KR20220153218A - Battery cooling system and battery pack using this - Google Patents

Abstract

The present invention relates to a battery cooling system for stably forming a passage of a refrigerant moving in a zigzag shape, and improving cooling efficiency of a battery module, and a battery pack using the same. To this end, the battery cooling system includes: an upper plate member having, on one side, an inlet through which the refrigerant flows in and an outlet which is spaced apart from the inlet and through which the refrigerant is discharged; a middle plate member laminated and coupled to a lower part of the upper plate member; a lower plate member laminated and coupled to a lower part of the middle plate member; a supply passage formed between the upper plate member and the middle plate member to form a zigzag movement path of the refrigerant introduced from the inlet; a return passage formed between the middle plate member and the lower plate member to form a zigzag movement path of the refrigerant discharged to the outlet, and having a part overlapping the supply passage; and a connection passage communicating an end of the supply passage and an end of the return passage.

Description

Battery cooling system and battery pack using it {BATTERY COOLING SYSTEM AND BATTERY PACK USING THIS}

The present invention relates to a battery cooling system and a battery pack using the same, and more specifically, to a battery cooling system for stably forming a flow path of a refrigerant moving along a zigzag shape and improving the cooling efficiency of a battery module, and using the same. It's about the battery pack.

In vehicles that use batteries as power, such as electric vehicles or plug-in hybrids, it is necessary to manage the temperature of the battery to maintain its performance or prevent shortening of its lifespan. In particular, if the temperature of the battery is not managed and overheated, the life span of the battery is reduced and it causes a fire due to overheating.

A cooling sheet of a fuel cell cell constituting a conventional battery is configured such that an aluminum thermal conductive sheet transfers thermal energy of the cell through brazing welding or to a pipe through which a cooling fluid flows. This is widely used as a cooling method for fuel cell units.

In the case of cooling fins constituting a cooling module on a unit module including fuel cell cells, it is the same concept that cooling is performed by contacting the battery and the cooling fins on a cell-by-cell basis. On the other hand, there may be a difference in the shape, shape or arrangement of the cooling fins constituting the unit module.

On the other hand, in order to cool the heat generated in the fuel cell, a method of bonding cooling plates on the upper and lower surfaces of the fuel cell has been sought.

Republic of Korea Patent Registration No. 10-2124387 (Title of Invention: Method for Manufacturing Cooling Panel of Battery, 2020. 06. 18. Notice)

An object of the present invention is to solve the conventional problems, and to provide a battery cooling system for improving the cooling efficiency of a battery module and a battery pack using the same while stably forming a flow path of a refrigerant moving along a zigzag shape. have.

According to a preferred embodiment for achieving the above object of the present invention, the battery cooling system according to the present invention includes a top plate member having an inlet through which a refrigerant flows in and an outlet spaced from the inlet and through which the refrigerant is discharged; a middle plate member laminated to a lower portion of the upper plate member; a lower plate member laminated to a lower portion of the middle plate member; Forming a zigzag movement path of the refrigerant introduced from the inlet formed between the upper plate member and the middle plate member, two or more supply passage parts disposed in parallel with each other, and a supply connection part connecting the inlet and the supply passage part; a supply passage including a supply conversion unit connecting two supply passage sections adjacent to each other to form a zigzag movement path of the refrigerant; A return connection portion formed between the middle plate member and the lower plate member to form a zigzag movement path of the refrigerant discharged to the outlet, and connecting two or more return passage portions disposed in parallel with each other, and connecting the outlet and the return passage portion; a return flow path including a return conversion unit connecting two adjacent return path units to form a zigzag movement path of the refrigerant; and a connection passage for communicating the supply passage part and the return passage part at an end of the supply passage and an end of the return passage, wherein the supply connection part is parallel to the return connection part in a state separated from the return connection part. The supply passage part is formed to overlap the upper part of the return connection part in a state of being separated from the return passage part via the middle plate member, and the supply conversion part is formed to overlap with the return conversion part via the middle plate member. It is formed to overlap the upper part of the return conversion part in a separated state.

Here, a part of the middle plate member includes a supply connection groove protruding from the upper part of the middle plate member to form the supply connection part, and a part of the lower plate member includes the A return connection groove protrudes from the lower portion of the lower plate member as it is recessed from the upper portion of the lower plate member to form a return connection portion.

Here, a middle plate protruding member is protruded from the edge of the middle plate member in correspondence with the inlet, and the supply connection groove is included in a part of the middle plate member through which the middle plate protruding member and the middle plate protruding member protrude. A lower plate protruding member is protruded from an edge of the lower plate member corresponding to the outlet, and the return connection groove is included in a portion of the lower plate member through which the lower plate protruding member and the lower plate protruding member protrude.

Here, the middle plate protruding member is laminated and coupled to a part of the lower plate protruding member.

Here, the passage connection part for forming the connection passage is formed through the middle plate member or formed in a depression from an edge of the middle plate member.

Here, the top plate member includes two or more upper plate grooves protruding upward from the top of the top plate member as they are recessed from the bottom of the top plate member; and a top plate shifting ledge formed between two adjacent top plate grooves, wherein the mid plate member protrudes from the bottom of the mid plate member as it is recessed from the top of the mid plate member in correspondence with the top plate shifting ledge. and a transition groove, wherein the lower plate member includes two or more lower plate grooves protruding from the lower part of the lower plate member as they are recessed from the upper part of the lower plate member in correspondence with the upper plate groove part; And a lower plate conversion groove formed between two mutually adjacent lower plate grooves corresponding to the upper plate shifting jaw, and protruding from the lower plate member to the lower part of the lower plate member as it is formed more recessed than the lower plate groove part from the upper part of the lower plate member. The upper plate groove communicates with the supply connecting part, communicates with the middle plate switching groove, or communicates with the connection passage to form the supply passage part, and the middle plate switching groove communicates the two adjacent upper plate grooves to switch the supply. The lower plate groove part communicates with the return connection part, communicates with the lower plate conversion groove, or communicates with the connection passage to form the return passage part, and the lower plate conversion groove communicates two adjacent lower plate groove parts. According to this, the return conversion unit is formed.

Here, the top plate groove portion includes two or more unit supply grooves protruding from the top of the top plate member as they are recessed from the bottom of the top plate member; and an upper plate connection step formed between two unit supply grooves adjacent to each other and intersected with the moving direction of the refrigerant moving in the supply passage. and an upper plate distribution step formed in parallel with the moving direction of the refrigerant moving in the supply passage and formed between two mutually adjacent unit supply grooves. and in the middle plate member, the middle plate protrudes from the lower part of the middle plate member as it is recessed from the upper part of the middle plate member in correspondence with at least one of the upper plate connecting ledge and the upper plate distributing ledge. A connecting groove is included, and the middle plate connecting groove communicates two or more unit supply grooves.

Here, in the supply passage, a supply distributing unit provided in at least one of a part of the top plate groove part and a part of the middle plate member corresponding to the top plate groove part to disperse the refrigerant; and a supply switching/distributing unit provided on at least one of a part of the upper plate converting jaw and a part of the middle plate converting groove to disperse the refrigerant. At least one of them is included.

Here, the lower plate groove part includes two or more unit return grooves protruding to the lower part of the lower plate member as they are recessed from the upper part of the lower plate member, and is formed to cross the moving direction of the refrigerant moving in the return passage. and a lower plate connection groove formed between two unit return grooves adjacent to each other; and a first lower plate dispersion unit formed in parallel with the moving direction of the refrigerant moving in the return passage and formed between two adjacent unit return grooves. and, in the middle plate member, in correspondence with at least one of the lower plate connection groove and the first lower plate dispersion part, the middle plate member is formed to protrude from the upper part of the middle plate member to the lower part of the middle plate member. A middle plate connection groove is included, and at least one of the lower plate connection groove and the lower plate distribution groove communicates two or more unit return grooves.

Here, the return flow passage includes: a return dispersion unit provided in at least one of a part of the lower plate groove part and a part of the middle plate member corresponding to the lower plate groove part to disperse the refrigerant; and a return conversion/dispersion unit disposed in at least one of a part of the lower plate conversion groove and a part of the middle plate conversion groove to disperse the refrigerant. At least one of them is included.

Here, the top plate member includes two or more top plate passage grooves protruding from the top of the top plate member as they are recessed from the bottom of the top plate member; and an upper plate passage connection groove protruding from the lower portion of the upper plate member in the same manner as the upper plate passage groove and protruding from the top of the top plate member, wherein the lower plate member includes the lower plate corresponding to the upper plate passage groove. two or more lower plate passage grooves protruding from the lower part of the lower plate member as they are recessed from the upper part of the member; and a lower plate passage connection groove corresponding to the upper plate passage connection groove and protruding from the upper portion of the lower plate member in the same manner as the lower plate passage groove and protruding from the lower plate member. The upper plate passage groove includes, The supply passage part is formed by communicating with the supply connection part or the connection passage, and the upper plate passage connection groove forms the supply switching part by communicating two mutually adjacent upper plate passage grooves, and the lower plate passage groove , Communication with the return connection part or with the connection passage forms the return passage part, and the lower plate passage connection groove communicates two mutually adjacent lower plate passage grooves to form the return conversion part.

