JP2014120340A - Battery pack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the temperature difference of a plurality of secondary batteries in the secondary batteries arranged in a vertical direction.SOLUTION: A battery pack 30 comprises a counter weight 31 for balancing a load mounted on a fork. The counter weight 31 includes a rectangular weight part 32, and a planar weight body 33 that is protruded in a thickness direction of the weight part 32 from one end of a transverse direction of the weight part 32 and extends over the other end of a longitudinal direction from one end of the longitudinal direction of the weight part 32. The weight body 33 has a thick part 34 whose thickness gradually increases from upward of the longitudinal direction to downward of the longitudinal direction. At an opposite region A, an upper side region A2 has a heat capacity larger than that of a lower region A1.

Description

  The present invention relates to a battery pack in which a secondary battery is installed on a heat absorbing member that is erected in a vertical direction.

  Examples of the battery pack in which the secondary batteries are stacked and arranged include a secondary battery device described in Patent Document 1. The secondary battery device described in Patent Document 1 includes a plurality of battery stack assemblies. The battery stack assembly includes a floor plate and a base plate fixed in a floor plate shape, and five battery modules are placed on the base plate. Side plates are provided between adjacent battery modules. A packing is placed on each battery module. Further, a base plate of the next stage is stacked on the side plate, the packing, and the battery module, and the battery module is placed on the base plate. Thereby, the battery modules are stacked and arranged.

JP 2011-54353 A

  By the way, when the battery modules (secondary batteries) arranged in a stacked manner generate heat, this heat moves upward in the vertical direction. For this reason, in the stacked battery module, the temperature of the upper battery module is likely to be higher than that of the lower battery module, and a temperature difference is generated between the upper battery module and the lower battery module.

  The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to reduce the temperature difference between secondary batteries in a plurality of secondary batteries arranged in the vertical direction. It is to provide a battery pack.

  A battery pack that solves the above problem includes a heat absorbing member that is erected in a vertical direction, and a plurality of secondary batteries that are installed on the heat absorbing member, wherein the heat absorbing member is a part of the plurality of secondary batteries. From the most vertically upper portion of the facing portion facing the secondary battery located in the uppermost vertical direction, the most vertical portion of the plurality of secondary batteries facing the secondary battery located in the lowermost vertical direction. When the region extending in the lower direction is divided into two at the vertical center of the region, the upper region in the vertical direction is the upper region, and the lower region is the upper region. The summary is that the heat capacity of is lower than the heat capacity of the lower region.

  According to this, when the secondary battery generates heat, this heat is absorbed by the heat absorbing member. In the heat-absorbing member, by increasing the heat capacity of the upper area in the vertical direction where the temperature increases, the temperature of the upper area in the vertical direction is unlikely to rise, and as a result, the heat of the secondary battery disposed on the upper side in the vertical direction is reduced. Easy to absorb. For this reason, the temperature difference between the secondary battery disposed on the lower side in the vertical direction and the secondary battery disposed on the upper side in the vertical direction can be reduced.

In the battery pack, the heat absorbing member is preferably a counterweight mounted on an industrial vehicle.
According to this, the counterweight mounted in an industrial vehicle can be utilized as a heat absorbing member. For this reason, it is not necessary to prepare an endothermic member separately, and the increase in a number of parts is suppressed.

  ADVANTAGE OF THE INVENTION According to this invention, the temperature difference of a secondary battery can be made small in the some secondary battery arrange | positioned at a perpendicular direction.

The schematic side view which shows the forklift of embodiment. The perspective view which shows the battery pack of embodiment. 3-3 sectional drawing of FIG. 2 which shows the battery module of embodiment. FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. 2 showing the battery pack of the embodiment. Sectional drawing which shows the battery pack of another example. Sectional drawing which shows the battery pack of another example. Sectional drawing which shows the battery pack of another example. Sectional drawing which shows the battery pack of another example.

  Hereinafter, an embodiment in which the battery pack is embodied as a battery pack mounted on a forklift will be described. In the following description, “front”, “rear”, “left”, “right”, “upper”, and “lower” are “front”, “rear”, and “left” when the forklift driver is facing the front of the forklift. ”,“ Right ”,“ upper ”, and“ lower ”.

