JP5904087B2 - Power storage module - Google Patents

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 a battery module by connecting two or more. As such a battery module, for example, a battery module described in Patent Document 1 is known.

JP 2006-210312 A

  Patent Document 1 discloses a battery module formed by laminating a plurality of unit cells from which positive and negative lead terminals protrude from an end portion. In this battery module, adjacent unit cells are connected in series by connecting lead terminals having different polarities (reverse polarities).

  In the battery 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 battery module, the single cells adjacent in the stacking direction are arranged in a separated state 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 battery module, heat generated from the power storage elements may become high due to repeated charging and discharging. 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.

  As a method for improving the heat dissipation of the power storage module, it is conceivable to dispose a heat transfer plate made of a heat conductive material such as a metal plate between adjacent power storage elements in the stacking direction.

  However, in a power storage module including a power storage element in which a power storage element is accommodated in a laminate film container in which a resin layer is laminated on a metal foil, the metal foil inside the resin layer is exposed from the end face of the laminate film container. There is a case. If the metal foil is exposed from the end face of the laminate film container, there is a concern about the occurrence of a short circuit due to the contact between the metal foil and the heat transfer plate made of the metal plate. As a result of further studies, it has been found that the occurrence of a short circuit can be prevented by forming a contact prevention portion on the heat transfer plate material.

That is, the present invention provides the above-mentioned electricity storage that is adjacent to the laminate obtained by laminating a plurality of electricity storage elements each containing an electricity storage element in a laminate film container in which a resin layer is laminated on a metal foil in the stacking direction. And a heat transfer plate made of a heat conductive material that is disposed between the elements and conducts heat generated in the power storage element to the outside. The heat transfer plate includes an end face of the power storage element and the heat transfer The contact prevention part which prevents a contact with a board | plate material is provided, and the said contact prevention part is an electrical storage module by which the convex part and recessed part which protrude in the mutually opposite direction from the board surface of the said heat-transfer board | plate material are formed alternately. It is.

  In the present invention, since the heat transfer plate material is disposed between the adjacent power storage elements, the heat generated in the power storage element is transferred to the heat transfer plate material and is radiated from the heat transfer plate material to the outside of the power storage element. The heat dissipation can be improved. Further, in the present invention, since the heat transfer plate material is provided with a contact prevention portion for preventing the contact between the end surface of the electricity storage element and the heat transfer plate material, the contact between the end surface of the electricity storage element (the end surface of the container) and the heat transfer plate material. It is possible to prevent a short circuit due to.

As a result, according to the present invention, it is possible to provide a power storage module with improved heat dissipation while preventing a short circuit due to contact between the end face of the laminate film container and the heat transfer plate.
Moreover, since the said contact prevention part is the structure by which the convex part and recessed part which protrude in the mutually opposite direction from the board surface of the said heat-transfer board | plate material are formed alternately, it can provide a contact prevention part by simple structure. it can.

The present invention may have the following configurations .

The heat transfer plate is provided with a case that accommodates the laminate and the heat transfer plate, and the heat transfer plate has a heat conductive wall that contacts the inner wall surface of the case and conducts heat generated in the power storage element to the case. It may be provided.
With such a configuration, heat generated in the power storage element is transmitted to the case through the heat conduction wall and is radiated to the outside of the case, so that heat dissipation is excellent.

Among the plurality of power storage elements, a power storage element disposed at an end in the stacking direction may be disposed so as to be in contact with the inner wall surface of the case.
With such a configuration, heat generated in the power storage element disposed at the end in the stacking direction is transmitted to the inner wall surface of the case and radiated to the outside of the case, so that heat dissipation is further improved.

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

The perspective view of the electrical storage module of Embodiment 1 Perspective view of laminate Plan view of laminate Side view of laminate Sectional drawing in the AA line of FIG. Drawing depicting a case with a cross-sectional view taken along the line BB in FIG. Front view of laminate Sectional drawing in the CC line of FIG. Plan view of battery unit Sectional drawing in the DD line of FIG. Plan view of battery unit Sectional drawing in the EE line of FIG. The perspective view which shows a mode that the heat exchanger plate was attached to the holding member from the back side Partially enlarged perspective view of FIG. The perspective view which shows a mode that the heat exchanger plate was attached to the holding member from the back side Partially enlarged perspective view of FIG. The top view which shows a mode that the terminal for a detection has been arrange | positioned to the holding member which attached the heat exchanger plate The top view which shows a mode that the terminal for a detection and the connection member were arrange | positioned to the holding member which attached the heat exchanger plate

<Embodiment 1>
A first embodiment in which the present invention is applied to a battery module 10 will be described with reference to FIGS. In the following description, the left side in FIG. 4 is the front, the right side is the rear, the upper side in FIG. 4 is the upper side, and the lower side is the lower side.
The battery module 10 of the present embodiment is used as, for example, a battery module 10 for an integrated starter generator (ISG).