Here, in the supply passage, an upper plate guide provided in the upper plate passage groove and the upper plate passage connection groove to disperse the refrigerant; and a mid-plate guide provided on a part of the mid-plate member corresponding to the upper plate passage groove and the upper plate passage connection groove to disperse the refrigerant. At least one of them is included.

Here, the return passage includes a lower plate guide provided in the lower plate passage groove and the lower plate passage connection groove to disperse the refrigerant; and a middle plate guide provided on a part of the middle plate member to correspond to the lower plate passage groove and the lower plate passage connection groove to disperse the refrigerant. At least one of them is included.

A battery pack according to the present invention includes at least one battery module in which power is charged; a housing in which the battery module is inserted and supported; a cover module detachably coupled to the housing to open and close at least one of upper and lower portions of the housing; and a cooling module stacked and supported on at least one of an upper part of the housing and a lower part of the housing so as to contact or come into close contact with the battery module and cool the battery module according to the circulation of the refrigerant, wherein the cooling module includes, A battery cooling system according to the present invention is included.

Here, the cover module is provided with a cover partition corresponding to the arrangement shape of the battery module or the protruding shape of the cooling module.

According to the battery cooling system and the battery pack using the battery cooling system according to the present invention, the cooling efficiency of the battery module can be improved while stably forming the passage of the refrigerant moving along the zigzag shape.

In particular, since the supply passage part and the supply conversion part are overlapped with the return passage part and the return conversion part, respectively, and are in contact with or closely supported by at least one of the upper and lower parts of the battery module, the refrigerant moving through the supply passage part covers the contact surface of the battery module as much as possible. It can be uniformly cooled, and the life of the battery module can be extended. In the conventional battery cooling system, there was a problem in that the cooling efficiency for the edge of the battery module rapidly decreased as the supply passage part and the return passage part were divided in a single-layer structure. Since the refrigerant on the supply passage side and the refrigerant on the return passage side interact with each other, the upper part of the upper plate member can exhibit a uniform temperature distribution as a whole, and contact the upper part of the upper plate member. Alternatively, it is possible to uniformly cool the battery module that is closely supported. Accordingly, the present invention makes it possible to conveniently manage the temperature of the battery module, improve the cooling efficiency of the battery module, and extend the life of the battery module.

In addition, the present invention makes it possible to clarify the supply connection part and the return connection part through the coupling relationship between the connection grooves and facilitate the circulation of the refrigerant.

In addition, the present invention limits the position of the connection groove through the coupling relationship of the protruding members, while defining the positions of the supply connection part and the return connection part, and allows the refrigerant to stably move through the supply connection part and the return connection part.

In addition, the present invention can stably accommodate the relatively expanded refrigerant when the refrigerant is returned through the arrangement of the connection grooves, and smoothly supply and return the refrigerant.

In addition, the present invention allows the refrigerant in the supply passage to be stably transferred to the return passage through the coupling relationship of the passage connection part.

In addition, the present invention limits the positions of the supply passage part, the supply conversion part, the return passage part, and the return conversion part through the first coupling relationship between the upper plate member, the middle plate member, and the lower plate member, while the supply passage part is in stable contact with the battery module. Alternatively, it may be brought into close contact, and the heat dissipation effect may be improved in the return passage part and the return conversion part.

In addition, the present invention clarifies the structure of the upper plate groove through the first coupling relationship between the upper plate member, the middle plate member, and the lower plate member, clarifies the contact or close contact with the battery module, and smoothly moves the refrigerant in the supply passage part. can do

In addition, according to the present invention, the dispersing effect of the refrigerant in the supply passage can be exhibited through the first coupling relationship between the upper plate member, the middle plate member, and the lower plate member, and the battery module can be smoothly cooled by the dispersed refrigerant.

In addition, the present invention clarifies the structure of the lower plate groove through the first coupling relationship between the upper plate member, the middle plate member, and the lower plate member, clarifies the heat dissipation effect in the battery cooling system, and facilitates the movement of the refrigerant in the return passage part. can do.

In addition, the present invention can show the effect of dispersing the refrigerant in the return passage through the first coupling relationship between the upper plate member, the middle plate member, and the lower plate member, and promote heat dissipation of the refrigerant in the battery cooling system by the dispersed refrigerant.

In addition, the present invention limits the positions of the supply passage, the supply conversion section, the return passage section, and the return conversion section through the second coupling relationship between the upper plate member, the middle plate member, and the lower plate member, while the supply passage unit is in stable contact with the battery module. Alternatively, it may be brought into close contact, and the heat dissipation effect may be improved in the return passage part and the return conversion part.

In addition, according to the present invention, the dispersing effect of the refrigerant in the supply passage can be exhibited through the second coupling relationship between the upper plate member, the middle plate member, and the lower plate member, and the battery module can be smoothly cooled by the dispersed refrigerant.

In addition, the present invention can show the effect of dispersing the refrigerant in the return passage through the second coupling relationship between the upper plate member, the middle plate member, and the lower plate member, and promote heat dissipation of the refrigerant in the battery cooling system by the dispersed refrigerant.

In addition, by limiting the depression depth in the upper plate member and the middle plate member, the height of the supply passage can be kept constant, the refrigerant can move smoothly in the supply passage, and the battery module can be uniformly cooled.

In addition, by limiting the depression depth in the middle plate member and the lower plate member, the height of the return passage is kept constant, the refrigerant moves smoothly in the return passage, and the heat dissipation effect of the refrigerant after heat exchange is completed can be improved. .

In addition, the present invention can easily cool the battery module through the coupling relationship of the battery pack, while stably fixing the battery module in place in the housing.

In addition, the present invention can stably support the battery module or the cooling module through the coupling relationship of the cover module, prevent the battery module or the cooling module from flowing, and improve the heat dissipation effect of the battery module or the cooling module.

1 is a perspective view showing a battery cooling system according to a first embodiment of the present invention.
2 is a perspective view showing an upper plate member in a battery cooling system according to a first embodiment of the present invention.
3 is a perspective view showing a middle plate member in the battery cooling system according to the first embodiment of the present invention.
4 is a perspective view showing a lower plate member in the battery cooling system according to the first embodiment of the present invention.
5 is a perspective view showing a battery cooling system according to a second embodiment of the present invention.
6 is a perspective view showing an upper plate member in a battery cooling system according to a second embodiment of the present invention.
7 is a perspective view showing a middle plate member in a battery cooling system according to a second embodiment of the present invention.
8 is a perspective view showing a lower plate member in a battery cooling system according to a second embodiment of the present invention.
9 is a perspective view showing a battery cooling system according to a third embodiment of the present invention.
10 is a perspective view showing an upper plate member in a battery cooling system according to a third embodiment of the present invention.
11 is a perspective view illustrating a middle plate member in a battery cooling system according to a third embodiment of the present invention.
12 is a perspective view illustrating a lower plate member in a battery cooling system according to a third embodiment of the present invention.
13 is a perspective view showing a battery cooling system according to a fourth embodiment of the present invention.
14 is a perspective view showing an upper plate member in a battery cooling system according to a fourth embodiment of the present invention.
15 is a perspective view showing a middle plate member in a battery cooling system according to a fourth embodiment of the present invention.
16 is a perspective view illustrating a lower plate member in a battery cooling system according to a fourth embodiment of the present invention.
17 is a perspective view illustrating a battery cooling system according to a fifth embodiment of the present invention.
18 is a perspective view showing an upper plate member in a battery cooling system according to a fifth embodiment of the present invention.
19 is a perspective view illustrating a middle plate member in a battery cooling system according to a fifth embodiment of the present invention.
20 is a perspective view showing a lower plate member in a battery cooling system according to a fifth embodiment of the present invention.
21 is an exploded perspective view showing a battery pack according to an embodiment of the present invention.

Hereinafter, an embodiment of a battery cooling system according to the present invention and a battery pack using the same will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to clarify the gist of the present invention.

In describing the present invention, a battery pack according to a preferred embodiment of the present invention will be described, and a battery cooling system according to a preferred embodiment of the present invention will be described as being included in the battery pack according to a preferred embodiment of the present invention.

A battery pack according to a preferred embodiment of the present invention will now be described.

Referring to FIG. 21 , a battery pack according to a preferred embodiment of the present invention may include a battery module 200, a housing 100, a cover module, and a cooling module 500.

At least one battery module 200 is provided.

The battery module 200 is charged with power.

In one embodiment of the present invention, eight battery modules 200 are provided, and are shown in a form arranged in two rows and four columns, but the present invention is not limited thereto, and the performance of the battery pack according to an embodiment of the present invention Accordingly, the number of battery modules 200 may be determined and arranged in various ways. Two or more battery modules 200 may be connected in series or parallel.

