JP2021089790A - Battery temperature control device - Google Patents

Abstract

To provide a battery temperature control device which enables temperature equalization of a plurality of laminated battery cells by exchanging heat with a heating medium circulating through a heat exchanger.SOLUTION: A battery temperature control device 1 has a plurality of battery cells 11, a connection member 40, a first heat exchanger 20, and a second heat exchanger 30. The plurality of battery cells 11 are laminated in a predetermined lamination direction. The connection member 40 is disposed between the plurality of battery cells 11 aligned in the lamination direction, and has an inlet part 42 and an outlet part 43 for a heating medium. The first heat exchanger 20 exchanges heat between the heating medium and those of the plurality of battery cells 11 disposed on one side in the lamination direction with respect to the connection member 40. Further, the first heat exchanger has a plurality of heat exchange parts 21 and a first folded part 23. The second heat exchanger 30 exchanges heat between the heating medium and those of the plurality of battery cells 11 disposed on the other side in the lamination direction with respect to the connection member 40. Further, the second heat exchanger has a plurality of heat exchange parts 31 and a second folded part 33.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a battery temperature control device that adjusts the temperature of a battery.

Conventionally, the technique described in Patent Document 1 is known as a battery temperature control device that adjusts the temperature of a plurality of stacked battery cells. In the battery temperature control device of Patent Document 1, a heat exchanger in which a heat medium flows inside is arranged in a meandering shape through between adjacent battery cells among a plurality of battery cells arranged in a stacked manner. There is.

Special Table 2016-526763A

However, in the configuration of Patent Document 1, the inlet and outlet of the heat medium are arranged on one side in the stacking direction of the battery cells, and the heat medium exchanges heat with the battery cells and is a heat exchanger. It circulates inside. Then, the flow of the heat medium in the heat exchanger is folded back on the other side in the stacking direction of the battery cells.

Therefore, when the configuration of Patent Document 1 is adopted and the number of battery cells constituting the battery module is increased, the temperature difference between the battery cells may increase depending on the positional relationship in the stacking direction of the battery module. It is conceivable that the temperature of each battery cell will vary.

In view of the above points, it is an object of the present disclosure to provide a battery temperature control device that realizes temperature equalization of a plurality of battery cells arranged in a stack by heat exchange with a heat medium flowing through a heat exchanger. ..

The battery temperature control device according to one aspect of the present disclosure includes a plurality of battery cells (11), a connecting member (40), a first heat exchanger (20), and a second heat exchanger (30). Have. The plurality of battery cells are stacked in a predetermined stacking direction. The connecting member is arranged between the battery cells arranged in the stacking direction, and has an inflow portion (42) and an outflow portion (43) of a heat medium that exchanges heat with the plurality of battery cells.

The first heat exchanger exchanges heat between a battery cell arranged on one side of the connecting member in the stacking direction and a heat medium circulated through the connecting member in a plurality of battery cells. Then, the second heat exchanger exchanges heat between the battery cells arranged on the other side of the connecting member in the stacking direction and the heat medium circulated through the connecting member in the plurality of battery cells.

Further, the first heat exchanger has a plurality of heat exchange portions (21) and a first folded portion (23). The plurality of heat exchange units are arranged so that heat can be exchanged with respect to the battery cell on one side in the stacking direction with respect to the connecting member. The first folded portion is arranged on the most one side in the stacking direction of the plurality of battery cells, and the flow of the heat medium passing through the plurality of heat exchange portions is folded back toward the outflow portion of the connecting member.

The second heat exchanger has a plurality of heat exchange portions (31) and a second folded portion (33). The plurality of heat exchange units are arranged so as to be heat exchangeable with respect to the battery cell on the other side in the stacking direction with respect to the connecting member. The second folded-back portion is arranged on the most opposite side in the stacking direction of the plurality of battery cells, and the flow of the heat medium passing through the plurality of heat exchange portions is folded back toward the outflow portion of the connecting member.

According to this, the temperature is adjusted by the first heat exchanger on one side of the plurality of battery cells in the stacking direction with respect to the connecting member, and the temperature of the plurality of battery cells is adjusted with respect to the connecting member in the stacking direction. On the side, the temperature is adjusted by the second heat exchanger.

When a plurality of battery cells are arranged in the stacking direction, it is considered that the battery cells 11 located outside the stacking direction are more likely to dissipate heat, and the batteries cells located inside are more likely to generate heat. In this regard, according to the battery temperature control device, the connecting member can be arranged at a position where heat buildup is likely to occur, so that the generation of heat buildup can be suppressed and the temperature of each battery cell can be equalized. Can be done.

Further, according to the battery temperature control device, even when the number of battery cells is increased, the path of the heat medium from the inflow portion to the outflow portion can be shortened, and the temperature of each battery cell can be adjusted. It is possible to suppress the variation and realize the equalization of the temperature of a plurality of battery cells.

The reference numerals in parentheses of each means described in this column and in the claims indicate the correspondence with the specific means described in the embodiments described later.

It is explanatory drawing which shows the structure of the battery temperature control device which concerns on 1st Embodiment. It is a top view of the battery temperature control device which concerns on 1st Embodiment. It is a front view of the battery temperature control device which concerns on 1st Embodiment. It is a partial cross-sectional view which shows the arrangement of the heat exchange part with respect to a battery cell. It is explanatory drawing which shows the flow of the heat medium in the outbound side flow path of 1st Embodiment. It is explanatory drawing which shows the flow of the heat medium in the return path side flow path of 1st Embodiment. It is a top view of the battery temperature control device which concerns on 2nd Embodiment. It is explanatory drawing which shows the flow of the heat medium in the outbound side flow path of 2nd Embodiment. It is explanatory drawing which shows the flow of the heat medium in the return path side flow path of 2nd Embodiment. It is a top view of the battery temperature control device which concerns on 3rd Embodiment. It is a top view of the battery temperature control device which concerns on 4th Embodiment.