(Battery module 10)
As shown in FIG. 1, the battery module 10 has a substantially rectangular parallelepiped shape as a whole. A plurality of electric wires 65 connected to the lead terminals 34 of each unit cell 32 (an example of a power storage element) are respectively connected to the outside from the front side surface and the rear side surface (surfaces arranged on the left and right in FIG. 1) of the battery module 10. Has been derived. One end of each of the plurality of electric wires 65 is connected to the lead terminal 34 of the unit cell 32 via the plate-shaped voltage detection terminal 66, and the other end is connected to a voltage detection output connector 64 (hereinafter referred to as “connector 64”). Has been.

  The plurality of connectors 64 connected to the electric wire 65 led out to the front side surface and the plurality of connectors 64 connected to the electric wire 65 led out to the rear side surface are respectively laminated and integrated.

  As shown in FIG. 4, the battery module 10 is attached to a stacked body 30 formed by stacking a plurality of unit cells 32 (six unit cells 32 in the present embodiment) and to both ends of each unit cell 32. A holding member 40, a heat transfer plate 60 (an example of a heat transfer plate material) disposed between adjacent cells 32, 32 in the stacking direction (up and down direction), and a metal case 11 that accommodates them. Prepare.

(Case 11)
The case 11 includes a case main body 12 that houses the stacked body 30 and a lid portion 18 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. At the upper end of the rear side surface of the case body 12, a wire lead-out hole (not shown) for leading the plurality of wires 65 out of the case 11 is formed. An insulating lid member 26 is attached to the front opening of the case body 12.

  As shown in FIG. 1, the lid portion 18 includes a substantially rectangular plate-like portion 19, and a fixing portion 23 that is connected substantially vertically downward to the plate-like portion 19 and is fixed to the upper end portion of the case body 12. Prepare. A projecting surface 20 that projects inward (downward) is formed at the center of the plate-like portion 19. The protruding surface 20 of the lid portion 18 can be brought into contact with the uppermost unit cell 32 (the first step from the top). When the projecting surface 20 of the lid portion 18 and the unit cell 32 come into contact with each other, heat generated from the unit cell 32 is transmitted to the lid unit 18 and is radiated to the outside.

  In the plate-like portion 19, a fixing hole 21 in which a first fixing member (not shown) for fixing the lid portion 18, the laminated body 30, and the case main body 12 is disposed outside the protruding surface 20. Is formed through. The hole diameter of the fixing hole 21 is smaller than the outer diameter of the first fixing member.

  Further, in the plate-like portion 19, a rectangular hole 22 is formed through the front end portion side. The hole 22 serves as a lid locking hole 22 for locking an insulating lid member 26 attached to the front side.

  The fixing portion 23 has a substantially circular shape, and a plurality (three) of insertion holes 24 through which a second fixing member (not shown) for fixing the lid portion 18 to the case body 12 can be inserted. The fixing portion 23 is overlaid on a pair of side surfaces (surfaces disposed on the front side and the back side in FIG. 1) and the outer side of the rear side surface of the case body 12.

  Bus bar outlets 29B and 29B from which the bus bar 38 is led are formed in the insulating lid member 26 attached to the opening on the front side of the case body 12.

  As shown in FIG. 1, a substantially rectangular cutout 29 </ b> A for leading out the plurality of electric wires 65 is provided at the lower end of the insulating lid member 26. The insulating lid member 26 has a function of not only covering the opening of the case body 12 but also insulating and protecting the lead terminal 34 disposed on the front end face side of the stacked body 30.

(Laminated body 30)
As shown in FIGS. 2 to 4, the case 11 accommodates a stacked body 30 formed by stacking a plurality of unit cells 32. In the present embodiment, the stacked body 30 is formed by stacking a plurality of unit cells 32 (hereinafter referred to as “battery units 31”) placed on a heat transfer plate 60 to which the holding member 40 is attached.

(Single cell 32)
As shown in FIG. 3, in the battery unit 31, the unit cell 32 having a substantially rectangular shape when viewed from the top holds the lead terminals 34 protruding from the pair of end portions in the short side direction by the holding member 40 and the holding member 40. It is mounted on the heat transfer plate 60 attached to.

  9 is a diagram showing the battery unit 31 in the third stage from the top, FIG. 11 is a diagram showing the battery unit 31 in the sixth stage from the top, and FIG. 17 is the battery in the third stage from the top. FIG. 18 is a diagram illustrating an assembly procedure of the unit 31, and FIG. 18 is a diagram illustrating an assembly procedure of the battery unit 31 in the sixth stage from the top.

  As shown in FIGS. 9 and 11, each single battery 32 is arranged substantially in parallel with a surface 33 </ b> A having a large area among the outer surfaces arranged vertically. As a result, the surface 33A having a large area comes into contact with the heat transfer plate 60 and is excellent in heat dissipation. The unit cells 32 that are adjacent in the stacking direction are arranged so that the lead terminals 34 having different polarities face each other.

  Each unit cell 32 is a laminate type battery. Each cell 32 is connected to a power generation element (an example of a power storage element) (not shown), a laminate film 33 (an example of a container made of a laminate film) in which the power generation element is accommodated and the end 33B is welded, and the power generation element. And a lead terminal 34 protruding outward from the opposite end portions 33B and 33B to which the laminate film 33 is welded.