In the battery module 200, two or more unit batteries 210 may be connected in series or parallel. In one embodiment of the present invention, the battery module 200 is provided with four unit batteries 210, and is shown in a form arranged in four rows, but is not limited thereto, and the battery according to an embodiment of the present invention Depending on the performance of the pack, the number of battery modules 200 may be determined and arranged in various ways.

Here, the upper portion of the battery module 200 is a portion facing the upper cover 300 based on FIG. 21 , and the lower portion of the battery module 200 is a portion facing the lower cover 400 based on FIG. 21 .

The housing 100 forms a body in which the battery module 200 is seated.

The battery module 200 is inserted into and supported by the housing 100 .

In the housing 100, a module space 110 in which the battery module 200 is inserted and supported is recessed or penetrating, corresponding to the arrangement of the battery module 200.

In the housing 100 , a dummy space 120 may be recessed or formed through one side of the module space 110 . In the dummy space 120, a refrigerant line forming a movement path between the refrigerant supplied to the cooling module 500 and the refrigerant discharged from the cooling module 500 is disposed. Further, the housing 100 may be provided with a refrigerant hole 130 through which a refrigerant line passes by communicating the dummy space 120 with the outside.

Here, the upper portion of the housing 100 is a portion facing the upper cover 300 based on FIG. 21 , and the lower portion of the housing 100 is a portion facing the lower cover 400 based on FIG. 21 .

The cover module opens and closes at least one of the upper and lower portions of the housing 100 . The cover module may be detachably coupled to the housing 100 to open and close at least one of the upper and lower portions of the opened housing 100 .

The cover module may be provided with a cover compartment corresponding to the arrangement shape of the battery module 200 or the protruding shape of the cooling module 500 .

Here, the upper part of the cover module is a part facing the housing 100 based on the housing 100, and the lower part of the cover module is a part facing the upper part of the cover module based on the housing 100.

The cover module may further include at least one of an upper cover 300 and a lower cover 400 . The cover compartment may be divided into an upper compartment 310 and a lower compartment 410 .

The upper cover 300 opens and closes the top of the housing 100 . The upper cover 300 may be detachably coupled to the housing 100 to open and close the upper portion of the opened housing 100 . Accordingly, the upper cover 300 may cover the battery module 200 exposed to the upper portion of the housing 100 . When the cooling module 500 is stacked and supported between the housing 100 and the upper cover 300, the upper cover 300 covers the cooling module 500 stacked and supported on the top of the housing 100 and the cooling module ( 500) can be dissipated.

Since the upper cover 300 is supported in contact with or in close contact with the corresponding module stacked and supported thereon, the corresponding module stacked and supported on the upper cover 300 can be stably supported. At this time, the upper cover 300 may be provided with an upper compartment 310 corresponding to the arrangement shape of the battery module 200 or the protruding shape of the cooling module 500 . The upper compartment 310 is formed to protrude from the upper part of the upper cover 300 as it is recessed from the lower part of the upper cover 300 so that the upper cover 300 contacts or adheres to the corresponding module stacked and supported thereon, or the upper cover As the upper cover 300 is recessed, it may protrude from the lower part of the upper cover 300 . The upper compartment 310 may be provided between two adjacent battery modules 200 . The upper compartment 310 may contact or closely support a partition wall partitioning the module space 110 in the housing 100, or may be spaced apart from each other to face the partition wall. In addition, the upper compartment 310 may be provided between two parts protruding from the cooling module 500 corresponding to the battery module 200 .

The edge of the upper cover 300 is supported by the housing 100 as it protrudes or protrudes from the upper part of the upper cover 300 as it is recessed or protrudes from the lower part of the upper cover 300 .

Here, the upper part of the upper cover 300 is a part facing the housing 100 based on the housing 100, and the lower part of the upper cover 300 is the upper part and the upper cover 300 based on the housing 100. the opposite part.

The lower cover 400 opens and closes the lower part of the housing 100 . The lower cover 400 may be detachably coupled to the housing 100 to open and close the lower portion of the opened housing 100 . Accordingly, the lower cover 400 may cover the battery module 200 exposed to the lower portion of the housing 100 . When the cooling module 500 is stacked and supported between the housing 100 and the lower cover 400, the lower cover 400 covers the cooling module 500 stacked and supported on the lower portion of the housing 100 and the cooling module ( 500) can be dissipated.

Since the lower cover 400 is supported in contact with or in close contact with the corresponding module stacked and supported on the upper part, the corresponding module stacked and supported on the upper part of the lower cover 400 can be stably supported. At this time, the lower cover 400 may be provided with a lower compartment 410 corresponding to the arrangement shape of the battery module 200 or the protruding shape of the cooling module 500 . The lower compartment 410 is formed to protrude from the upper part of the lower cover 400 as it is recessed from the lower part of the lower cover 400 so that the lower cover 400 contacts or adheres to the corresponding module stacked and supported on the upper part or the lower cover 400. As the upper part of the lower cover 400 is recessed, it may protrude from the lower part of the lower cover 400 . The lower compartment 410 may be provided between two adjacent battery modules 200 . The lower compartment 410 may contact or closely support a partition wall partitioning the module space 110 in the housing 100, or may be spaced apart from each other to face the partition wall. In addition, the lower compartment 410 may be provided between two parts protruding from the cooling module 500 corresponding to the battery module 200 .

The edge of the lower cover 400 is supported by the housing 100 as it protrudes or protrudes from the upper part of the lower cover 400 as it is recessed or protrudes from the lower part of the lower cover 400 .

Here, the upper part of the lower cover 400 is a part facing the housing 100 based on the housing 100, and the lower part of the lower cover 400 is the upper part of the lower cover 400 based on the housing 100. the opposite part.

The cooling module 500 is stacked and supported on at least one of an upper portion of the housing 100 and a lower portion of the housing 100 . In one embodiment of the present invention, the cooling module 500 is shown as being stacked and supported at the lower portion of the housing 100, but is not limited thereto, and corresponds to the opening direction of the module space 110 in the housing 100. At least one of the upper part of the housing 100 and the lower part of the housing 100 may be laminated and supported.

The cooling module 500 may be brought into contact with or brought into close contact with the battery module 200 inserted into and supported by the housing 100 to facilitate heat exchange with the battery module 200 .

The cooling module 500 may safely manage the battery module 200 by cooling the battery module 200 according to the circulation of the refrigerant.

The cooling module 500 includes a battery cooling system according to a preferred embodiment of the present invention, and will be described in more detail in the battery cooling system according to a preferred embodiment of the present invention.

Here, the upper part of the cooling module 500 is a part facing the housing 100 based on the housing 100, and the lower part of the cooling module 500 is the upper part and the upper part of the cooling module 500 based on the housing 100. the opposite part.

According to the battery pack according to a preferred embodiment of the present invention, the battery module 200 can be cooled as the refrigerant circulates inside the cooling module 500 .

Hereinafter, a battery cooling system according to a preferred embodiment of the present invention will be described.

A battery cooling system according to a preferred embodiment of the present invention cools the battery module 200 included in a battery pack according to a preferred embodiment of the present invention, and may include the aforementioned cooling module 500.

1 to 20, the battery cooling system according to a preferred embodiment of the present invention includes an upper plate member 10, a middle plate member 20, a lower plate member 30, a supply passage, a return passage, A connection path may be included.

In describing the battery cooling system according to a preferred embodiment of the present invention, the upper part of the top plate member 10 is a part facing the battery module 200 based on the battery module 200, and the lower part of the top plate member 10 is defined as a portion opposite to the upper portion of the top plate member 10 based on the battery module 200. The lower part of the upper plate member 10 contacts or adheres to the upper part of the middle plate member 20 and is coupled to the upper part of the middle plate member 20 so that the supply passage is stably formed.

In describing the battery cooling system according to a preferred embodiment of the present invention, the upper part of the middle plate member 20 is a part facing the battery module 200 based on the battery module 200, and the lower part of the middle plate member 20 is defined as a portion opposite to the upper portion of the middle plate member 20 based on the battery module 200. The upper part of the middle plate member 20 comes into contact with or adheres to the lower part of the upper plate member 10 and is coupled to the lower part of the upper plate member 10 so that the supply passage is stably formed. The lower part of the middle plate member 20 comes into contact with or adheres to the upper part of the lower plate member 30 and is coupled to the upper part of the lower plate member 30 so that the return passage is stably formed.

In describing the battery cooling system according to a preferred embodiment of the present invention, the upper part of the lower plate member 30 is a part facing the battery module 200 based on the battery module 200, and the lower part of the lower plate member 30 is defined as a portion opposite to the upper portion of the lower plate member 30 based on the battery module 200 . The upper part of the lower plate member 30 contacts or adheres to the lower part of the middle plate member 20 and is coupled to the lower part of the middle plate member 20 so that the return passage is stably formed. The lower part of the lower plate member 30 comes into contact with or adheres to the upper part of the above-described cover module, and as it is coupled to the upper part of the cover module, heat generated in the battery cooling system according to a preferred embodiment of the present invention is discharged to the outside through the cover module. to ensure smooth heat dissipation.