(First Embodiment)
Hereinafter, embodiments will be described with reference to the drawings. In the following embodiments, parts that are the same or equal to each other are designated by the same reference numerals in the drawings.

First, the schematic configuration of the battery temperature control device according to the first embodiment will be described with reference to the drawings. When the following description is made using the front-back, left-right, up-down directions, it indicates the front-back, left-right, up-down directions when the direction in which the inflow portion 42 and the outflow portion 43 are arranged in the battery temperature control device 1 is the front. And. The same definition is used for the arrows shown in each figure as appropriate, and the stacking direction corresponds to the left-right direction.

As shown in FIGS. 1 to 6, the battery temperature control device 1 according to the first embodiment includes a battery module 10, a first heat exchanger 20, a second heat exchanger 30, a connecting member 40, and a first. It has one end plate 50, a second end plate 51, and a restraint member 55. The battery temperature control device 1 adjusts the temperature of each battery cell 11 constituting the battery module 10 by exchanging heat with a heat medium flowing inside the first heat exchanger 20 and the second heat exchanger 30. As the heat medium, for example, an ethylene glycol-based antifreeze solution (LLC) can be used.

As shown in FIGS. 1 to 6, the battery module 10 is composed of a plurality of battery cells 11 stacked and arranged in a predetermined stacking direction (left-right direction in the present embodiment). In the present embodiment, the battery module 10 is configured by stacking eight battery cells 11. In the present embodiment, the left direction corresponds to one side in the stacking direction, and the right direction corresponds to the other side in the stacking direction.

The battery cell 11 has a flat shape having a flat plate surface. The battery cell 11 of the present embodiment has a flat rectangular parallelepiped shape and has a rectangular plate surface. The plurality of battery cells 11 are arranged in parallel so that their plate surfaces are parallel to each other. The plate surface of the battery cell 11 is orthogonal to the stacking direction of the battery cell 11.

As the battery cell 11, any kind of battery can be used, and in this embodiment, a lithium ion battery is used. A lithium ion battery is a rechargeable secondary battery. The surface of the battery cell 11 is covered with an insulating film made of polypropylene, for example. As the battery cell 11, a battery having a shape such as a square type or a laminated type can be preferably used.

As shown in FIGS. 1 to 3, and the like, the connecting member 40 is arranged at the central portion of the battery module 10 in the stacking direction. Like each battery cell 11, the connecting member 40 is formed in a flat rectangular parallelepiped shape, and is made of a metal material having good thermal conductivity (for example, aluminum, stainless steel, etc.).

In the first embodiment, the connecting member 40 is arranged so as to be sandwiched between two battery cells 11 forming a central portion in the stacking direction of the battery modules 10. Here, since the left and right side surfaces of the connecting member 40 are arranged so as to be in contact with the battery cell 11, heat exchange is performed between the heat medium flowing in the connecting member 40 and the battery cell 11.

Further, an inflow portion 42 and an outflow portion 43 are provided on the front surface of the connecting member 40. As shown in FIGS. 5 and 6, an internal flow path 41 through which a heat medium flows is formed inside the connecting member 40. The inflow section 42 causes the heat medium to flow into the internal flow path 41 of the connecting member 40. The outflow portion 43 causes the heat medium flowing through the internal flow path 41 to flow out to the outside of the connecting member 40.

In the first embodiment, the first connecting portion 44 and the second connecting portion 45 are provided on the rear surface of the connecting member 40. The first connecting portion 44 is formed on the left side of the rear surface of the connecting member 40, and is a portion to which the flat multi-hole tube constituting the first heat exchanger 20 is connected. Therefore, the internal flow path 41 of the connecting member 40 and the inside of the first heat exchanger 20 are connected via the first connecting portion 44 so that the heat medium can flow in and out.

As shown in FIGS. 5 and 6, the second connecting portion 45 is formed on the right side of the rear surface of the connecting member 40, and is a portion to which the flat multi-hole tube constituting the second heat exchanger 30 is connected. .. Therefore, the internal flow path 41 of the connecting member 40 and the inside of the second heat exchanger 30 are connected via the second connecting portion 45 so that the heat medium can flow in and out. Therefore, the internal flow path 41 communicates the first connection portion 44 and the second connection portion 45 with the inflow portion 42 and the outflow portion 43.

In the battery temperature control device 1, a heat medium circulates inside the first heat exchanger 20 and the second heat exchanger 30, and heat exchange between the battery cell 11 and the heat medium is performed. As a result, the battery cell 11 is cooled or heated, and the temperature of the battery cell 11 is adjusted.

The first heat exchanger 20 and the second heat exchanger 30 have a strip-shaped member, and are configured by using, for example, a flat multi-hole tube made of aluminum. As shown in FIGS. 1 to 3, the first heat exchanger 20 is arranged on the left side of the connecting member 40 in the battery temperature control device 1. The second heat exchanger 30 is arranged on the right side of the connecting member 40 in the battery temperature control device 1. In FIGS. 4 to 6, the restraint member 55 is not shown.

As shown in FIG. 2 and the like, the first heat exchanger 20 has a plurality of heat exchange portions 21 and a plurality of curved portions 22. In the first heat exchanger 20, the heat exchange section 21 is a flat plate-shaped portion sandwiched between the two battery cells 11 and has a shape corresponding to the plate surface of the battery cells 11. The curved portion 22 is a portion curved so as to connect the adjacent heat exchange portions 21. The heat exchange portion 21 is in contact with the battery cell 11, and the curved portion 22 is not in contact with the battery cell 11.