  Laminate film 33 (a laminate film container) is made of a laminate film in which a resin layer is laminated on the outside of a metal foil. Examples of the metal foil include aluminum foil, and examples of the resin layer include polyethylene terephthalate and nylon. On the inner side (power generation element side) of the metal foil, a heat welding layer made of polyethylene or polypropylene is provided.

(Lead terminal 34)
The lead terminals 34 and 34 having different polarities of the adjacent unit cells 32 and 32 are opposite to each other except for the negative electrode lead terminal 34 of the first-stage unit cell 32 from the top and the positive electrode lead terminal 34 of the sixth stage from the top. And are connected by overlapping and welding so that the end portions are in contact with each other (see FIG. 7).

  Specifically, as shown in FIG. 10, the lead terminal 34 </ b> B protruding outward from one end 33 </ b> B of the unit cell 32 is bent substantially vertically upward after passing through the side-arc-shaped protrusion 36. The end portion has a J-shape when viewed from the side. A lead terminal 34B (not shown) protruding from the other end portion 33B is bent substantially vertically downward after passing through a projecting portion 36 having a side view arc shape, and the end portion has a J-shape in side view. Yes. That is, although not shown in detail, the lead terminals 34B projecting outward from one edge 33B of the unit cells 32 arranged in the second to fifth stages from the top, and projecting outward from the other edge 33B. The lead terminals 34B are bent in opposite directions.

  Lead terminals 34A other than the lead terminal 34B (terminal connection terminal 34B) connected to the lead terminal 34B of the adjacent unit cell 32 (the first negative lead terminal 34A from the top and the sixth positive lead lead terminal 34A from the top). Are formed with U-shaped protrusions 35 when viewed from the side, and in these terminals, portions (ends) closer to the ends than the U-shaped protrusions 35 are substantially parallel to the protruding direction (straight lines). State).

  These lead terminals 34A (the negative electrode lead terminal 34A of the unit cell 32 at the first stage from the top and the positive electrode lead terminal 34A of the unit cell 32 at the sixth stage from the top) are directly superimposed on the voltage detection terminal 66 and the bus bar 38. Connected (bus bar connection terminal 34A).

  Although not shown in detail, the negative lead terminal 34 of each unit cell 32 is directly overlapped with and connected to the voltage detection terminal 66.

  The arc-shaped protrusion 36 formed on the lead terminal 34B has a function of relieving stress received by the lead terminal 34B when welding the lead terminals 34B and 34B. The U-shaped protrusion 35 formed on the lead terminal 34A has a function of relieving stress applied to the lead terminal 34A when the lead terminal 34A and the bus bar 38 are connected.

  As shown in FIGS. 10 and 12, each lead terminal 34 protrudes in the vertical direction between the end 33 </ b> B of the laminate film 33 and the protrusions 35 and 36, and is engaged with the holding member 40. A stop convex portion 37 is formed.

  A region 34 a on the end 33 B side of the laminate film of the lead terminal 34 is a wide region 34 a wider than the region 34 b on the end side, and a corner 34 c of the wide region 34 a is formed on the unit cell holding portion 51 of the holding member 40. The movement of the unit cell 32 is regulated by fitting.

(Bus bar 38)
The bus bar 38 (second bus bar 38B) connected to the uppermost unit cell 32 is a terminal 38B that functions as the negative electrode of the battery module 10, and the bus bar 38 connected to the lowermost unit cell 32 is connected to the battery module 10. This is a terminal 38A (first bus bar 38A) that functions as a positive electrode. Each bus bar 38 is made of a conductive material such as pure aluminum, aluminum alloy, copper or copper alloy, and a portion 39 led out from the bus bar lead-out port 29B of the insulating lid member 26 is a terminal portion 39 connected to an external device. .

(Holding member 40)
Each unit cell 32 is held in a state of being placed on the heat transfer plate 60 by a holding member 40 made of an insulating resin. The holding members 40 are respectively disposed at both ends of the unit cell 32.

  In the present embodiment, of the holding members 40 that overlap in the vertical direction, one holding member 40 is formed with a locking claw 41A that protrudes toward the other holding member 40 and protrudes inward. A protrusion 41 is provided, and the other holding member 40 has a recessed shape for receiving the engagement protrusion 41 and an engagement receiving portion 42 formed with a locking protrusion 42A for locking the locking claw 41A. Is provided. The engaging protrusion 41 and the engagement receiving portion 42 are structured to engage with each other. The holding members 40, 40 that are adjacent in the vertical direction are engaged at two locations. Specifically, it is as follows.

  Engaging protrusions 41 are respectively provided on the two side surfaces of the holding member 40B disposed in front of the second stage from the top, while the two side surfaces of the holding member 40A disposed in front of the first stage from the top. Are provided with engagement receiving portions 42 that mutually engage with the engagement protrusions 41 provided on the holding member 40B in the second stage from the top (see FIGS. 4 and 5).

  Two engaging protrusions 41 are provided on the front side surface of the holding member 40C arranged in front of the third step from the top, while the front side surface of the holding member 40B arranged in front of the second step from the top. Is provided with an engagement receiving portion 42 that mutually engages with each of the engagement protrusions 41 provided on the holding member 40C in the third step from the top (see FIGS. 7 and 8).