The upper plate member 10 has an inlet 11 and an outlet 12 on one side. The inlet 11 is a part through which the refrigerant flows, and the outlet 12 is a part spaced apart from the inlet 11 and through which the refrigerant is discharged.

The middle plate member 20 is laminated and coupled to the lower part of the upper plate member 10 .

The lower plate member 30 is laminated and coupled to the lower part of the middle plate member 20 .

The supply passage is formed between the upper plate member 10 and the middle plate member 20 . The supply passage forms a zigzag movement path of the refrigerant introduced from the inlet 11 . The supply passage may include two or more supply passage portions disposed in parallel with each other, a supply connection portion connecting the inlet 11 and the supply passage portion, and a supply switching portion connecting the two supply passage portions adjacent to each other to form a zigzag movement path of the refrigerant. can

In a preferred embodiment of the present invention, the supply flow path is indicated by a solid arrow.

The return passage is formed between the middle plate member 20 and the lower plate member 30 . The return passage forms a zigzag movement path discharged to the outlet 12 . The return passage may include two or more return passage portions disposed in parallel with each other, a return connection portion connecting the outlet 12 and the return passage portion, and a return conversion portion connecting the two return passage portions adjacent to each other to form a zigzag movement path of the refrigerant. can

In a preferred embodiment of the present invention, the return passage is indicated by a dotted arrow.

The connection passage communicates the supply passage portion and the return passage portion at an end of the supply passage and an end of the return passage.

In a preferred embodiment of the present invention, the connection passage is indicated by a round solid line arrow.

According to a preferred embodiment of the present invention, since the supply connection part is disposed in parallel with the return connection part in a state separated from the return connection part, it is possible to clearly supply and discharge the refrigerant. In addition, since the supply passage part is formed to overlap the upper portion of the return connection part in a state of being separated from the return passage part through the middle plate member 20, the cooling efficiency of the battery module 200 using a refrigerant can be improved. In addition, since the supply conversion unit is formed to overlap the upper portion of the return conversion unit in a state of being separated from the return conversion unit via the intermediate plate member 20, the cooling efficiency of the battery module 200 using the refrigerant is improved and the circulation of the refrigerant is improved. can be done smoothly.

In particular, since the supply passage part and the supply conversion part are overlapped with the return passage part and the return conversion part, respectively, and are in contact with or closely supported by at least one of the upper and lower parts of the battery module 200, the refrigerant moving through the supply passage part is the battery module ( 200) can be cooled as uniformly as possible, and the life of the battery module 200 can be extended. In the conventional battery cooling system, there is a problem that the cooling efficiency for the edge of the battery module 200 is rapidly reduced as the supply passage part and the return passage part are divided in a single-layer structure, but as in the present invention, the supply passage part and the supply conversion part are respectively Since the return passage part overlaps with the return conversion part to represent a two-stage structure, the refrigerant on the supply passage side and the refrigerant on the return passage side interact, so that the upper part of the upper plate member 10 can exhibit a uniform temperature distribution as a whole, It is possible to uniformly cool the battery module 200 that is in contact with or closely supported on the top of the upper plate member 10 . Accordingly, the present invention makes it possible to conveniently manage the temperature of the battery module 200, improve the cooling efficiency of the battery module 200, and extend the lifespan of the battery module 200.

Here, the height of the supply passage part, the height of the supply conversion part, the height of the return passage part, and the height of the return conversion part are formed to be substantially the same, so that the refrigerant can be smoothly circulated.

In addition, the height of the supply connection part is formed to be greater than the height of the supply passage part, so that the supplied refrigerant can be stably delivered to the supply passage part while performing a buffer function of stably accommodating the supplied refrigerant.

In addition, the height of the return connection portion is formed to be greater than that of the return passage portion to perform a buffer function of stably accommodating the discharged refrigerant, while allowing the refrigerant of the return passage portion to be stably transferred to the return connection portion.

In addition, the height of the supply connection part is formed equal to or smaller than the height of the return connection part so that the refrigerant that has undergone heat exchange in the return connection part is stably accommodated.

A battery cooling system according to a preferred embodiment of the present invention will be described in more detail through five embodiments.

1 to 4, the battery cooling system according to the first embodiment of the present invention includes the above-described upper plate member 10, middle plate member 20, lower plate member 30, supply passage, and return It may include a flow path and a connection flow path.

Regarding the above-described supply connection part, a part of the middle plate member 20 includes a supply connection groove 211 protruding from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 to form a supply connection part. do. The supply connection groove 211 communicates with the inlet 11 while communicating with the supply passage to form a stable supply connection.

In the supply connection groove 211, a middle plate connecting groove 23-2 or a middle plate conversion groove 24-1, or a first middle plate distribution part 23-3 or a second middle plate distribution part 24-2, which will be described later, are recessed. It is recessed at a second middle plate depth greater than the first middle plate depth to stably accommodate the incoming refrigerant and stably communicates with the unit supply groove 13-1 of the upper plate groove part or the upper plate passage groove 15 described later. .

In more detail, the middle plate protruding member 21 is protruded from the edge of the middle plate member 20 corresponding to the inlet 11, and the supply connection groove 211 has the middle plate protruding member 21 and the middle plate protruding member 21. It may be included in a part of the protruding middle plate member 20.

Regarding the above-described return connection part, a part of the lower plate member 30 includes a return connection groove 311 protruding from the lower part of the lower plate member 30 as it is recessed from the upper part of the lower plate member 30 to form a return connection part. do. The return connection groove 311 communicates with the outlet 12 and communicates with the return passage to form a stable return connection.

The return connection groove 311 is recessed to a second lower plate depth greater than the first lower plate depth in which the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later, is depressed, stably discharging the refrigerant It is accommodated and is stably communicated with the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later.

In more detail, the lower plate protruding member 31 is protruded from the edge of the lower plate member 30 corresponding to the outlet 12, and the return connection groove 311 has the lower plate protruding member 31 and the lower plate protruding member 31. It may be included in a part of the protruding lower plate member 30 .

In a preferred embodiment of the present invention, the middle plate protruding member 21 is stacked and coupled to a portion of the lower plate protruding member 31 to protect the supply connection portion. In more detail, the lower plate protruding member 31 is stacked and coupled to the lower part of the middle plate protruding member 21, and the lower part of the supply connection groove 211 is supported on a part of the upper bottom of the return connection groove 311 to supply the connection groove (211) can be stably protected.

Since the passage connection part 22 for forming the connection passage with respect to the above-described connection passage is formed through the middle plate member 20 or formed by being recessed from the edge of the middle plate member 20, the supply passage part and the return passage part are easily communicated. .

Regarding the above-described supply passage portion and supply conversion portion, and the return passage portion and return conversion portion overlapping therein, the upper plate member 10 includes two or more upper plate grooves and upper plate conversion jaws 14-1, and the middle plate member 20 ) includes the middle plate conversion groove 24-1, and the lower plate member 30 may include two or more lower plate grooves and the lower plate conversion groove 34-1.

The top plate groove is formed to protrude from the top of the top plate member 10 as it is recessed from the bottom of the top plate member 10 . It is preferable that two or more of the grooves of the upper plate are spaced apart in correspondence with the arrangement of the battery module 200 . As the upper part of the upper plate groove is in contact with or closely supported by the battery module 200, the refrigerant flowing into the upper plate groove can stably cool the battery module 200. The lower part of the upper plate groove is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. It is preferable that the top plate groove portion is recessed to a depth corresponding to the height of the supply passage portion.

The upper plate conversion jaw 14-1 is formed between two mutually adjacent upper plate grooves. The upper plate shifting jaw 14-1 is formed on the same plane as the upper plate member 10 as the upper plate groove is formed.

The middle plate conversion groove 24-1 is formed to protrude from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 corresponding to the upper plate conversion jaw 14-1. It is preferable that the intermediate plate conversion groove 24-1 is recessed to the first intermediate plate depth corresponding to the height of the supply conversion unit.

Corresponding to the upper plate grooves, the lower plate grooves are formed by being recessed from the upper part of the lower plate member 30 so as to protrude toward the lower part of the lower plate member 30 . Corresponding to the arrangement of the battery module 200, two or more of the lower plate grooves are spaced apart from each other and are preferably overlapped with the upper plate grooves. The upper part of the lower plate groove is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower part of the lower plate groove may be exposed to the outside or contacted or closely supported by the cover module, thereby improving the heat dissipation effect. It is preferable that the lower plate groove portion is recessed to the first lower plate depth corresponding to the height of the return passage portion.