The plurality of heat exchange units 21 are arranged in parallel on the left side of the connecting member 40 at predetermined intervals in the stacking direction. The heat exchange section 21 is arranged so that the plate surface is orthogonal to the cell stacking direction, and as shown in FIGS. 5 and 6, the heat medium flow direction is orthogonal to the cell stacking direction.

In the first heat exchanger 20, adjacent heat exchange portions 21 are connected by curved portions 22 and are formed in a meandering shape. That is, the first heat exchanger 20 is a serpentine type that is bent in a meandering shape.

Therefore, on the left side of the connecting member 40, the heat exchange portions 21 of the first heat exchanger 20 are arranged so that the battery cells 11 and the heat exchange portions 21 are alternately laminated. That is, one or more battery cells 11 are arranged between the adjacent heat exchange units 21.

As shown in FIG. 2, a first folded-back portion 23 is provided at the left end portion of the first heat exchanger 20. The first folded-back portion 23 is located between the battery cell 11 located on the leftmost side of the battery module 10 and the first end plate 50 in the stacking direction. The first folded-back portion 23 is a portion of the first heat exchanger 20 that folds back the flow of the heat medium flowing in from the inflow portion 42 toward the outflow portion 43.

Here, the internal structure of the first heat exchanger 20 will be described with reference to the drawings. FIG. 4 shows a cross section of the first heat exchanger 20 orthogonal to the heat medium flow direction, and shows two battery cells 11 and three heat exchange units 21.

As described above, the first heat exchanger 20 is composed of a flat multi-hole tube. Therefore, the first heat exchanger 20 has a plurality of heat medium flow paths 24 separated by the partition portion 25.

As shown in FIGS. 3 and 4, the plurality of heat medium flow paths 24 formed in the upper portion of the first heat exchanger 20 form the outward path side flow path 24o, and are located in the lower portion of the first heat exchanger 20. The formed plurality of heat medium flow paths 24 form a return path side flow path 24r. In the outward path side flow path 24o and the return path side flow path 24r, the total of the cross-sectional areas of the respective flow paths is equal.

The outward flow path 24o is a flow path through which the heat medium flows from the inflow portion 42 to the first folded portion 23 in the first heat exchanger 20. That is, the outward path side flow path 24o constitutes the upstream side of the first folded-back portion 23 with respect to the flow of the heat medium in the first heat exchanger 20.

The return path side flow path 24r is a flow path through which the heat medium flows from the first folded portion 23 to the outflow portion 43 in the first heat exchanger 20. That is, the return path side flow path 24r constitutes the downstream side of the first folding portion 23 with respect to the flow of the heat medium in the first heat exchanger 20.

On the other hand, the second heat exchanger 30 is arranged on the right side of the battery temperature control device 1, and has a plurality of heat exchange portions 31 and a plurality of curved portions 32, similarly to the first heat exchanger 20. .. The heat exchange unit 31 is a flat plate-shaped portion sandwiched between the two battery cells 11 in the second heat exchanger 30, and has a shape corresponding to the plate surface of the battery cells 11. The curved portion 32 is a portion curved so as to connect the adjacent heat exchange portions 31.

Therefore, the second heat exchanger 30 is formed in a meandering shape in which adjacent heat exchange portions 31 are connected by curved portions 32, similarly to the first heat exchanger 20, and constitutes a so-called serpentine type heat exchanger. ing.

Therefore, on the right side of the connecting member 40, the heat exchange portions 31 of the second heat exchanger 30 are arranged so that the battery cells 11 and the heat exchange portions 31 are alternately laminated. That is, one or more battery cells 11 are arranged between the adjacent heat exchange units 31.

Then, as shown in FIG. 2, a second folded-back portion 33 is provided at the right end portion of the second heat exchanger 30. The second folded-back portion 33 is located between the battery cell 11 located on the rightmost side of the battery module 10 and the second end plate 51 in the stacking direction. The second folded-back portion 33 is a portion of the second heat exchanger 30 that folds the flow of the heat medium flowing in from the inflow portion 42 toward the outflow portion 43.

As described above, the second heat exchanger 30 is composed of a flat multi-hole tube like the first heat exchanger 20. Therefore, like the first heat exchanger 20, the second heat exchanger 30 has a plurality of heat medium flow paths separated by a partition portion, and these heat medium flow paths are outward flow side flows. It constitutes a road 34o and a return path side flow path 34r.

Specifically, as shown in FIG. 3, a plurality of heat medium flow paths formed in the upper portion of the second heat exchanger 30 form an outward flow path side flow path 34o. The outward flow path 34o is a flow path through which the heat medium flows from the inflow portion 42 to the second folded portion 33 in the second heat exchanger 30. That is, the outward path side flow path 34o constitutes the upstream side of the second folded-back portion 33 with respect to the flow of the heat medium in the second heat exchanger 30.

Further, the plurality of heat medium flow paths formed in the lower portion of the second heat exchanger 30 form a return path side flow path 34r. The return path side flow path 34r is a flow path through which the heat medium flows from the second folded-back portion 33 to the outflow portion 43 in the second heat exchanger 30. That is, the return path side flow path 34r constitutes the downstream side of the second folded-back portion 33 with respect to the flow of the heat medium in the second heat exchanger 30. Further, in the outward path side flow path 34o and the return path side flow path 34r, the total of the cross-sectional areas of the respective flow paths is equal.

Since the first heat exchanger 20 and the second heat exchanger 30 configured in this way both use a flat multi-hole tube, they can be formed by, for example, extrusion molding. In the present embodiment, one flat multi-hole tube is formed by extrusion molding, and then the portion corresponding to the curved portion is bent to form a meandering shape. Therefore, in the first heat exchanger 20 and the second heat exchanger 30, the heat exchange portion and the curved portion are integrally formed.