  As shown in FIG. 1, drive wheels 12 are provided at the front lower part of a vehicle body 11 of a forklift 10 as an industrial vehicle, and steering wheels 13 are provided at a rear lower part of the vehicle body 11. In addition, a cargo handling device is provided at the front portion of the vehicle body 11. The mast 14 constituting the cargo handling apparatus is erected on the front portion of the vehicle body 11, and the mast 14 is provided with a pair of left and right forks 16 via a lift bracket 15. The fork 16 is lifted and lowered together with the lift bracket 15 by driving a lift cylinder 17 connected to the mast 14. Further, the fork 16 is tilted together with the mast 14 by driving a tilt cylinder 18 connected to the mast 14. A load 19 is mounted on the fork 16. The vehicle body 11 is equipped with a traveling motor M1 as a drive source for the drive wheels 12 and a cargo handling motor M2 as a drive source for the fork 16.

  A cab 20 is provided in the center of the vehicle body 11. The cab 20 is provided with a driving seat 21 on which an operator (driver) can sit. A handle 22 is provided in front of the driving seat 21. A battery pack 30 is mounted below the cab 20. Hereinafter, the battery pack 30 will be described in detail.

  As shown in FIG. 2, the battery pack 30 includes a counterweight 31 for balancing with the load 19 mounted on the fork 16. The counterweight 31 is erected in the thickness direction of the weight portion 32 from the weight portion 32 having a rectangular parallelepiped shape, and the one end 32a in the lateral direction of the weight portion 32, and the other end in the longitudinal direction from the longitudinal one end 32c of the weight portion 32 It consists of a plate-shaped weight main body 33 extending over 32d. In other words, the weight portion 32 is erected from the base end of the weight body 33 in the thickness direction of the weight body 33. The weight body 33 extends in the vertical direction.

  The weight main body 33 has a rectangular cross-sectional shape in the thickness direction (short direction of the weight portion 32). The longitudinal direction of the weight body 33 coincides with the longitudinal direction of the weight part 32, and the short direction of the weight body 33 coincides with the thickness direction of the weight part 32.

  At the distal end of the weight body 33 (the end opposite to the base end of the weight body 33), a notch 35 is formed by cutting the weight body 33 in the thickness direction of the weight body 33. The cutout portion 35 is provided on the first surface 33 a on which the weight portion 32 is provided, of both sides in the thickness direction of the weight main body 33.

  The weight main body 33 has a thickness that gradually increases from the lower side in the vertical direction to the upper side in the vertical direction on the second surface 33b on the opposite side to the first surface 33a of the both sides in the thickness direction of the weight main body 33. Part 34 is provided. The thick portion 34 extends on the second surface 33b from slightly below the portion facing the notch 35 to slightly above the portion facing the weight portion 32. The weight main body 33 and the thick portion 34 function as a heat absorbing member. In the present embodiment, the thick portion 34 is integrally formed with the counterweight 31 and is formed of a metal material such as iron, for example.

  An inverted U-shaped frame 41 that is spaced apart from the weight main body 33 is erected from the weight portion 32 at the other end 32 b in the short direction of the weight portion 32. The frame 41 includes a first pillar portion 43 and a second pillar portion 44 erected from two corners on the upper surface of the weight portion 32 at the other end 32b in the lateral direction, and a first pillar portion 43 and a second pillar portion 44. And a base portion 42 that connects the upper end portion of the column portion 44 (the end portion opposite to the end portion joined to the weight portion 32). That is, the battery pack 30 has a front opening 30 a surrounded by the weight 32 and the frame 41 on the other end 32 b side of the weight 32. In the battery pack 30, the front opening 30a is closed by a lid member 46 having a rectangular plate shape.

  The length in the standing direction of each pillar portion 43, 44 (the length in the longitudinal direction of each pillar portion 43, 44) is the same as the shortest length from the upper surface of the weight portion 32 to the distal end surface of the weight body 33. A top plate 47 is supported on the upper surface of the frame 41 and the upper surface of the weight main body 33. The top plate 47 closes an opening (not shown) between the weight body 33 and the frame 41. Further, the battery pack 30 has a weight main body 33, the weight portion 32, the first column portion 43, and one end side opening 30 b surrounded by the top plate 47 on the one end 32 c side of the weight portion 32 in the longitudinal direction. . Further, the battery pack 30 has the other end side opening 30c surrounded by the weight main body 33, the weight portion 32, the second column portion 44, and the top plate 47 on the other end 32d side of the weight portion 32 in the longitudinal direction. Have The one end side opening 30b and the other end side opening 30c are closed by a lid member 45.