The lower plate conversion groove 34-1 is formed between two mutually adjacent lower plate grooves corresponding to the upper plate conversion jaw 14-1. The lower plate conversion groove 34-1 protrudes from the upper part of the lower plate member 30 to the lower part of the lower plate member 30 as it is recessed more than the lower plate groove part. The lower part of the lower plate conversion groove 34-1 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect. At this time, the lower plate groove may be exposed to the outside or spaced apart to face the cover module to form a heat dissipation space. It is preferable that the lower plate conversion groove 34-1 is recessed to a second lower plate depth greater than the first lower plate depth corresponding to the height of the return conversion portion.

Then, the upper plate groove part may communicate with the supply connection part, communicate with the middle plate conversion groove 24-1, or communicate with the connection passage to form a supply passage part. In addition, the middle plate switching groove 24-1 may form a supply switching part by communicating two upper plate grooves adjacent to each other. In addition, the lower plate groove communicates with the return connection part, communicates with the lower plate conversion groove 34-1, or communicates with the connection passage, thereby forming a return passage part. In addition, the lower plate conversion groove 34-1 may form a return conversion portion by communicating two adjacent lower plate groove portions.

In other words, as the middle plate members 20 are spaced apart from each other in the lower part of the upper plate groove, a supply passage is formed. In addition, as the lower plate grooves are spaced apart from each other so as to overlap with the upper plate grooves, the return passage portion is formed in the lower part of the middle plate member 20 . In addition, as the intermediate plate conversion grooves 24-1 are spaced apart from each other at the bottom of the upper plate conversion jaw 14-1, a supply conversion unit is formed. In addition, as the lower plate conversion grooves 34-1 are spaced apart from each other in the lower part of the middle plate conversion groove 24-1, a return conversion portion is formed.

The above-described upper plate groove portion may include two or more unit supply grooves 13-1 protruding from the upper portion of the upper plate member 10 as they are recessed from the lower portion of the upper plate member 10. The upper plate groove portion is formed to cross the direction of movement of the refrigerant moving in the supply passage and is formed between the two adjacent unit supply grooves 13-1, the upper plate connecting jaw 13-2, and the movement of the refrigerant moving in the supply passage. At least one of the upper plate distribution jaws 13-4 formed in parallel with the direction and formed between the two unit supply grooves 13-1 adjacent to each other may be further included.

In addition, the middle plate member 20 is recessed from the upper part of the middle plate member 20 corresponding to at least one of the upper plate connecting jaw 13-2 and the upper plate distribution jaw 13-4. A middle plate connection groove 23-2 protruding downward is included.

At this time, the middle plate connecting groove 23-2 communicates two or more unit supply grooves 13-1, so that the supply passage can be clarified.

The above-described lower plate groove portion may include two or more unit return grooves 33-1 protruding from the lower portion of the lower plate member 30 as they are recessed from the upper portion of the lower plate member 30. The lower plate groove part is formed to cross the moving direction of the refrigerant moving in the return passage, and the lower plate connecting groove 33-2 formed between two unit return grooves 33-1 adjacent to each other and the movement of the refrigerant moving in the return passage At least one of the first lower plate dispersion units 33-3 formed in parallel with the direction and formed between two unit return grooves 33-1 adjacent to each other may be further included.

In addition, the middle plate connection groove 23-2 corresponds to at least one of the lower plate connection groove 33-2 and the lower plate distribution groove in the middle plate member 20 and is formed by being recessed from the upper part of the middle plate member 20. It protrudes from the bottom of (20).

At this time, at least one of the lower plate connection groove 33-2 and the first lower plate dispersion part 33-3 communicates two or more unit return grooves 33-1, so that the return flow passage can be clarified.

In the supply passage, a supply distributing part provided in at least one of a part of the upper plate groove and a part of the middle plate member 20 corresponding to the upper plate groove to disperse the refrigerant, a part of the upper plate conversion jaw 14-1, and a middle plate conversion groove Since at least one of the supply switching/distributing units provided in at least one of the parts of (24-1) and distributing the refrigerant is included, the cooling effect of the battery module 200 is improved through the dispersion of the refrigerant, and the battery module ( 200) can be uniformly cooled.

In the return passage, a return distributing part provided in at least one of a part of the lower plate groove and a part of the middle plate member 20 corresponding to the lower plate groove to disperse the refrigerant, a part of the lower plate conversion groove 34-1, and a middle plate conversion groove Since at least one of the return conversion dispersion units provided in at least one of the parts of 24-1 to disperse the refrigerant is included, the heat dissipation effect of the refrigerant can be improved through the dispersion of the refrigerant.

In the first embodiment of the present invention, the supply distributing unit can be implemented with the above-described upper plate distributing jaw 13-4, and the supply switching and distributing unit uses the upper plate distributing unit 14-2 provided on the upper plate diverting jaw 14-1. The return dispersion unit can be implemented through the above-described first lower plate dispersion unit 33-3, and the return conversion and dispersion unit is provided in the lower plate conversion groove 34-1. ) It is shown that it can be implemented through.

In particular, the first lower plate distributing part 33-3 is shown as being supported on the lower part of the middle plate member 20 by protruding from the upper part of the lower plate groove part as it is formed in the lower part of the lower plate groove part. In addition, the second lower plate dispersion unit 34-2 is formed to protrude from the upper part of the lower plate conversion groove 34-1 as it is recessed at the bottom of the lower plate conversion groove 34-1, thereby forming a middle plate conversion groove 24-1. It is shown as being supported at the bottom of.

5 to 8, the battery cooling system according to the second embodiment of the present invention includes the above-described upper plate member 10, middle plate member 20, lower plate member 30, supply passage, and return It may include a flow path and a connection flow path.

Regarding the above-described supply connection part, a part of the middle plate member 20 includes a supply connection groove 211 protruding from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 to form a supply connection part. do. The supply connection groove 211 communicates with the inlet 11 while communicating with the supply passage to form a stable supply connection.

In the supply connection groove 211, a middle plate connecting groove 23-2 or a middle plate conversion groove 24-1, or a first middle plate distribution part 23-3 or a second middle plate distribution part 24-2, which will be described later, are recessed. It is recessed at a second middle plate depth greater than the first middle plate depth to stably accommodate the incoming refrigerant and stably communicates with the unit supply groove 13-1 of the upper plate groove part or the upper plate passage groove 15 described later. .

In more detail, the middle plate protruding member 21 is protruded from the edge of the middle plate member 20 corresponding to the inlet 11, and the supply connection groove 211 has the middle plate protruding member 21 and the middle plate protruding member 21. It may be included in a part of the protruding middle plate member 20.

Regarding the above-described return connection part, a part of the lower plate member 30 includes a return connection groove 311 protruding from the lower part of the lower plate member 30 as it is recessed from the upper part of the lower plate member 30 to form a return connection part. do. The return connection groove 311 communicates with the outlet 12 and communicates with the return passage to form a stable return connection.

The return connection groove 311 is recessed to a second lower plate depth greater than the first lower plate depth in which the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later, is depressed, stably discharging the refrigerant It is accommodated and is stably communicated with the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later.

In more detail, the lower plate protruding member 31 is protruded from the edge of the lower plate member 30 corresponding to the outlet 12, and the return connection groove 311 has the lower plate protruding member 31 and the lower plate protruding member 31. It may be included in a part of the protruding lower plate member 30 .

In a preferred embodiment of the present invention, the middle plate protruding member 21 is stacked and coupled to a portion of the lower plate protruding member 31 to protect the supply connection portion. In more detail, the lower plate protruding member 31 is stacked and coupled to the lower part of the middle plate protruding member 21, and the lower part of the supply connection groove 211 is supported on a part of the upper bottom of the return connection groove 311 to supply the connection groove (211) can be stably protected.

Since the passage connection part 22 for forming the connection passage with respect to the above-described connection passage is formed through the middle plate member 20 or formed by being recessed from the edge of the middle plate member 20, the supply passage part and the return passage part are easily communicated. .

Regarding the above-described supply passage portion and supply conversion portion, and the return passage portion and return conversion portion overlapping therein, the upper plate member 10 includes two or more upper plate grooves and upper plate conversion jaws 14-1, and the middle plate member 20 ) includes the middle plate conversion groove 24-1, and the lower plate member 30 may include two or more lower plate grooves and the lower plate conversion groove 34-1.

The top plate groove is formed to protrude from the top of the top plate member 10 as it is recessed from the bottom of the top plate member 10 . It is preferable that two or more of the grooves of the upper plate are spaced apart in correspondence with the arrangement of the battery module 200 . As the upper part of the upper plate groove is in contact with or closely supported by the battery module 200, the refrigerant flowing into the upper plate groove can stably cool the battery module 200. The lower part of the upper plate groove is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. It is preferable that the top plate groove portion is recessed to a depth corresponding to the height of the supply passage portion.

The upper plate conversion jaw 14-1 is formed between two mutually adjacent upper plate grooves. The upper plate shifting jaw 14-1 is formed on the same plane as the upper plate member 10 as the upper plate groove is formed.