In the battery temperature control device 1, the first end plate 50 and the second end plate 51 are arranged on both ends in the stacking direction of the battery modules 10. The first end plate 50 and the second end plate 51 have a shape corresponding to the battery cell 11, and are laminated together with the battery cell 11.

As shown in FIG. 1 and the like, the first end plate 50 is arranged outside the battery module 10 on one side (that is, the left side) in the stacking direction. On the other hand, the second end plate 51 is arranged outside the battery module 10 on the other side (that is, the right side) in the stacking direction.

The first end plate 50 and the second end plate 51 are connected by a plurality of restraint members 55. The restraint member 55 is provided so as to connect the corresponding corners of the first end plate 50 and the second end plate 51.

As a result, the plurality of battery cells 11, the first heat exchanger 20, and the second heat exchanger 30 are in a state where a predetermined restraint load is applied between the first end plate 50 and the second end plate 51. , It is fixed by the restraint member 55.

Further, as shown in FIGS. 1 to 3, a connecting member 40 arranged at the center of the battery module 10 in the stacking direction is also connected to each restraining member 55. Therefore, in the left side portion of the battery temperature control device 1, the battery cell 11 and the first heat exchanger 20 are in a state where a predetermined restraint load is applied between the connection member 40 and the first end plate 50. It is fixed.

Similarly, in the right side portion of the battery temperature control device 1, the battery cell 11 and the second heat exchanger 30 are fixed between the connecting member 40 and the second end plate 51 in a state where a predetermined restraint load is applied. Will be done. That is, the connecting member 40 according to the present embodiment functions as a so-called intermediate plate.

Subsequently, the flow of the heat medium in the battery temperature control device 1 according to the first embodiment will be described with reference to FIGS. 5 and 6.

As shown in FIG. 5, the internal flow path 41 of the connecting member 40 has at least a flow path extending to the first connecting portion 44 and a flow path extending to the second connecting portion 45 with respect to the flow path extending from the inflow portion 42. It is connected and configured. Therefore, the flow of the heat medium flowing in from the inflow portion 42 branches into a flow to the first heat exchanger 20 side and a flow to the second heat exchanger 30 side inside the internal flow path 41.

First, the flow of the heat medium on the first heat exchanger 20 side will be described. The heat medium flowing out from the first connection portion 44 flows into the outward path side flow path 24o in the first heat exchanger 20. In the process of flowing through the outward flow path 24o, the heat medium passes through the plurality of heat exchange portions 21 and the plurality of curved portions 22.

At this time, the heat medium flows through between the four battery cells 11 located on the left side of the connecting member 40 while meandering to one side in the stacking direction of the battery modules 10. Therefore, the heat medium adjusts the temperature of the four battery cells 11 by heat exchange with the four battery cells 11 located on the left side of the connecting member 40, and flows into the first folded portion 23.

Inside the first folded-back portion 23, the heat medium flows downward and flows into the return path side flow path 24r of the first heat exchanger 20. As a result, in the first folding section 23, the flow of the heat medium that has passed from the inflow section 42 to the outward path side flow path 24o can be turned back toward the outflow section 43.

As shown in FIG. 6, when the heat medium flows out from the first folded-back portion 23, the heat medium flows into the return path side flow path 24r of the first heat exchanger 20. In the process of flowing through the return path side flow path 24r, the heat medium passes through the plurality of heat exchange portions 21 and the plurality of curved portions 22.

At this time, the heat medium meanders through between the four battery cells 11 located on the left side of the connecting member 40 and flows toward the central portion of the battery module 10 in the stacking direction. Therefore, the heat medium can adjust the temperature of the four battery cells 11 by exchanging heat with the four battery cells 11 located on the left side of the connecting member 40. After passing through the return path side flow path 24r, the heat medium flows into the internal flow path 41 of the connecting member 40 via the first connecting portion 44.

Next, the flow of the heat medium on the second heat exchanger 30 side will be described. The heat medium flowing out from the second connection portion 45 flows into the outbound flow path 34o in the second heat exchanger 30. In the process of flowing through the outward flow path 34o, the heat medium passes through the plurality of heat exchange portions 31 and the plurality of curved portions 32.

At this time, the heat medium meanders through between the four battery cells 11 located on the right side of the connecting member 40 and flows toward the other side in the stacking direction of the battery modules 10. Therefore, the heat medium adjusts the temperature of the four battery cells 11 by heat exchange with the four battery cells 11 located on the right side of the connecting member 40, and flows into the second folded portion 33.

Inside the second folded-back portion 33, the heat medium flows downward and flows into the return path side flow path 34r of the second heat exchanger 30. As a result, in the second folding section 33, the flow of the heat medium that has passed from the inflow section 42 to the outward flow path 34o can be turned back toward the outflow section 43.

As shown in FIG. 6, when the heat medium flows out from the second folded-back portion 33, the heat medium flows into the return path side flow path 34r of the second heat exchanger 30. In the process of flowing through the return path side flow path 34r, the heat medium passes through the plurality of heat exchange portions 31 and the plurality of curved portions 32.

At this time, the heat medium meanders through between the four battery cells 11 located on the right side of the connecting member 40 and flows toward the central portion of the battery module 10 in the stacking direction. Therefore, the heat medium can adjust the temperature of the four battery cells 11 by exchanging heat with the four battery cells 11 located on the right side of the connecting member 40. After passing through the return path side flow path 34r, the heat medium flows into the internal flow path 41 of the connecting member 40 via the second connecting portion 45.

As a result, inside the internal flow path 41 of the connecting member 40, the flow of the heat medium flowing in from the first connecting portion 44 and the flow of the heat medium flowing in from the second connecting portion 45 merge. The heat medium merged in the internal flow path 41 flows out from the outflow portion 43 to the outside of the battery temperature control device 1.