  A plurality of battery modules 60 are provided on the first surface 33 a of the weight body 33. Two battery modules 60 provided in a row in the short direction of the weight body 33 are provided in two sets in the longitudinal direction of the weight body 33. A mounting plate 36 having a rectangular flat plate shape is fixed to the notch 35. On the mounting plate 36, a housing case 37 that houses a control device that controls the battery module 60 and a junction box 38 that houses a relay, wiring, and the like are disposed.

  As shown in FIG. 3, the battery module 60 is arranged in parallel with a square battery 61 as a secondary battery (for example, a lithium ion secondary battery or a nickel hydride storage battery) held by a battery holder 62. At the same time, a heat transfer plate 63 is interposed between the adjacent square batteries 61. In the battery module 60, end plates 64 are provided at both ends of the prismatic battery 61 in the parallel direction.

  A bracket 65 is fixed to the outer surface of each end plate 64 (the surface opposite to the surface facing the battery module 60). The battery module 60 is joined to the weight main body 33 by screwing the bolt B inserted through the bracket 65 into the weight main body 33.

  As shown in FIG. 4, the battery module 60 (square battery 61) is installed in a region facing the thick portion 34 of the weight body 33. Here, in the weight main body 33, among the plurality of prismatic batteries 61, from the uppermost part in the vertical direction in the facing portion that faces the prismatic battery 61 positioned at the uppermost position in the vertical direction, A region extending from the most vertically lower portion of the facing portion facing the rectangular battery 61 positioned most vertically downward is referred to as a facing region A. In the weight main body 33, the facing area A that faces the square batteries 61 that are stacked in the vertical direction is located within the range of the thick portion 34. In the present embodiment, the thick portion 34 is opposed to the rectangular battery 61 disposed most vertically downward from the uppermost portion of the portion facing the rectangular battery 61 disposed uppermost in the vertical direction. It extends to the lowermost part of the vertical direction.

  When the opposing area A of the weight body 33 is divided into two at the vertical center P of the opposing area A, the lower area A1 is the lower area in the vertical direction, and the upper area A2 is the upper area in the vertical direction. Since 34 is thicker upward in the vertical direction, the volume of the upper region A2 is larger than the volume of the lower region A1. Thereby, the heat capacity of the upper area A2 is larger than the heat capacity of the lower area A1.

Next, the operation of the battery pack 30 in this embodiment will be described.
When the battery module 60 (square battery 61) generates heat as the forklift 10 is driven, this heat is absorbed by the weight body 33 via the heat transfer plate 63 and the battery holder 62. At this time, the heat generated by the battery module 60 is also conducted to the air (heat medium) existing around the battery module 60. Since the heated air flows upward in the vertical direction, the square battery 61 installed on the upper side in the vertical direction is heated by the air.

  In the present embodiment, the counterweight 31 has a thick portion 34, and the square battery 61 is disposed so as to face the thick portion 34 that becomes thicker upward in the vertical direction. For this reason, the heat capacity of the portion facing the square battery 61 positioned on the upper side in the vertical direction is larger, and the heat of the weight body 33 is more easily absorbed by the square battery 61 positioned on the upper side in the vertical direction. By making it easy to absorb the heat of the square battery 61 on the upper side in the vertical direction where the temperature tends to rise, the temperature difference between the square batteries 61 arranged in the vertical direction can be reduced.

Therefore, according to the above embodiment, the following effects can be obtained.
(1) In the facing area A of the weight body 33 facing the prismatic battery 61, the heat capacity of the upper area A2 is larger than the heat capacity of the lower area A1. For this reason, the square battery 61 arranged on the upper side in the vertical direction where the temperature is likely to rise is more likely to absorb heat. For this reason, the temperature difference between the square batteries 61 arranged in the vertical direction can be reduced.

  (2) A part of the counterweight 31 (the weight main body 33) mounted on the forklift 10 is used as the heat absorbing member. For this reason, it is not necessary to provide an endothermic member separately, and the number of parts is reduced.

In addition, you may change the said embodiment as follows.
A counterweight 31 as shown in FIGS. 5 to 8 may be used. As shown in FIG. 5, the thickness of the thick portion 34 may gradually increase from the lower vertical direction to the upper vertical direction. As shown in FIG. 6, a plurality of convex portions 71 to 73 protruding from the weight main body 33 may be formed. The convex portions 71 to 73 have a larger volume as the convex portions 71 to 73 located on the upper side in the vertical direction. Specifically, the volume of the convex portion 73 provided at the uppermost position in the vertical direction is the largest, and the volume of the convex portion 71 provided at the lowermost position in the vertical direction is the smallest. And the volume of the convex part 72 located in the middle of the convex part 73 and the convex part 71 is larger than the volume of the convex part 71, and smaller than the volume of the convex part 73. As shown in FIG. 7, a block-shaped additional weight 81 may be provided only in the upper area A <b> 2 in the facing area A of the weight body 33. In this case, the whole including the additional weight 81 and the counter weight 31 in the embodiment is a counter weight. As shown in FIG. 7, the additional weight 81 may be fixed by bolt fastening by screwing the bolt B <b> 2 to the weight body 33 or by fixing with an adhesive.