  Engaging protrusions 41 are respectively provided on the two side surfaces of the holding member 40D arranged in front of the fourth step from the top, while the two side surfaces of the holding member 40C arranged in front of the third step from the top Are provided with engagement receiving portions 42 that are engaged with the engagement protrusions 41 provided on the holding member 40D in the fourth stage from the top (see FIGS. 4 and 5).

  Two engaging protrusions 41 are provided on the front side surface of the holding member 40E arranged in front of the fifth step from the top, while on the front side surface of the holding member 40D arranged in front of the fourth step from the top. Is provided with an engagement receiving portion 42 that mutually engages with each of the engagement protrusions 41 provided on the holding member 40E in the fifth step from the top (see FIGS. 7 and 8).

  Engaging protrusions 41 are respectively provided on the two side surfaces of the holding member 40F arranged in front of the sixth step from the top, while the two side surfaces of the holding member 40E arranged in front of the fifth step from the top Are provided with engagement receiving portions 42 that mutually engage with the engagement protrusions 41 provided on the holding member 40F in the sixth step from the top (see FIGS. 4 and 5).

  Two engaging protrusions 41 are provided on the rear side surface of the holding member 40H arranged at the rear of the second stage from the top, while on the rear side surface of the holding member 40G arranged at the rear of the first stage from the top. Is provided with an engagement receiving portion 42 that mutually engages with each of the engaging protrusions 41 provided on the holding member 40H at the second stage from the top (see FIG. 8).

  Engaging protrusions 41 are provided on the two side surfaces of the holding member 40I arranged at the rear of the third step from the top, respectively, while the two side surfaces of the holding member 40H arranged at the rear of the second step from the top are provided. Are provided with engagement receiving portions 42 that mutually engage with the engagement protrusions 41 provided on the holding member 40I at the rear of the third row from the top (see FIG. 4).

  Two engaging protrusions 41 are provided on the rear side surface of the holding member 40J arranged at the rear of the fourth stage from the top, while the rear side surface of the holding member 40I arranged at the rear of the third stage from the top is provided. Are provided with engagement receiving portions 42 that mutually engage with the respective engagement protrusions 41 provided on the holding member 40J at the rear of the fourth stage from the top (see FIG. 8).

  Engaging protrusions 41 are respectively provided on the two side surfaces of the holding member 40K disposed at the rear of the fifth step from the top, while the two side surfaces of the holding member 40J disposed at the rear of the fourth step from the top Are provided with engagement receiving portions 42 that mutually engage with the engagement protrusions 41 provided on the holding member 40K at the rear of the fifth stage from the top (see FIG. 4).

  Two engaging protrusions 41 are provided on the rear side surface of the holding member 40L disposed at the rear of the sixth stage from the top, while the rear side surface of the holding member 40K disposed at the rear of the fifth stage from the top. Is provided with an engagement receiving portion 42 that mutually engages with each of the engagement protrusions 41 provided on the holding member 40L at the rear of the sixth stage from the top (see FIG. 8).

  The engaging protrusion 41 of the holding member 40 is adapted to fit inside the engagement receiving portion 42 of the holding member 40 that overlaps the holding member 40, and the plurality of holding members 40 are overlapped to be in an engaged state. Both the engagement protrusion 41 and the engagement receiving part 42 do not protrude to the outside of the holding member 40 and are space-saving.

Moreover, in this embodiment, as shown in FIG. 2 and FIG. 8, when a plurality of battery units 31 are stacked, a space S is formed between the holding members 40 and 40 adjacent in the vertical direction as shown in FIG. 4. Is to be formed.
Specifically, the lower side surface of the holding member 40B disposed in front of the second stage from the top and the upper side surface of the holding member 40C disposed in front of the third stage from the top are both recessed. When the two holding members 40B and 40C are overlapped, a space S penetrating substantially parallel to the short side direction of the laminate film 33 of the unit cell 32 is formed between the holding members 40B and 40C.

  Similarly, the holding member 40G disposed between the holding member 40D disposed in front of the fourth stage from the top and the holding member 40E disposed in front of the fifth stage from the top, and the rear of the first stage from the top. And a holding member 40H arranged behind the third stage from the top, a holding member 40I arranged behind the third stage from the top, and a holding member 40J arranged behind the fourth stage from the top A space S is also formed between the holding member 40K arranged at the rear of the fifth stage from the top and the holding member 40L arranged at the rear of the sixth stage from the top.

In the space S between the holding members 40 adjacent to each other in the vertical direction, connection portions 36B of the lead terminals 34B and 34B having different polarities adjacent to each other in the vertical direction are arranged. In this space S, a jig (not shown) for welding adjacent lead terminals 34B, 34B having different polarities can be inserted, and the holding member 40 on the side surface or the back side in FIG. The side surface is an insertion port 71 for inserting the jig into the space S.
Each holding member 40 is provided with two through holes 43 through which the first fixing member can be inserted.