The middle plate conversion groove 24-1 is formed to protrude from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 corresponding to the upper plate conversion jaw 14-1. It is preferable that the intermediate plate conversion groove 24-1 is recessed to the first intermediate plate depth corresponding to the height of the supply conversion section.

Corresponding to the upper plate grooves, the lower plate grooves are formed by being recessed from the upper part of the lower plate member 30 so as to protrude toward the lower part of the lower plate member 30 . Corresponding to the arrangement of the battery module 200, two or more of the lower plate grooves are spaced apart from each other and are preferably overlapped with the upper plate grooves. The upper part of the lower plate groove is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower part of the lower plate groove may be exposed to the outside or contacted or closely supported by the cover module, thereby improving the heat dissipation effect. It is preferable that the lower plate groove portion is recessed to the first lower plate depth corresponding to the height of the return passage portion.

The lower plate conversion groove 34-1 is formed between two mutually adjacent lower plate grooves corresponding to the upper plate conversion jaw 14-1. The lower plate conversion groove 34-1 protrudes from the upper part of the lower plate member 30 to the lower part of the lower plate member 30 as it is recessed more than the lower plate groove part. The lower part of the lower plate conversion groove 34-1 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect. At this time, the lower plate groove may be exposed to the outside or spaced apart to face the cover module to form a heat dissipation space. It is preferable that the lower plate conversion groove 34-1 is recessed to a second lower plate depth greater than the first lower plate depth corresponding to the height of the return conversion portion.

Then, the upper plate groove part may communicate with the supply connection part, communicate with the middle plate conversion groove 24-1, or communicate with the connection passage to form a supply passage part. In addition, the middle plate switching groove 24-1 may form a supply switching part by communicating two upper plate grooves adjacent to each other. In addition, the lower plate groove communicates with the return connection part, communicates with the lower plate conversion groove 34-1, or communicates with the connection passage, thereby forming a return passage part. In addition, the lower plate conversion groove 34-1 may form a return conversion portion by communicating two adjacent lower plate groove portions.

In other words, as the middle plate members 20 are spaced apart from each other in the lower part of the upper plate groove, a supply passage is formed. In addition, as the lower plate grooves are spaced apart from each other so as to overlap with the upper plate grooves, the return passage portion is formed in the lower part of the middle plate member 20 . In addition, as the intermediate plate conversion grooves 24-1 are spaced apart from each other at the bottom of the upper plate conversion jaw 14-1, a supply conversion unit is formed. In addition, as the lower plate conversion grooves 34-1 are spaced apart from each other in the lower part of the middle plate conversion groove 24-1, a return conversion portion is formed.

The above-described upper plate groove portion may include two or more unit supply grooves 13-1 protruding from the upper portion of the upper plate member 10 as they are recessed from the lower portion of the upper plate member 10. The upper plate groove portion is formed to cross the direction of movement of the refrigerant moving in the supply passage and is formed between the two adjacent unit supply grooves 13-1, the upper plate connecting jaw 13-2, and the movement of the refrigerant moving in the supply passage. At least one of the upper plate distribution jaws 13-4 formed in parallel with the direction and formed between the two unit supply grooves 13-1 adjacent to each other may be further included.

In addition, the middle plate member 20 is recessed from the upper part of the middle plate member 20 corresponding to at least one of the upper plate connecting jaw 13-2 and the upper plate distribution jaw 13-4. A middle plate connection groove 23-2 protruding downward is included.

At this time, the middle plate connecting groove 23-2 communicates two or more unit supply grooves 13-1, so that the supply passage can be clarified.

The above-described lower plate groove portion may include two or more unit return grooves 33-1 protruding from the lower portion of the lower plate member 30 as they are recessed from the upper portion of the lower plate member 30. The lower plate groove part is formed to cross the moving direction of the refrigerant moving in the return passage, and the lower plate connecting groove 33-2 formed between two unit return grooves 33-1 adjacent to each other and the movement of the refrigerant moving in the return passage At least one of the first lower plate dispersion units 33-3 formed in parallel with the direction and formed between two unit return grooves 33-1 adjacent to each other may be further included.

In addition, the middle plate connection groove 23-2 corresponds to at least one of the lower plate connection groove 33-2 and the lower plate distribution groove in the middle plate member 20 and is formed by being recessed from the upper part of the middle plate member 20. It protrudes from the bottom of (20).

At this time, at least one of the lower plate connection groove 33-2 and the first lower plate dispersion part 33-3 communicates two or more unit return grooves 33-1, so that the return flow passage can be clarified.

In the supply passage, a supply distributing part provided in at least one of a part of the upper plate groove and a part of the middle plate member 20 corresponding to the upper plate groove to disperse the refrigerant, a part of the upper plate conversion jaw 14-1, and a middle plate conversion groove Since at least one of the supply switching/distributing units provided in at least one of the parts of (24-1) and distributing the refrigerant is included, the cooling effect of the battery module 200 is improved through the dispersion of the refrigerant, and the battery module ( 200) can be uniformly cooled.

In the return passage, a return distributing part provided in at least one of a part of the lower plate groove and a part of the middle plate member 20 corresponding to the lower plate groove to disperse the refrigerant, a part of the lower plate conversion groove 34-1, and a middle plate conversion groove Since at least one of the return conversion dispersion units provided in at least one of the parts of 24-1 to disperse the refrigerant is included, the heat dissipation effect of the refrigerant can be improved through the dispersion of the refrigerant.

In the second embodiment of the present invention, the supply distribution unit uses at least one of the first middle plate distribution unit 23-3 provided in the middle plate member 20 corresponding to the above-described upper plate distribution jaw 13-4 and the upper plate groove. The supply conversion and distribution unit can be implemented through the second middle plate distribution unit 24-2 provided in the middle plate conversion groove 24-1, and the return distribution unit is provided in the middle plate member 20 corresponding to the upper plate groove. It can be implemented through at least one of the provided first middle plate dispersion unit 23-3 and the above-described first lower plate dispersion unit 33-3, and the return conversion dispersion unit is provided in the middle plate conversion groove 24-1. It is shown that it can be realized through at least one of the second middle plate dispersion unit 24-2 and the second lower plate dispersion unit 34-2 provided in the lower plate conversion groove 34-1.

In particular, the first middle plate dispersion unit 23-3 is formed to protrude from the upper part of the middle plate member 20 as it is recessed in the lower part of the middle plate member 20, and is supported by the lower part of the upper plate groove of the upper plate member 10. shown In addition, the second middle plate dispersion unit 24-2 is formed to protrude from the upper part of the middle plate conversion groove 24-1 as it is recessed at the lower part of the middle plate conversion groove 24-1, thereby converting the upper plate of the upper plate member 10. It is shown as being supported on the jaw (14-1). In addition, as the first lower plate dispersion unit 33-3 is formed in a depression at the bottom of the lower plate groove, it protrudes from the upper part of the lower plate groove and is formed in the lower part of the middle plate member 20 or the lower part of the first middle plate distribution part 23-3. It is shown as being supported on . In addition, the second lower plate dispersion unit 34-2 is formed to protrude from the upper part of the lower plate conversion groove 34-1 as it is recessed at the bottom of the lower plate conversion groove 34-1, thereby forming a middle plate conversion groove 24-1. It is shown as being supported on the lower part of the lower part or the lower part of the second middle plate dispersion unit 24-2.

9 to 12, the battery cooling system according to the third embodiment of the present invention includes the above-described upper plate member 10, middle plate member 20, lower plate member 30, supply passage, and return It may include a flow path and a connection flow path.

Regarding the above-described supply connection part, a part of the middle plate member 20 includes a supply connection groove 211 protruding from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 to form a supply connection part. do. The supply connection groove 211 communicates with the inlet 11 while communicating with the supply passage to form a stable supply connection.

In the supply connection groove 211, a middle plate connecting groove 23-2 or a middle plate conversion groove 24-1, or a first middle plate distribution part 23-3 or a second middle plate distribution part 24-2, which will be described later, are recessed. It is recessed at a second middle plate depth greater than the first middle plate depth to stably accommodate the incoming refrigerant and stably communicates with the unit supply groove 13-1 of the upper plate groove part or the upper plate passage groove 15 described later. .

In more detail, the middle plate protruding member 21 is protruded from the edge of the middle plate member 20 corresponding to the inlet 11, and the supply connection groove 211 has the middle plate protruding member 21 and the middle plate protruding member 21. It may be included in a part of the protruding middle plate member 20.

Regarding the above-described return connection part, a part of the lower plate member 30 includes a return connection groove 311 protruding from the lower part of the lower plate member 30 as it is recessed from the upper part of the lower plate member 30 to form a return connection part. do. The return connection groove 311 communicates with the outlet 12 and communicates with the return passage to form a stable return connection.

The return connection groove 311 is recessed to a second lower plate depth greater than the first lower plate depth in which the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later, is depressed, stably discharging the refrigerant It is accommodated and is stably communicated with the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later.