As shown in FIGS. 5 and 6, according to the battery temperature control device 1, the flow of the heat medium at the connecting member 40, the flow of the heat medium to the first heat exchanger 20 side, and the second heat exchanger. It is branched into the flow of the heat medium to the 30 side.

In the first heat exchanger 20, the flow of the heat medium is such that the temperature of a part of the plurality of battery cells 11 constituting the battery module 10 (that is, the four battery cells 11 on the left side of the connecting member 40) is adjusted. The road is arranged.

On the other hand, in the second heat exchanger 30, heat is adjusted so as to adjust the temperature of the other parts of the plurality of battery cells 11 constituting the battery module 10 (that is, the four battery cells 11 on the right side of the connecting member 40). The flow path of the medium is arranged.

That is, both the flow path of the heat medium passing through the first heat exchanger 20 and the flow path of the heat medium passing through the second heat exchanger 30 target the eight battery cells 11 constituting the battery module 10. It is configured to be shorter than the case where the heat medium flow path is arranged. As a result, according to the battery temperature control device 1, the pressure loss of the heat medium flowing from the inflow portion 42 to the outflow portion 43 can be reduced.

Further, since the battery module 10 has a plurality of battery cells 11 stacked and arranged, heat buildup is likely to occur in the battery cells 11 at the center in the stacking direction. As shown in FIGS. 5 and 6, since the connecting member 40 is arranged at the center of the battery module 10 in the stacking direction, the battery temperature control device 1 can be cooled from the battery cell 11 in which heat buildup is likely to occur. The temperature difference between the battery cells 11 constituting the battery module 10 can be reduced.

Here, as shown in FIG. 1, a communication unit 60 and a flow rate adjusting unit 65 are arranged on the connecting member 40 of the battery temperature control device 1. The communication unit 60 is communicably connected to the control device 70 and communicates cell information of each battery cell 11 constituting the battery module 10.

The cell information includes information on the temperature of the battery cell 11 and information on the output voltage of the battery cell 11. As information on the temperature of the battery cell 11, output results of various sensors such as a battery temperature sensor (not shown) can be used.

As shown in FIG. 1, the communication unit 60 is provided so as to come into contact with the upper surface of the connecting member 40. The connecting member 40 is made of a metal having good thermal conductivity, and an internal flow path 41 through which a heat medium flows is formed inside the connecting member 40. Therefore, the battery temperature control device 1 can absorb the heat of the communication unit 60 generated by the operation through the connecting member 40 through which the heat medium flows, and can cool the communication unit.

The flow rate adjusting unit 65 determines the flow rate of the heat medium flowing from the first connection unit 44 toward the first heat exchanger 20 and the flow rate of the heat medium flowing from the second connection unit 45 to the second heat exchanger 30 with respect to the heat medium flowing from the inflow unit 42. Adjust the flow rate of the heat medium flowing toward.

The flow rate adjusting unit 65 is arranged at a branch portion in the internal flow path 41, and for example, an electric three-way flow rate adjusting valve having three inflow ports can be used. The operation of the flow rate adjusting unit 65 is controlled by the control signal output from the control device 70.

A plurality of solenoid valves may be used as the flow rate adjusting unit 65. That is, the flow rate adjusting unit 65 may be configured by a solenoid valve that adjusts the opening degree of the flow path toward the first connecting portion 44 and an electromagnetic valve that adjusts the opening degree of the flow path toward the second connecting portion 45. ..

The control device 70 includes a well-known microcomputer including a CPU, ROM, RAM, and the like, and peripheral circuits thereof. Then, the control device 70 performs various calculations and processes based on the control program stored in the ROM to control the operation of the various controlled devices.

Regarding the battery temperature control device 1, the control device 70 has a temperature within a predetermined temperature range of each battery cell 11 of the battery module 10 based on the cell information of each battery cell 11 acquired by communication with the communication unit 60. The control signal related to the operation of the flow rate adjusting unit 65 is determined so as to be. The predetermined temperature range is, for example, 15 ° C. or higher and 55 ° C. or lower.

Specifically, the control device 70 first determines the temperature of the battery cell 11 located on the left side of the connecting member 40 and the battery cell 11 located on the right side of the connecting member 40 based on the cell information acquired from the communication unit 60. Compare with the temperature of.

When it is determined that the temperature of the battery cell 11 on the left side of the connecting member 40 is higher than the temperature of the battery cell 11 on the right side, the control device 70 has an opening degree in the flow path on the first connecting portion 44 side of the second connecting portion. The control signal is determined so as to be larger than the opening degree in the flow path on the 45 side.

On the other hand, when it is determined that the temperature of the battery cell 11 on the right side of the connecting member 40 is higher than the temperature of the battery cell 11 on the left side, the control device 70 has a first opening degree in the flow path on the second connecting portion 45 side. The control signal is determined so as to be larger than the opening degree in the flow path on the connection portion 44 side.

The balance between the opening degree in the flow path on the first connecting portion 44 side and the opening degree in the flow path on the second connecting portion 45 side is the temperature of the battery cell 11 on the right side of the connecting member 40 and the battery on the left side of the connecting member 40. It is determined according to the temperature difference from the temperature of the cell 11.

By the operation of the flow rate adjusting unit 65, it is controlled so that a larger amount of heat medium flows into the side of the first heat exchanger 20 and the second heat exchanger 30 where the high temperature battery cell 11 is arranged. Will be done. As a result, the battery cell 11 having a high temperature exchanges heat with a larger amount of heat medium. Therefore, the temperature difference between the battery cells 11 constituting the battery module 10 is reduced to equalize the temperature of the battery cell 11. Can be realized.

As described above, in the battery temperature control device 1 according to the present embodiment, the connection member 40 arranged at the center of the battery module 10 in the stacking direction is connected to the first heat exchanger 20 on one side in the stacking direction and the stacking direction. The heat medium can be circulated to the second heat exchanger 30 on the other side.