  A terminal arrangement part 45 for arranging and holding the lead terminals 34 is formed on the upper side surface of each holding member 40. The terminal arrangement part 45 receives and engages with a locking projection 37 of the lead terminal 34. A locking groove 46 for stopping is provided (see FIGS. 10 and 12). The locking groove 46 has a function of locking the lead terminal 34 and positioning the unit cell 32.

A thickness region 52 having a thickness dimension larger than that of the terminal placement portion 45 is provided in a region adjacent to the terminal placement portion 45 of each holding member 40, and the wide width of the lead terminal 34 is provided in this thickness region 52. A concave unit cell holding portion 51 into which the corner portion 34c of the region 34a is fitted is formed. The movement of the lead terminal 34 (unit cell 32) is restricted by the unit cell holding portion 51.
On the lower surface of each holding member 40, heat transfer plate locking portions 44 that engage with the locking holes 63A of the heat transfer plate 60 are provided at opposing positions (two in total) (FIG. 13). -See FIG.

  As shown in FIGS. 15 and 16, the heat transfer plate locking portion 44 is provided in a portion in which a part of the lower surface of the holding member 40 is hollowed out into a square shape. Slits 44B and 44B are formed on both sides of the heat transfer plate locking portion 44, respectively, and have a structure that can be bent and deformed in the vertical direction. The heat transfer plate locking portion 44 having a square shape is formed with a heat transfer plate locking protrusion 44A that protrudes downward (side on which the heat transfer plate is disposed) closer to the end.

  The end surface 44C that separates the slits 44B and 44B of the holding member 40 has a stepped shape, and the protruding piece 63 of the heat transfer plate 60 is moved along the stepped end surface 44C, whereby the heat transfer plate 60 protrudes. The piece 63 is slidably mounted on the holding member 40.

  As shown in FIG. 16, the distance between the opposing stepped end faces 44 </ b> C and 44 </ b> C is the width dimension of the protruding piece 63 of the heat transfer plate 60 on the upper surface side (lower P in FIG. 16) of the holding member 40. Although it is slightly larger than Q, it is smaller than the width dimension Q of the protruding piece 63 of the heat transfer plate 60 on the lower surface side (the upper R in FIG. 16). That is, the protruding piece 63 of the heat transfer plate 60 is sandwiched between the lower surface of the holding member 40 and the heat transfer plate locking portion 44 of the holding member 40 when attached to the holding member 40 (FIG. 14).

  The holding members 40C, 40E, 40H, and 40J include an insulating wall portion 54 that surrounds the periphery of the connecting portion 36A that connects the lead terminals 34 and prevents and insulates the other connecting portions 36A and other lead terminals 34 from contacting each other. (See FIG. 2 and the like).

  The holding members 40A, 40C, 40E, 40F, 40H, 40J, and 40L each include a terminal holding portion 47 that holds the voltage detection terminal 66 and an electric wire that houses the electric wire 65 connected to the voltage detection terminal 66. A housing groove 48 is provided. A crimping portion 65 </ b> A crimped by a voltage detection terminal 66 of the electric wire 65 is also held in the electric wire receiving groove 48.

  As shown in FIG. 10 and FIG. 12, the upper surface (one surface) of the voltage detection terminals 66 held by the terminal holding portions 47 of the holding members 40A, 40C, 40E, 40F, 40H, 40J, and 40L are lead terminals. 34 is held at a position that is on the same line (on the XX line and on the YY line) with the lower surface (an example of the surface).

  Furthermore, the holding members 40A and 40F are each provided with a bus bar holding portion 49 (an example of a connection member holding portion) that holds the bus bar 38. The bus bar holding portion 49 is formed with a recessed portion 49A into which the bus bar 38 is fitted, and a plurality of retaining projections 49B that retain the bus bar 38 fitted into the recessed portion 49A.

  As shown in FIG. 12, the upper surface (one surface) of the bus bar 38 held by the bus bar holding portion 49 of the holding members 40 </ b> A and 40 </ b> F is collinear with the lower surface (an example of the surface) of the lead terminal 34 (YY On the line).

  Each holding member 40 is formed with an electric wire passage portion 53 through which an electric wire 65 attached to the holding member 40 or another holding member 40 is passed. The wire passing portion 53 of the holding member 40 other than the holding member 40G arranged at the rear of the first stage from the top is a groove-like portion in which a part of the holding member 40 is cut out, and is accommodated in the case 11. The electric wire passing portion 53 of the holding member 40G is disposed so as to protrude out of the case 11 from an electric wire outlet hole formed at the upper end of the rear side surface of the case main body 12. A plurality of electric wires 65 are led out of the case 11 from the electric wire passage portion 53 of the holding member 40G.

  In the holding members 40F and 40L in the sixth stage from the top, the locking grooves 46 are provided only on the upper surface, but in the other holding members 40, the locking grooves 46 are provided on the upper and lower surfaces, respectively.

  Further, the holding member 40G arranged at the rear of the first stage from the top has a locking hole 50A for locking a laminated body holding member (not shown) and an attachment recess 50B to which the laminated body holding member is attached. , Provided. The multilayer body holding member is disposed between the connection portion 36 </ b> A of the lead terminal 34 disposed on the rear end face side of the multilayer body 30 and the case 11, and insulates and protects the lead terminal 34.