  As shown in FIG. 8, the thick part of the counterweight may be formed of a member separate from the counterweight. The counterweight 31 includes a first member 93 having a weight portion 91 and a rectangular parallelepiped standing portion 92 erected from the weight portion 91. The standing member 92 of the first member 93 is provided with a rectangular parallelepiped second member 94 that is connected to the standing member 92 and forms the weight main body 33 together with the standing member 92. A thick member 95 serving as a thick portion is provided on the second surface 33 b of the counterweight 31.

  In the embodiment, the thick portion 34 may extend to the lowermost portion of the second surface 33b (the lower surface of the weight portion 32). That is, the thick portion 34 is not limited to being provided only in the region facing the square battery 61, and may be provided beyond the facing region A facing the square battery 61.

  In the embodiment, the battery modules 60 (rectangular batteries 61) arranged in a stack may be arranged at intervals in the vertical direction. Even in this case, the endothermic member is the most in the portion facing the rectangular battery 61 provided on the uppermost side in the vertical direction from the lowermost portion in the portion facing the rectangular battery 61 provided on the lowermost side in the vertical direction. When the region (opposite region A) over the upper part in the vertical direction is divided into two at the vertical center P of the region, the upper region in the vertical direction is defined as the upper region A2, and the lower region in the vertical direction is defined as the lower region. When A1 is set, the heat capacity of the upper region A2 only needs to be larger than the heat capacity of the lower region A1. That is, the heat absorbing member in the present embodiment includes the horizontal line L1 passing through the point in the uppermost vertical direction in the portion facing the battery cell (square battery 61) provided in the uppermost vertical direction, and the battery provided in the lowermost vertical direction. Vertical when a region between the cell (square battery 61) and a horizontal line L2 passing through a point in the vertical direction at the lowest part is divided into two by a horizontal line L passing through a point at the center P in the vertical direction of the region. When the upper area A2 and the upper area A2 are used, and the lower area A1 is the lower area A1, the heat capacity of the upper area A2 only needs to be larger than the heat capacity of the lower area A1.

In the embodiment, the thick portion 34 may be formed only within the range of the facing region A.
In the embodiment, a heat absorbing member other than the weight main body 33 of the counterweight 31 may be used. For example, when the battery pack 60 is configured by fixing the battery module 60 to the housing, the side wall of the housing extending in the vertical direction serves as a heat absorbing member.

  In the embodiment, the shape of the weight portion 32 may be any shape. Similarly, the weight main body 33 may have any shape. For example, it may be a circular shape in plan view or a polygonal shape such as a triangular shape or a quadrangular shape.

  In the embodiment, the battery module 60 may be a cylindrical battery or a battery module in which laminated batteries are arranged in parallel. That is, the secondary battery may be a cylindrical battery or a laminated battery.

  In the embodiment, the square battery 61 may not be held by the battery holder 62. That is, the battery module 60 may not include the battery holder 62. Further, the battery module 60 may not include the heat transfer plate 63.

In the embodiment, the counterweight 31 may be configured only from the weight body 33.
A counterweight provided on a power shovel (industrial vehicle) may be used as a heat absorbing member.

  A ... opposing area, A1 ... lower area, A2 ... upper area, 10 ... forklift, 30 ... battery pack, 31 ... counterweight, 33 ... weight body, 60 ... battery module, 61 ... square battery.

Claims (2)

An endothermic member erected in the vertical direction;
A plurality of secondary batteries installed on the heat absorbing member,
The heat-absorbing member extends from the most vertically upper part of the opposed part facing the secondary battery located most vertically above the plurality of secondary batteries to the most vertically lower part of the plurality of secondary batteries. The region extending from the most vertically lower portion of the facing portion facing the secondary battery located in the vertical direction when the region is divided into two at the vertical center of the region is defined as the upper region, and the vertically lower side. The battery pack is characterized in that when the region is a lower region, the heat capacity of the upper region is larger than the heat capacity of the lower region.   The battery pack according to claim 1, wherein the heat absorbing member is a counterweight mounted on an industrial vehicle.