In more detail, the lower plate protruding member 31 is protruded from the edge of the lower plate member 30 corresponding to the outlet 12, and the return connection groove 311 has the lower plate protruding member 31 and the lower plate protruding member 31. It may be included in a part of the protruding lower plate member 30 .

In a preferred embodiment of the present invention, the middle plate protruding member 21 is stacked and coupled to a portion of the lower plate protruding member 31 to protect the supply connection portion. In more detail, the lower plate protruding member 31 is stacked and coupled to the lower part of the middle plate protruding member 21, and the lower part of the supply connection groove 211 is supported on a part of the upper bottom of the return connection groove 311 to supply the connection groove (211) can be stably protected.

Since the passage connection part 22 for forming the connection passage with respect to the above-described connection passage is formed through the middle plate member 20 or formed by being recessed from the edge of the middle plate member 20, the supply passage part and the return passage part are easily communicated. .

Regarding the above-described supply passage part and supply conversion part, and the return passage part and return conversion part overlapping therewith, the upper plate member 10 includes two or more upper plate passage grooves 15 and upper plate passage connection grooves 17, and the lower plate The member 30 may include two or more lower plate passage grooves 35 and lower plate passage connection grooves 37 .

The upper plate passage groove 15 protrudes upward from the upper plate member 10 as it is recessed from the lower part of the upper plate member 10 . It is preferable that two or more of the upper plate passage grooves 15 are spaced apart in correspondence with the arrangement of the battery module 200 . As the upper part of the upper plate passage groove 15 contacts or closely supports the battery module 200, the refrigerant flowing into the upper plate groove part can stably cool the battery module 200. The lower part of the upper plate passage groove 15 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. It is preferable that the upper plate passage groove 15 is recessed to a depth corresponding to the height of the supply passage part.

The upper plate passage connection groove 17 is formed by being recessed from the bottom of the top plate member 10 in the same manner as the top plate passage groove 15, so that it protrudes from the top of the top plate member 10. It is preferable that the top plate flow path connection groove 17 is recessed between two mutually adjacent top plate flow path grooves 15 to the same depth as the top plate flow path groove 15 .

The lower plate passage groove 35 is formed by being recessed from the upper part of the lower plate member 30 corresponding to the upper plate passage groove 15 so as to protrude toward the lower part of the lower plate member 30 . Corresponding to the arrangement of the battery module 200, two or more of the lower plate passage grooves 35 are preferably spaced apart from each other so as to overlap the upper plate passage grooves 15. The upper part of the lower plate passage groove 35 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect. It is preferable that the lower plate passage groove 35 is recessed to the first lower plate depth corresponding to the height of the return passage portion.

The lower plate passage connection groove 37 is formed to protrude from the upper part of the lower plate member 30 to the lower part of the lower plate member 30 as it is recessed in the same manner as the lower plate passage groove 35 corresponding to the upper plate passage connection groove 17. . It is preferable that the lower plate passage connection groove 37 is recessed between two mutually adjacent lower plate passage grooves 35 to a first lower plate depth that is the same depth as the lower plate passage groove 35 . The upper part of the lower plate passage connection groove 37 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect.

Then, the upper plate passage groove 15 may form a supply passage part as it communicates with the supply connection part or the connection passage. In addition, the top plate passage connection groove 17 may form a supply switching unit by communicating the two adjacent top plate passage grooves 15 to each other. In addition, the lower plate passage groove 35 may form a return passage part as it communicates with the return connection part or with the connection passage. In addition, the lower plate passage connecting groove 37 may form a return conversion part by communicating the two adjacent lower plate passage grooves 35 to each other.

In other words, the upper plate passage groove 15 and the top plate passage connection groove 17 are integrally formed with the same depth as the top plate, so that the supply passage part and the supply switching part of the supply passage can be formed. In addition, since the lower plate passage groove 35 and the lower plate passage connection groove 37 are integrally formed with the same first lower plate depth, a return passage portion and a return conversion portion may be formed.

In the supply passage, the upper plate guide 16 is provided in the upper plate passage groove 15 and the upper plate passage connection groove 17 to disperse the refrigerant, and a middle plate member corresponding to the upper plate passage groove 15 and the upper plate passage connection groove 17 Since at least one of the middle plate guides provided in a part of the 20 to disperse the refrigerant is included, the cooling effect of the battery module 200 can be improved and the battery module 200 can be uniformly cooled through the dispersion of the refrigerant. have.

In the return passage, a lower plate guide 36 provided in the lower plate passage groove 35 and the lower plate passage connection groove 37 to disperse the refrigerant, and a middle plate member corresponding to the lower plate passage groove 35 and the lower plate passage connection groove 37 Since at least one of the middle plate guides provided in a part of 20 to disperse the refrigerant is included, the heat dissipation effect of the refrigerant can be improved through the dispersion of the refrigerant.

In the third embodiment of the present invention, the upper plate guide 16, the middle plate guide, and the lower plate guide 36 are omitted.

13 to 16, the battery cooling system according to the fourth embodiment of the present invention includes the above-described upper plate member 10, middle plate member 20, lower plate member 30, supply passage, and return It may include a flow path and a connection flow path.

Regarding the above-described supply connection part, a part of the middle plate member 20 includes a supply connection groove 211 protruding from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 to form a supply connection part. do. The supply connection groove 211 communicates with the inlet 11 while communicating with the supply passage to form a stable supply connection.

In the supply connection groove 211, a middle plate connecting groove 23-2 or a middle plate conversion groove 24-1, or a first middle plate distribution part 23-3 or a second middle plate distribution part 24-2, which will be described later, are recessed. It is recessed at a second middle plate depth greater than the first middle plate depth to stably accommodate the incoming refrigerant and stably communicates with the unit supply groove 13-1 of the upper plate groove part or the upper plate passage groove 15 described later. .

In more detail, the middle plate protruding member 21 is protruded from the edge of the middle plate member 20 corresponding to the inlet 11, and the supply connection groove 211 has the middle plate protruding member 21 and the middle plate protruding member 21. It may be included in a part of the protruding middle plate member 20.

Regarding the above-described return connection part, a part of the lower plate member 30 includes a return connection groove 311 protruding from the lower part of the lower plate member 30 as it is recessed from the upper part of the lower plate member 30 to form a return connection part. do. The return connection groove 311 communicates with the outlet 12 and communicates with the return passage to form a stable return connection.

The return connection groove 311 is recessed to a second lower plate depth greater than the first lower plate depth in which the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later, is depressed, stably discharging the refrigerant It is accommodated and is stably communicated with the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later.

In more detail, the lower plate protruding member 31 is protruded from the edge of the lower plate member 30 corresponding to the outlet 12, and the return connection groove 311 has the lower plate protruding member 31 and the lower plate protruding member 31. It may be included in a part of the protruding lower plate member 30 .

In a preferred embodiment of the present invention, the middle plate protruding member 21 is stacked and coupled to a portion of the lower plate protruding member 31 to protect the supply connection portion. In more detail, the lower plate protruding member 31 is stacked and coupled to the lower part of the middle plate protruding member 21, and the lower part of the supply connection groove 211 is supported on a part of the upper bottom of the return connection groove 311 to supply the connection groove (211) can be stably protected.

Since the passage connection part 22 for forming the connection passage with respect to the above-described connection passage is formed through the middle plate member 20 or formed by being recessed from the edge of the middle plate member 20, the supply passage part and the return passage part are easily communicated. .

Regarding the above-described supply passage part and supply conversion part, and the return passage part and return conversion part overlapping therewith, the upper plate member 10 includes two or more upper plate passage grooves 15 and upper plate passage connection grooves 17, and the lower plate The member 30 may include two or more lower plate passage grooves 35 and lower plate passage connection grooves 37 .

The upper plate passage groove 15 protrudes upward from the upper plate member 10 as it is recessed from the lower part of the upper plate member 10 . It is preferable that two or more of the upper plate passage grooves 15 are spaced apart in correspondence with the arrangement of the battery module 200 . As the upper part of the upper plate passage groove 15 contacts or closely supports the battery module 200, the refrigerant flowing into the upper plate groove part can stably cool the battery module 200. The lower part of the upper plate passage groove 15 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. It is preferable that the upper plate passage groove 15 is recessed to a depth corresponding to the height of the supply passage part.

The upper plate passage connection groove 17 is formed by being recessed from the bottom of the top plate member 10 in the same manner as the top plate passage groove 15, so that it protrudes from the top of the top plate member 10. It is preferable that the top plate flow path connection groove 17 is recessed between two mutually adjacent top plate flow path grooves 15 to the same depth as the top plate flow path groove 15 .