(Heat transfer plate 60)
In the present embodiment, a heat transfer plate 60 made of a heat conductive material is disposed between the unit cells 32 and 32 adjacent in the stacking direction (vertical direction). 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 plate 60, as shown in FIG. 2, four standing walls 61 that stand upward are formed at intervals of four. The upright wall 61 is a heat conducting wall 61 that is disposed so as to contact the inner wall surface of the case 11 when the stacked body 30 is accommodated in the case 11, and conducts heat generated from the unit cell 32 to the case 11. . The heat generated from the unit cell 32 is transmitted to the case 11 through the heat conducting wall 61 and is radiated to the outside of the case 11.

  Now, in this embodiment, as shown in FIG. 13, it protrudes below in FIG. 13 in the inner side rather than a pair of side edge of the heat transfer plate 60 in the longitudinal direction, substantially parallel to the side edge of the longitudinal direction. The convex portions 62A and the concave portions 62B protruding upward in FIG. 13 are alternately formed. The convex portion 62A and the concave portion 62B protrude in opposite directions from the plate surface of the heat transfer plate 60 (see FIG. 6). Three protrusions 62A and two recesses 62B are formed for each heat transfer plate 60.

  The metal foil disposed inside the laminate film 33 may be exposed from the end face 33C of the laminate film 33 that accommodates the power generation element of the unit cell 32, but the protrusion 62A formed on the heat transfer plate 60 and The recess 62B prevents the end surface 33C of the laminate film 33 of the single battery 32 from contacting the heat transfer plate 60 (an example of a contact prevention unit). Thereby, even if the metal foil is exposed from the end face 33 </ b> C of the laminate film 33, it is possible to prevent a short circuit due to the contact between the metal foil and the heat transfer plate 60.

  As shown in FIGS. 13 to 16, the heat transfer plate 60 includes two protruding pieces 63 each having a substantially rectangular locking hole 63 </ b> A formed on both side edges in the short side direction (four in total). Yes. The protruding piece 63 is provided at an opposing position. The protruding piece 63 is slidably mounted by moving along the end surface 44C (sliding portion 44C) of the holding member 40. A heat transfer plate locking projection 44A of the holding member 40 is fitted into a locking hole 63A provided in the protruding piece 63 so as to be engaged with each other.

(Assembly method of battery module 10 of this embodiment)
Next, a method for assembling the battery module 10 of the present embodiment will be described. A total of six unit cells 32 including lead terminals 34 having a predetermined shape are prepared.
The holding members 40 corresponding to the end portions of the six heat transfer plates 60 are respectively attached. Specifically, the heat transfer plate 60 with the holding member 40A and the holding member 40G attached, the heat transfer plate 60 with the holding member 40B and the holding member 40H attached, the heat transfer plate 60 with the holding member 40C and the holding member 40I attached, heat transfer plate 60 with holding member 40D and holding member 40J attached, heat transfer plate 60 with holding member 40E and holding member 40K attached, heat transfer plate 60 with holding member 40F and holding A member to which the member 40L is attached is produced.

  The operation of attaching the holding member 40 to the heat transfer plate 60 is performed by inserting the protruding piece 63 of the heat transfer plate 60 between the opposing stepped end surfaces 44C and 44C of the holding member 40, and attaching the heat transfer plate 60 to the holding member 40. And the heat transfer plate locking projection 44A is engaged with the locking hole 63A of the protruding piece 63.

Next, the voltage detection terminal 66 to which the connector 64 is connected and the bus bar 38 are attached to predetermined positions of the heat transfer plate 60 to which the holding member 40 is attached two by two.
Specifically, the electric wire 65 connected to the connector 64 is accommodated in the electric wire accommodation groove 48 of the holding members 40A, 40C, 40E, 40H, 40J, 40F, and 40L, and the bus bar holding portion 49 of the holding members 40A and 40F Each bus bar 38 is attached (see FIGS. 17 and 18).

  The attachment work of the electric wire 65 connected to the connector 64 can be performed by fitting the voltage detection terminal 66 into the terminal holding portion 47 of the holding member 40 and attaching the electric wire 65 in the electric wire accommodation groove 48.

  The work of attaching the bus bar 38 is performed as follows. When the bus bar 38 is inserted into the recessed portion 49A of the bus bar holding portion 49, the bus bar 38 and the retaining projection 49B come into contact with each other, and the retaining projection 49B bends and deforms outward. When the bus bar 38 is fitted into the recess 49A, the retaining protrusion 49B is elastically restored, restricting the upward movement of the bus bar 38 and becoming a retaining state.

Next, the unit cell 32 is placed on the heat transfer plate 60.
When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40A and the holding member 40G are attached, the first-stage battery unit 31A from the top is obtained. When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40B and the holding member 40H are attached, the battery unit 31B in the second stage from the top is obtained. When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40C and the holding member 40I are attached, a battery unit 31C in the third stage from the top is obtained. When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40D and the holding member 40J are attached, a battery unit 31D in the fourth stage from the top is obtained. When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40E and the holding member 40K are attached, the battery unit 31E at the fifth stage from the top is obtained. When the unit cell 32 is placed on the heat transfer plate 60 to which the holding member 40F and the holding member 40L are attached, the sixth-stage battery unit 31F from the top is obtained.

