unit 21 shown in FIG. 4 is the lowermost power storage unit 21.

  As shown in FIG. 4, each holding member 40 is formed with a concave storage element holding portion 42 into which the corner portion 23 </ b> B of the wide region 23 </ b> A of the lead terminal 24 is fitted. The lead terminal 24 (power storage element 22) is restricted from moving by the power storage element holding part 42.

  Each holding member 40 is provided with a terminal holding portion 43 for holding the voltage detection terminal 26 and a wire receiving groove 44 for receiving the electric wire 27 connected to the voltage detection terminal 26. A crimping portion 26 </ b> A crimped by the voltage detection terminal 26 of the wire 27 is also held in the wire receiving groove 44.

  Further, the holding member 40 disposed in front of the uppermost power storage unit 21 and the holding member 40 disposed in front of the lowermost power storage unit 21 are each provided with a bus bar holding portion 45 for holding the bus bar 28. ing. As shown in FIG. 4, the bus bar holding portion 45 is formed with a recess 45A into which the bus bar 28 is fitted, and a plurality of retaining projections 45B that prevent the bus bar 28 fitted into the recess 45A from coming off. Yes.

  A laminated body holding member 19 is attached to the holding member 40 disposed at the rear of the uppermost stage. The laminated body holding member 19 is a member that holds the laminated body 20 in a laminated state, and is arranged between the connection portion 25 of the lead terminal 24 arranged on the rear end face side of the laminated body 20 and the case 11, and leads The terminal 24 is covered over the entire area for insulation protection.

(Elastic member 50)
In the present embodiment, each power storage unit 21 includes an elastic member 50 made of an elastic material. Examples of the elastic material include an adhesive, a potting agent, a double-sided tape, and a rubber sheet.

  The elastic member 50 is in the form of a sheet, and is placed on each power storage unit 21 so as to be in contact with the laminate film 23 (battery container) of the power storage element 22.

  The lower side surface of the elastic member 50 is in contact with the power storage element 22, and the upper side surface of the elastic member 50 is in contact with the heat transfer member 30 of the power storage unit 21 disposed above or the protruding surface 13 </ b> A of the lid portion 13.

  The elastic member 50 is elastically deformed in the stacking direction so as to absorb the manufacturing tolerance of the thickness dimension of the power storage element 22 in each power storage unit 21.

(Assembly method of power storage module 10 of this embodiment)
Next, a method for assembling the power storage module 10 of this embodiment will be described.
After the corresponding holding members 40 are attached to both side edges of the six heat transfer members 30, the voltage detection terminal 26 and, if necessary, the bus bar 28 are attached to predetermined positions of the holding member 40.

  Next, the storage element 22 is positioned and placed on the placement surface 30 </ b> A of each heat transfer member 30. Specifically, the corner 23 </ b> B of the lead terminal 24 of the power storage element 22 is placed on the placement surface 30 </ b> A of the heat transfer member 30 so as to fit into the power storage element holding part 42 of each holding member 40. At this time, a double-sided tape (not shown) may be pasted on the heat transfer member 30 in advance, and the electricity storage element 22 may be fixed to the heat transfer member 30 with the double-sided tape.

  Next, when the elastic member 50 is placed on the power storage element 22, the power storage unit 21 is obtained.

  The six power storage units 21 obtained in this way are stacked from the bottom to the top. Here, since there is a manufacturing tolerance in the thickness dimension of the energy storage element 22, the sum of the thickness dimension of the energy storage element 22 and the thickness dimension of the heat transfer member 30 may not be the same as the thickness dimension of the holding member 40. However, in this embodiment, since each power storage unit 21 has the elastic member 50, when stacking the power storage units 21 from the bottom to the top, the elastic member 50 is elastically deformed to absorb manufacturing tolerances.

  In the stacked body 20, the elastic tolerance 50 is displaced in the stacking direction of the stacked body 20, so that the manufacturing tolerance of the thickness dimension of the power storage element 22 is absorbed, and the upper surface of the power storage element 22 is another power storage unit 21 arranged on the upper side. Is in surface contact with the surface 30B opposite to the mounting surface 30A.

  After the stacked body 20 is manufactured, the ends of the two adjacent lead terminals 24 are joined in the vertical direction. The laminated body holding member 1958 is attached to the rear end face side of the laminated body 20 obtained in this way, and the laminated body 20 is held.