As a result, in the battery module 10, the temperature of each battery cell 11 located on one side of the connecting member 40 in the stacking direction is adjusted by the first heat exchanger 20. Further, the temperature of each battery cell 11 located on the other side of the connecting member 40 in the stacking direction is adjusted by the second heat exchanger 30.

Here, when a plurality of battery cells 11 are arranged in the stacking direction, the battery cells 11 located outside the stacking direction are more likely to dissipate heat, and the battery cells 11 located inside are more likely to generate heat. Conceivable.

In this regard, according to the battery temperature control device 1, since the connecting member 40 is arranged at a position where heat buildup is likely to occur, the generation of heat buildup inside the stacking direction of the battery module 10 is suppressed, and each battery is used. The temperature of the cell 11 can be equalized.

Further, according to the battery temperature control device 1, even when the number of battery cells 11 is increased, the path of the heat medium from the inflow portion 42 to the outflow portion 43 can be shortened, and each battery can be shortened. It is possible to suppress the variation in the temperature of the cells 11 and realize the equalization of the temperatures of the plurality of battery cells 11.

As shown in FIGS. 5 and 6, the connecting member 40 has an inflow portion 42, an outflow portion 43, a first connection portion 44, and a second connection portion 45. Inside the connecting member 40, the internal flow path 41 communicates the first connecting portion 44 and the second connecting portion 45 with the inflow portion 42 and the outflow portion 43.

As a result, the heat medium flows through the first folded-back portion 23 and the first heat exchanger 20 by circulating through the internal flow path 41, the first connecting portion 44, and the second connecting portion 45 of the connecting member 40. And, the flow of the heat medium through the second folded-back portion 33 and the second heat exchanger 30 can be realized.

As shown in FIGS. 1 to 3, the positions of the connecting member 40 with respect to the first end plate 50 and the second end plate 51 are fixed by the plurality of restraining members 55. That is, the connecting member 40 functions as a so-called intermediate plate.

As a result, the battery temperature control device 1 uses the connecting member 40 as an intermediate plate between the first end plate 50 and the second end plate 51 to exchange heat with each battery cell 11, the heat exchange unit 21, and the heat exchange unit 21. The adhesion with the portion 31 can be improved. As a result, it is possible to prevent the heat dissipation capacity from being reduced due to the contact thermal resistance between each battery cell 11 and the heat exchange unit 21 and the heat exchange unit 31.

Then, as shown in FIG. 1 and the like, a communication unit 60 that communicates cell information of each battery cell 11 constituting the battery module 10 to the control device 70 is arranged on the upper surface of the connection member 40. The communication unit 60 is arranged so as to exchange heat with the heat medium flowing through the internal flow path 41 of the connecting member 40 with respect to the connecting member 40.

As a result, according to the battery temperature control device 1, the heat generated in the communication unit 60 can be absorbed through the connecting member 40 through which the heat medium flow path 24 flows. That is, according to the battery temperature control device 1, the communication unit 60 can be kept within an appropriate temperature range, and malfunction of the communication unit 60 due to heat can be prevented.

Further, as shown in FIG. 1 and the like, the flow rate adjusting unit 65 is arranged on the connecting member 40. Based on the control signal from the control device 70, the flow rate adjusting unit 65 determines the flow rate of the heat medium flowing from the first connection unit 44 toward the first heat exchanger 20 and the flow rate of the heat medium flowing in from the inflow unit 42. 2 Adjust the flow rate of the heat medium flowing from the connection portion 45 toward the second heat exchanger 30.

Based on the cell information acquired from the communication unit 60, the control device 70 sends a control signal regarding the operation of the flow rate adjusting unit 65 so that the temperature of each battery cell 11 of the battery module 10 is within a predetermined temperature range. decide.

As a result, according to the battery temperature control device 1, the flow rate adjusting unit 65 is operated to adjust the flow rate of the heat medium on the first heat exchanger 20 side and the flow rate of the heat medium on the second heat exchanger 30 side. By doing so, the temperature of each battery cell 11 can be kept within a predetermined temperature range to equalize the temperature. Further, by using the cell information from the communication unit 60, the flow rate of the heat medium on the first heat exchanger 20 side and the flow rate of the heat medium on the second heat exchanger 30 side can be adjusted more accurately. Can be done.

(Second Embodiment)
In the present embodiment, as shown in FIGS. 7 to 9, the battery temperature control device 1 in which the configurations of the first heat exchanger 20, the second heat exchanger 30, and the connecting member 40 are different from those in the first embodiment will be described. .. In FIG. 7, the same or equal parts as those in the first embodiment are designated by the same reference numerals. This also applies to the drawings below.

Also in the battery temperature control device 1 according to the second embodiment, the connection member 40 is arranged at the center of the battery module 10 in the stacking direction and functions as a so-called intermediate plate. The connection member 40 according to the second embodiment has an internal flow path 41, an inflow portion 42, an outflow portion 43, a first connection portion 44, and a second connection portion 45, as in the first embodiment.

As shown in FIGS. 8 and 9, in the connecting member 40 of the second embodiment, the forming positions of the first connecting portion 44 and the second connecting portion 45 are different from those of the first embodiment. Further, as the positions of the first connecting portion 44 and the second connecting portion 45 are different, the configuration of the internal flow path 41 is also different.

The first connecting portion 44 according to the second embodiment is arranged on the left side surface of the connecting member 40 formed in a flat rectangular parallelepiped shape. On the other hand, the second connecting portion 45 according to the second embodiment is arranged on the right side surface of the connecting member 40.

That is, although the first connection portion 44 and the second connection portion 45 in the first embodiment are arranged on one surface called the rear surface of the connection member 40, the first connection portion 44 and the second connection in the second embodiment are arranged. The portions 45 are arranged on different side surfaces of the connecting member 40.