  When the single battery 32 is placed on the heat transfer plate 60, the locking projections 37 of the lead terminals 34 are fitted in the locking grooves 46 of the terminal arrangement portions 45, and the corners 33 c of the lead terminals 34. However, the unit cell 32 is placed on the heat transfer plate 60 so as to fit into the unit cell holding part 51 of each holding member 40. Then, the lead terminal 34 of the cell 32 is locked by the locking groove 46, thereby preventing the position shift of the cell 32 and the movement of the cell 32 is restricted by the cell holding part 51.

  Further, due to the convex portions 62A and the concave portions 62B formed on the heat transfer plate 60, the end surface 33C of the laminate film 33 of the unit cell 32 does not contact the heat transfer plate 60 as shown in FIG.

  Since the insulating wall portion 54 of the holding member 40 is disposed at the periphery of the connecting portion 36A between the adjacent lead terminals 34, 34, the connecting portion 36A between the adjacent lead terminals 34, 34 is also held in an insulated state. Is done.

In each battery unit 31, the upper surface of the voltage detection terminal 66 held by the terminal holding portion 47 of the holding member 40 and the lower surface of the lead terminal 34 of the unit cell 32 are arranged on the same line, and the voltage detection terminal 66. And the lead terminal 34 are in surface contact (see FIGS. 10 and 12). In particular, in the battery units 31 </ b> A and 31 </ b> F, the upper surface of the voltage detection terminal 66 held by the terminal holding portion 47 of the holding member 40, the upper surface of the bus bar 38, and the lower surface of the lead terminal 34 of the unit cell 32 are the same. Arranged on the wire, the voltage detection terminal 66 and the bus bar 38 are in surface contact with the lead terminal 34 (see FIG. 12).
When the voltage detection terminal 66 and the bus bar 38 are joined to the lead terminal 34 by laser welding, the battery unit 31 is obtained.

  Six battery units 31 are stacked in order from the bottom. The engagement receiving portion 42 of the holding member 40 arranged in the second step from the bottom (the fifth step from the top) is formed with the engagement protrusion formed in the holding member 40 arranged in the bottom step (the sixth step from the top). The battery units 31 are stacked so as to correspond to the portions 41.

  When the holding member 40 disposed on the upper side is moved downward, the engaging projection 41 is fitted into the engagement receiving portion 42, and the locking claw 41 </ b> A of the engagement protruding portion 41 is within the engagement receiving portion 42. When contacting the locking projection 42A, the movement of the engagement projection 41 is restricted, and the engagement projection 41 and the engagement receiving portion 42 are engaged with each other.

  When six battery units 31 are stacked by repeating the same operation, one engagement protrusion 41 and the other engagement receiving portion 42 of the holding member 40 that overlap in the vertical direction are mutually engaged and integrated. A laminated body 30 as shown in FIG. 2 is obtained. At this time, the through holes 43 of the holding members 40 stacked in six steps are overlapped to form one through hole, and a space S is formed between the adjacent holding members 40 and 40. When the battery unit 31 is stacked, the connector 64 is also stacked and integrated.

Next, a welding jig is inserted into the space S from the insertion port 71 between the holding members 40 adjacent to each other in the vertical direction, and the ends of the two lead terminals 34B, 34B adjacent to each other in the vertical direction ( The straight portions are joined together. By sandwiching a portion where the ends of the two lead terminals 34B and 34B overlap with each other with a pair of jigs inserted in a direction intersecting the protruding direction of the lead terminal 34, welding is performed by irradiating with laser light. Adjacent lead terminals 34B and 34B having different polarities are connected to each other.
A laminated body holding member is attached to the rear end face side of the laminated body 30 obtained in this way, and the laminated body 30 is brought into a holding state.

  Next, the connector-attached electric wire 65 led out from the rear side of the laminated body 30 is led out from the electric wire outlet hole formed in the upper end of the rear side surface of the case main body 12, and the laminated body 30 is accommodated in the case main body 12. When the laminated body 30 is accommodated in the case main body 12, the heat conducting wall 61 is arranged so as to contact the inner wall surface 12 </ b> A of the case main body 12.

  Next, the insulating lid member 26 is attached to the opening on the front side of the case body 12. Specifically, the electric wire with connector 65 led out from the front side of the laminated body 30 is led out from the notch 29A of the insulating lid member 26, and the bus bar 38 is led out from the bus bar outlet 29B of the insulating lid member 26. The insulating lid member 26 is attached to the case body 12. Next, when the lid 18 is placed so as to cover the upper surface of the case body 12, the battery module 10 as shown in FIG. 1 is obtained.

  Next, in the state where the first fixing member is passed through the through hole 43 of the holding member 40 arranged at the end of the laminated body 30 between the lid portion 18 and the bottom wall portion of the case main body 12. After inserting the fixing hole 21 of the lid portion 18, the hollow first fixing member and the fixing hole of the bottom wall portion of the case main body 12 into the jig not to be aligned, the lid portion 18 is The case body 12 is fixed. In this way, the battery module 10 is completed.