  Next, the stacked body 20 is accommodated in the case main body 12. When the laminated body 20 is accommodated in the case main body 12, the laminated body 20 is placed on the bottom wall portion of the case main body 12, and the heat conducting wall 31 of the heat transfer member 30 is arranged so as to contact the case inner wall surface 12A. . The electric wire 27 is led out to the outside of the case body 12.

Next, the insulating lid member 17 is attached to the opening on the front side of the case body 12.
Specifically, the insulating lid member 17 is attached to the case body 12 such that the electric wire 27 is led out from the notch portion of the insulating lid member 17 and the bus bar 28 is led out from the bus bar outlet port of the insulating lid member 17. Next, the lid 13 is placed so as to cover the upper surface of the case body 12.

  Next, between the lid part 13 and the bottom wall part of the case main body 12, the fixing member 18 is passed through the through hole 41 of the holding member 40 arranged at the end of the laminated body 20, not shown. After fixing and fixing the fixing hole of the lid part 13, the hollow fixing member 18 and the fixing hole (not shown) of the bottom wall part of the case body 12 to the jig, the lid part using screws or pins 13 and the case main body 12 are fixed. In this way, the power storage module 10 shown in FIG. 1 is completed. At this time, the elastic member 50 disposed in the uppermost power storage unit 21 is in surface contact with the protruding surface 13A of the lid 13 while being deformed in the stacking direction, and the elastic member 50 disposed in the other power storage unit 21 is stacked. While being deformed in the direction, it comes into surface contact with the lower surface 30B of the heat transfer member 30 of the power storage unit 21 disposed on the upper side. Thereby, as shown in FIGS. 2 and 3, the power storage element 22 is held in a compressed state between the lid portion 13 and the bottom wall portion of the case body 12.

(Operation and effect of this embodiment)
Next, the operation and effect of this embodiment will be described.
According to the present embodiment, in each power storage unit 21, the elastic member 50 absorbs the variation in the thickness dimension of the power storage element 22, so that one elastic member 50 is disposed between the stacked body 20 and the case 11. In addition, even the elastic member 50 having a small thickness dimension can sufficiently absorb the variation in the thickness dimension of the power storage element 22 and can sufficiently dissipate the heat generated from the stacked body 20. As a result, according to the present embodiment, the power storage module 10 with improved heat dissipation can be provided.

  Moreover, according to this embodiment, since the dispersion | variation in thickness dimension is absorbed in each electrical storage unit 21, sufficient compression force can also be applied to the electrical storage module 10. FIG.

  Furthermore, according to the present embodiment, the elastic member 50 is arranged between the power storage element 22 and the heat transfer member 30 of the power storage unit 21 adjacent to the power storage element 22. It can be set as the structure which mounts the electrical storage element 22, can increase the contact area of the heat-transfer member 30 and the electrical storage element 22, and heat dissipation improves.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.
(1) In the above embodiment, the elastic member 50 is arranged between the power storage element 22 and the heat transfer member 30 of the power storage unit 21 adjacent to the power storage element 22. You may mount in order of an elastic member and an electrical storage element on 30 A of surfaces. In this case, the elastic member may be bonded to the heat transfer member with an adhesive or a double-sided tape.
(2) In the above embodiment, the example in which the power storage element 22 is a battery has been described. However, the power storage element may be a capacitor or the like.
(3) Although the example used for the ISG power storage module 10 has been described in the above embodiment, it may be used for a power storage module for other purposes.

DESCRIPTION OF SYMBOLS 10 ... Power storage module 11 ... Case 12 ... Case main body (case)
13 ... Lid (case)
DESCRIPTION OF SYMBOLS 20 ... Laminated body 21 ... Power storage unit 22 ... Power storage element 30 ... Heat transfer member 30A ... Mounting surface 31 ... Heat conduction wall 50 ... Elastic member

Claims (2)

A stack formed by stacking a plurality of power storage elements, and a plurality of power storage units that have the heat storage elements mounted thereon and conduct heat generated from the power storage elements to the outside; and a case that houses the stack With
The plurality of power storage units each have an elastic member made of an elastic material. The power storage module according to claim 1, wherein the elastic member is disposed between the power storage element and the heat transfer member of the power storage unit adjacent to the power storage element.

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