Therefore, the first heat exchanger 20 extends between the left side surface of the connecting member 40 and the battery cell 11 so as to face forward, and then is bent so as to have a plurality of heat exchange portions 31 and a plurality of curved portions 32. Is composed of. Similar to the first embodiment, the first folded-back portion 23 is connected to the left end portion of the first heat exchanger 20.

The second heat exchanger 30 is configured to extend between the right side surface of the connecting member 40 and the battery cell toward the rear and then be bent so as to have a plurality of heat exchange portions 31 and a plurality of curved portions 32. Will be done. A second folded-back portion 33 is connected to the right end portion of the second heat exchanger 30 as in the first embodiment.

Since the other configurations in the second embodiment and the control of the communication unit 60 and the flow rate adjusting unit 65 are the same as those in the first embodiment, the description thereof will be omitted again.

According to the battery temperature control device 1 according to the second embodiment, even when the configurations of the first heat exchanger 20, the second heat exchanger 30, and the connecting member 40 are changed, the same effect as that of the above-described embodiment can be obtained. Obtainable. That is, the battery temperature control device 1 of the second embodiment suppresses the temperature variation of each battery cell 11 with respect to the battery module 10 in which a plurality of battery cells 11 are laminated in the stacking direction, and equalizes the plurality of battery cells 11. Achieves warming.

(Third Embodiment)
As shown in FIG. 10, in the present embodiment, the connecting member 40 is configured by connecting the front side connecting member 46, the rear side connecting member 47, and the connecting member 48. In the above-described embodiment, the connecting member 40 is a single member that functions as an intermediate plate, whereas in the third embodiment, the connecting member 40 is formed by combining a plurality of members. There is.

The front side connecting member 46 is formed in a square columnar shape having an internal space that functions as an internal flow path 41. An inflow portion 42 and an outflow portion 43 are formed on the front surface of the front side connecting member 46, as in the above-described embodiment. As shown in FIG. 10, the front side connecting member 46 is located at the center of the battery module 10 in the stacking direction in the stacking direction, and is located in front of the front surface of each battery cell 11.

Like the front connecting member 46, the rear connecting member 47 is formed in a square columnar shape having an internal space that functions as an internal flow path 41. A first connecting portion 44 is formed on the left side surface of the rear side connecting member 47, and a second connecting portion 45 is formed on the right side surface of the rear side connecting member 47. The rear connection member 47 is located at the center of the battery module 10 in the stacking direction, behind the rear surface of each battery cell 11.

The connecting member 48 is made of a metal material having good thermal conductivity (for example, aluminum, stainless steel, etc.) and is neglected in a tubular shape. The connecting member 48 is connected to the rear surface of the front side connecting member 46 and the front surface of the rear side connecting member 47, and communicates the internal space of the front side connecting member 46 and the internal space of the rear side connecting member 47. doing.

That is, in the third embodiment, the internal flow path 41 of the connecting member 40 is configured by connecting the internal space of the front side connecting member 46, the internal space of the rear side connecting member 47, and the internal space of the connecting member 48. There is.

Since the other configurations and the like in the third embodiment are the same as those in the above-described embodiment, the description thereof will be omitted again.

According to the battery temperature control device 1 according to the third embodiment, even when the connecting member 40 is composed of a plurality of members such as the front side connecting member 46, the same effect as that of the above-described embodiment can be obtained. That is, the battery temperature control device 1 of the third embodiment suppresses the temperature variation of each battery cell 11 with respect to the battery module 10 in which a plurality of battery cells 11 are laminated in the stacking direction, and equalizes the plurality of battery cells 11. Achieves warming.

(Fourth Embodiment)
In the present embodiment, the connecting member 40 is configured to be more compact than the above-described embodiment.

The connecting member 40 according to the fourth embodiment is formed in a square columnar shape having an internal space that functions as an internal flow path 41. The connecting member 40 is located at the center of the battery module 10 in the stacking direction in the stacking direction, and is located in front of the front surface of each battery cell 11.

As shown in FIG. 11, an inflow portion 42 and an outflow portion 43 are formed on the front surface of the connecting member 40, and a first connecting portion 44 and a second connecting portion 45 are formed on the rear surface of the connecting member 40. ing. Also in the fourth embodiment, the end portion of the first heat exchanger 20 is connected to the first connection portion 44, and the end portion of the second heat exchanger 30 is connected to the second connection portion 45. ..

The flat multi-hole tube connected to the first connection portion 44 extends rearward between the two battery cells 11 constituting the central portion in the stacking direction of the battery module 10, and then is bent in a meandering shape to form a serpentine. It constitutes the first heat exchanger 20 of the mold.

The flat multi-hole tube connected to the second connection portion 45 is a flat multi-hole tube forming the first heat exchanger 20 between the two battery cells 11 forming the central portion in the stacking direction of the battery module 10. It is arranged so as to extend backward along the. After that, it is bent in a meandering shape to form a serpentine type second heat exchanger 30.

Since the other configurations and the like in the fourth embodiment are the same as those in the above-described embodiment, the description thereof will be omitted again.

According to the battery temperature control device 1 according to the fourth embodiment, the same effect as that of the above-described embodiment can be obtained even when the connecting member 40 is compactly configured. That is, the battery temperature control device 1 of the fourth embodiment suppresses the temperature variation of each battery cell 11 with respect to the battery module 10 in which a plurality of battery cells 11 are laminated in the stacking direction, and equalizes the plurality of battery cells 11. Achieves warming.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be variously modified as follows without departing from the spirit of the present invention. Moreover, the means disclosed in each of the above-described embodiments may be appropriately combined to the extent feasible.