(Operation and effect of this embodiment)
Next, the operation and effect of this embodiment will be described.
In the present embodiment, since the heat transfer plate 60 is disposed between the unit cells 32 adjacent in the stacking direction (vertical direction), the heat generated in the unit cell 32 is transmitted to the heat transfer plate 60 and transferred. Since heat is transmitted from the hot plate 60 to the case 11 and is radiated to the outside of the unit cell 32, heat dissipation can be improved. Further, in the present embodiment, the heat transfer plate 60 is provided with a convex portion 62A and a concave portion 62B (contact prevention portion) that prevent the end surface 33C of the unit cell 32 and the heat transfer plate 60 from contacting each other. A short circuit due to the contact between the end face 33C of the battery 32 (the end face 33C of the laminate film) and the heat transfer plate 60 can be prevented. As a result, according to the present embodiment, it is possible to provide the battery module 10 with improved heat dissipation while preventing a short circuit due to contact between the end surface 33C of the laminate film 33 and the heat transfer plate 60.

  Moreover, according to this embodiment, since the contact prevention part is the structure by which the convex part 62A and the recessed part 62B which protrude in the mutually opposite direction from the plate surface of the heat exchanger plate 60 are formed alternately, simple structure Thus, a contact preventing part can be provided.

  Moreover, according to this embodiment, the laminated body 30, the holding member 40, and the case 11 which accommodates the heat exchanger plate 60 are provided, and the heat exchanger plate 60 contacts the inner wall surface 12A of the case 11. The heat conduction wall 61 that conducts the heat generated in the unit cell 32 to the case 11 is provided, so that the heat generated in the unit cell 32 is transmitted to the case 11 through the heat conduction wall 61 and is outside the case 11. Because it dissipates heat, it has excellent heat dissipation.

  Furthermore, according to the present embodiment, among the plurality of unit cells 32, the unit cell 32 disposed at the end (upper end) in the stacking direction is disposed so as to be in contact with the inner wall surface 12 </ b> A of the case 11. Since the heat generated in the unit cells 32 arranged at the end in the stacking direction is transmitted to the inner wall surface 12A of the case 11 and radiated to the outside of the case 11, the heat dissipation is further improved.

<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-described embodiment, the contact prevention unit has a configuration in which the three convex portions 62A and the three concave portions 62B are alternately formed for one heat transfer plate 60, but is not limited thereto. For example, the structure which formed the convex part and the recessed part 2 pieces or 4 pieces or more per sheet may be sufficient.
(2) In the above embodiment, the heat transfer plate 60 provided with the heat conductive wall 61 in contact with the inner wall surface 12 </ b> A of the case 11 is shown. However, even if the heat transfer plate is not provided with a heat conductive wall. Good.
(3) In the above embodiment, the unit cell 32 disposed at the upper end in the stacking direction of the unit cells 32 constituting the stacked body 30 is disposed so as to be in contact with the inner wall surface 12 </ b> A of the case 11. Although shown, the unit cell arrange | positioned at the lower end part in the lamination direction may be in contact with the inner wall surface of the case.
(4) In the said embodiment, although the heat-transfer plate 60 showed the example made from aluminum or aluminum alloy, if it is a heat-transfer plate which consists of a heat conductive material, a constituent material will not be limited.
(5) In the above embodiment, an example in which the power storage element is a battery has been described, but the power storage element may be a capacitor or the like.
(6) Although the example used for the battery module 10 for ISG was shown in the said embodiment, you may use for the battery module of another use.

10 ... Battery module (storage module)
11 ... Case 12 ... Case body (Case)
12A ... Inner wall surface of the case 18 ... Cover (case)
DESCRIPTION OF SYMBOLS 20 ... Projection surface 30 ... Laminated body 31 ... Battery unit 32 ... Single cell (electric storage element)
33 ... Laminate film (container made of laminate film)
33A ... A large surface 33A
34 (34A, 34B) ... lead terminal 40 ... holding member 60 ... heat transfer plate (heat transfer plate material)
61 ... Thermal conduction wall 62A ... Convex part (contact prevention part)
62B ... concave portion (contact prevention portion)

Claims (3)

A laminated body obtained by laminating a plurality of power storage elements each containing a power storage element in a laminate film container in which a resin layer is laminated on a metal foil;
A heat transfer plate made of a heat conductive material disposed between the power storage elements adjacent in the stacking direction and conducting heat generated in the power storage elements to the outside; and
The heat transfer plate material is provided with a contact preventing portion for preventing contact between the end face of the electricity storage element and the heat transfer plate material ,
The said contact prevention part is an electrical storage module by which the convex part and recessed part which protrude in the mutually opposite direction from the board surface of the said heat-transfer board | plate material are formed alternately . The heat transfer plate is provided with a case that accommodates the laminate and the heat transfer plate, and the heat transfer plate has a heat conductive wall that contacts the inner wall surface of the case and conducts heat generated in the power storage element to the case. The power storage module according to claim 1 provided. The power storage module according to claim 2 , wherein among the plurality of power storage elements, a power storage element disposed at an end in the stacking direction is disposed so as to be in contact with an inner wall surface of the case.

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