(A) In the above-described embodiment, the first heat exchanger 20 and the second heat exchanger 30 are of the serpentine type, but the first heat exchanger 20 and the second heat exchanger 30 are other than the serpentine type. It may be configured.

(B) In the above-described embodiment, the battery module 10 is composed of eight battery cells 11, but the present invention is not limited to this embodiment. The number of battery cells 11 constituting the battery module 10 can be changed as appropriate.

(C) The position of the connecting member 40 in the battery module 10 is preferably the central portion of the battery module 10 with respect to the stacking direction, but is not limited to the central portion of the battery module 10 in the stacking direction. In the plurality of battery cells 11 stacked in the stacking direction, the position of the connecting member 40 can be appropriately changed as long as the position is between the plurality of adjacent battery cells 11 (d) In the above-described embodiment. The battery module 10 sandwiched between the first end plate 50 and the second end plate 51 was configured by arranging one unit including the first heat exchanger 20, the second heat exchanger 30, and the connecting member 40. However, the present invention is not limited to this aspect. For example, a plurality of sets of units including a first heat exchanger 20, a second heat exchanger 30, and a connecting member 40 can be arranged in a battery module 10 in which a large number of battery cells 11 are stacked. ..

(E) Further, in the above-described embodiment, the total flow path cross-sectional area of the outward path side flow path 24o and the return path side flow path 24r is configured to be equal, but the present invention is not limited to this. Regarding the total flow path cross-sectional area of the outward path side flow path 24o and the return path side flow path 24r, one of them may be configured to be larger than the other.

For example, it is possible to increase the cross-sectional area of the flow path of the outward path side flow path 24o and the return path side flow path 24r, whichever is arranged in the portion of the battery cell 11 that is difficult to cool. Thereby, the cooling performance for the hard-to-cool portion of the battery cell 11 can be improved. The same applies to the total flow path cross-sectional area of the outward path side flow path 34o and the return path side flow path 34r.

1 Battery temperature controller 10 Battery module 11 Battery cell 20 1st heat exchanger 23 1st folded part 30 2nd heat exchanger 33 2nd folded part 40 Connecting member 42 Inflow part 43 Outflow part

Claims (6)

A plurality of battery cells (11) stacked in a predetermined stacking direction, and
A connecting member (40) arranged between the battery cells arranged in the stacking direction and having an inflow portion (42) and an outflow portion (43) of a heat medium that exchanges heat with the plurality of battery cells.
In a plurality of the battery cells, a first heat exchanger (20) that exchanges heat between the battery cells arranged on one side of the connecting member in the stacking direction and the heat medium flowing through the connecting member. )When,
In the plurality of battery cells, a second heat exchanger (30) that exchanges heat between the battery cell arranged on the other side of the connecting member in the stacking direction and the heat medium flowing through the connecting member. ) And,
The first heat exchanger is
A plurality of heat exchange units (21) arranged so as to be heat exchangeable with respect to the battery cell on one side of the connection member in the stacking direction.
A first folded portion (23) that is arranged on the most one side in the stacking direction of the plurality of battery cells and that folds the flow of the heat medium that has passed through the plurality of heat exchange portions toward the outflow portion of the connecting member. ) And,
The second heat exchanger is
A plurality of heat exchange units (31) arranged so as to be heat exchangeable with respect to the battery cell on the other side in the stacking direction with respect to the connecting member.
A second folded portion (33) that is arranged on the most opposite side in the stacking direction of the plurality of battery cells and that folds the flow of the heat medium that has passed through the plurality of heat exchange portions toward the outflow portion of the connecting member. ), And has a battery temperature control device. The connecting member includes a first connecting portion (44) to which the first heat exchanger is connected so that the heat medium can flow in and out.
A second connection portion (45) to which the second heat exchanger is connected so that the heat medium can flow in and out at a position different from the first connection portion.
The battery according to claim 1, further comprising an internal flow path (41) that communicates the first connection portion and the second connection portion with respect to the inflow portion and the outflow portion inside the connection member. Temperature control device. A first end plate (50) arranged on the most one side in the stacking direction of the plurality of battery cells,
A second end plate (51) arranged on the farthest side of the plurality of battery cells in the stacking direction, and
Between the first end plate and the second end plate, a restraining member (55) for fixing the battery cell and the heat exchange portion in a laminated state is provided.
The battery temperature control device according to claim 1 or 2, wherein the connecting member is fixed in position with respect to the first end plate and the second end plate via the restraining member. It has a communication unit (60) for communicating cell information indicating the state of a plurality of the battery cells, and has a communication unit (60).
The battery temperature control device according to any one of claims 1 to 3, wherein the communication unit is arranged so as to exchange heat with the heat medium circulating inside the connection member with respect to the connection member. With respect to the heat medium flowing from the inflow portion, the flow rate of the heat medium flowing toward the first heat exchanger and the flow rate of the heat medium flowing toward the second heat exchanger are adjusted, and the connection is made. The flow rate adjusting unit (65) arranged on the member and
The invention according to any one of claims 1 to 3, further comprising a control device (70) for controlling the operation of the flow rate adjusting unit so that the temperatures of the plurality of battery cells are within a predetermined temperature range. Battery temperature control device. A communication unit (60) arranged on the connection member and communicating cell information indicating the state of the plurality of battery cells, and a communication unit (60).
With respect to the heat medium flowing from the inflow portion, the flow rate of the heat medium flowing toward the first heat exchanger and the flow rate of the heat medium flowing toward the second heat exchanger are adjusted, and the connection is made. The flow rate adjusting unit (65) arranged on the member and
A control device (70) that controls the operation of the flow rate adjusting unit so that the temperatures of the plurality of battery cells are within a predetermined temperature range by using the cell information acquired by communication with the communication unit. The battery temperature control device according to any one of claims 1 to 3, wherein the battery temperature control device has

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