The lower plate passage groove 35 is formed by being recessed from the upper part of the lower plate member 30 corresponding to the upper plate passage groove 15 so as to protrude toward the lower part of the lower plate member 30 . Corresponding to the arrangement of the battery module 200, two or more of the lower plate passage grooves 35 are preferably spaced apart from each other so as to overlap the upper plate passage grooves 15. The upper part of the lower plate passage groove 35 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect. It is preferable that the lower plate passage groove 35 is recessed to the first lower plate depth corresponding to the height of the return passage portion.

The lower plate passage connection groove 37 is formed to protrude from the upper part of the lower plate member 30 to the lower part of the lower plate member 30 as it is recessed in the same manner as the lower plate passage groove 35 corresponding to the upper plate passage connection groove 17. . It is preferable that the lower plate passage connection groove 37 is recessed between two mutually adjacent lower plate passage grooves 35 to a first lower plate depth that is the same depth as the lower plate passage groove 35 . The upper part of the lower plate passage connection groove 37 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect.

Then, the upper plate passage groove 15 may form a supply passage part as it communicates with the supply connection part or the connection passage. In addition, the top plate passage connection groove 17 may form a supply switching unit by communicating the two adjacent top plate passage grooves 15 to each other. In addition, the lower plate passage groove 35 may form a return passage part as it communicates with the return connection part or with the connection passage. In addition, the lower plate passage connecting groove 37 may form a return conversion part by communicating the two adjacent lower plate passage grooves 35 to each other.

In other words, the upper plate passage groove 15 and the top plate passage connection groove 17 are integrally formed with the same depth as the top plate, so that the supply passage part and the supply switching part of the supply passage can be formed. In addition, since the lower plate passage groove 35 and the lower plate passage connection groove 37 are integrally formed with the same first lower plate depth, a return passage portion and a return conversion portion may be formed.

In the supply passage, the upper plate guide 16 is provided in the upper plate passage groove 15 and the upper plate passage connection groove 17 to disperse the refrigerant, and a middle plate member corresponding to the upper plate passage groove 15 and the upper plate passage connection groove 17 Since at least one of the middle plate guides provided in a part of the 20 to disperse the refrigerant is included, the cooling effect of the battery module 200 can be improved and the battery module 200 can be uniformly cooled through the dispersion of the refrigerant. have.

In the return passage, a lower plate guide 36 provided in the lower plate passage groove 35 and the lower plate passage connection groove 37 to disperse the refrigerant, and a middle plate member corresponding to the lower plate passage groove 35 and the lower plate passage connection groove 37 Since at least one of the middle plate guides provided in a part of 20 to disperse the refrigerant is included, the heat dissipation effect of the refrigerant can be improved through the dispersion of the refrigerant.

In the fourth embodiment of the present invention, it is shown that the middle plate guide is provided. At this time, the mid-plate guide protrudes upward from the mid-plate member 20 as it is recessed from the bottom of the mid-plate member 20, and is supported by the upper plate passage groove 15 and the upper plate passage connection groove 17 of the upper plate member 10. As the first middle plate guide 26-1 and the middle plate member 20 are recessed from the upper part, they protrude to the lower part of the middle plate member 20, forming the lower plate passage groove 35 and the lower plate passage of the lower plate member 30. At least one of the second middle plate guides 26-2 supported in at least one of the connection grooves 37 may be included.

17 to 20, the battery cooling system according to the fifth embodiment of the present invention includes the above-described upper plate member 10, middle plate member 20, lower plate member 30, supply passage, and return It may include a flow path and a connection flow path.

Regarding the above-described supply connection part, a part of the middle plate member 20 includes a supply connection groove 211 protruding from the lower part of the middle plate member 20 as it is recessed from the upper part of the middle plate member 20 to form a supply connection part. do. The supply connection groove 211 communicates with the inlet 11 while communicating with the supply passage to form a stable supply connection.

In the supply connection groove 211, a middle plate connecting groove 23-2 or a middle plate conversion groove 24-1, or a first middle plate distribution part 23-3 or a second middle plate distribution part 24-2, which will be described later, are recessed. It is recessed at a second middle plate depth greater than the first middle plate depth to stably accommodate the incoming refrigerant and stably communicates with the unit supply groove 13-1 of the upper plate groove part or the upper plate passage groove 15 described later. .

In more detail, the middle plate protruding member 21 is protruded from the edge of the middle plate member 20 corresponding to the inlet 11, and the supply connection groove 211 has the middle plate protruding member 21 and the middle plate protruding member 21. It may be included in a part of the protruding middle plate member 20.

Regarding the above-described return connection part, a part of the lower plate member 30 includes a return connection groove 311 protruding from the lower part of the lower plate member 30 as it is recessed from the upper part of the lower plate member 30 to form a return connection part. do. The return connection groove 311 communicates with the outlet 12 and communicates with the return passage to form a stable return connection.

The return connection groove 311 is recessed to a second lower plate depth greater than the first lower plate depth in which the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later, is depressed, stably discharging the refrigerant It is accommodated and is stably communicated with the unit return groove 33-1 or the lower plate passage groove 35 of the lower plate groove part, which will be described later.

In more detail, the lower plate protruding member 31 is protruded from the edge of the lower plate member 30 corresponding to the outlet 12, and the return connection groove 311 has the lower plate protruding member 31 and the lower plate protruding member 31. It may be included in a part of the protruding lower plate member 30 .

In a preferred embodiment of the present invention, the middle plate protruding member 21 is stacked and coupled to a portion of the lower plate protruding member 31 to protect the supply connection portion. In more detail, the lower plate protruding member 31 is stacked and coupled to the lower part of the middle plate protruding member 21, and the lower part of the supply connection groove 211 is supported on a part of the upper bottom of the return connection groove 311 to supply the connection groove (211) can be stably protected.

Since the passage connection part 22 for forming the connection passage with respect to the above-described connection passage is formed through the middle plate member 20 or formed by being recessed from the edge of the middle plate member 20, the supply passage part and the return passage part are easily communicated. .

Regarding the above-described supply passage part and supply conversion part, and the return passage part and return conversion part overlapping therewith, the upper plate member 10 includes two or more upper plate passage grooves 15 and upper plate passage connection grooves 17, and the lower plate The member 30 may include two or more lower plate passage grooves 35 and lower plate passage connection grooves 37 .

The upper plate passage groove 15 protrudes upward from the upper plate member 10 as it is recessed from the lower part of the upper plate member 10 . It is preferable that two or more of the upper plate passage grooves 15 are spaced apart in correspondence with the arrangement of the battery module 200 . As the upper part of the upper plate passage groove 15 contacts or closely supports the battery module 200, the refrigerant flowing into the upper plate groove part can stably cool the battery module 200. The lower part of the upper plate passage groove 15 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. It is preferable that the upper plate passage groove 15 is recessed to a depth corresponding to the height of the supply passage part.

The upper plate passage connection groove 17 is formed by being recessed from the bottom of the top plate member 10 in the same manner as the top plate passage groove 15, so that it protrudes from the top of the top plate member 10. It is preferable that the top plate flow path connection groove 17 is recessed between two mutually adjacent top plate flow path grooves 15 to the same depth as the top plate flow path groove 15 .

The lower plate passage groove 35 is formed by being recessed from the upper part of the lower plate member 30 corresponding to the upper plate passage groove 15 so as to protrude toward the lower part of the lower plate member 30 . Corresponding to the arrangement of the battery module 200, two or more of the lower plate passage grooves 35 are preferably spaced apart from each other so as to overlap the upper plate passage grooves 15. The upper part of the lower plate passage groove 35 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect. It is preferable that the lower plate passage groove 35 is recessed to the first lower plate depth corresponding to the height of the return passage portion.

The lower plate passage connection groove 37 is formed to protrude from the upper part of the lower plate member 30 to the lower part of the lower plate member 30 as it is recessed in the same manner as the lower plate passage groove 35 corresponding to the upper plate passage connection groove 17. . It is preferable that the lower plate passage connection groove 37 is recessed between two mutually adjacent lower plate passage grooves 35 to a first lower plate depth that is the same depth as the lower plate passage groove 35 . The upper part of the lower plate passage connection groove 37 is spaced apart from the middle plate member 20 so that the refrigerant moves smoothly. The lower portion of the lower plate passage groove 35 is exposed to the outside or is in contact with or closely supported by the cover module, thereby improving the heat dissipation effect.

Then, the upper plate passage groove 15 may form a supply passage part as it communicates with the supply connection part or the connection passage. In addition, the top plate passage connection groove 17 may form a supply switching unit by communicating the two adjacent top plate passage grooves 15 to each other. In addition, the lower plate passage groove 35 may form a return passage part as it communicates with the return connection part or with the connection passage. In addition, the lower plate passage connecting groove 37 may form a return conversion part by communicating the two adjacent lower plate passage grooves 35 to each other.

In other words, the upper plate passage groove 15 and the top plate passage connection groove 17 are integrally formed with the same depth as the top plate, so that the supply passage part and the supply switching part of the supply passage can be formed. In addition, since the lower plate passage groove 35 and the lower plate passage connection groove 37 are integrally formed with the same first lower plate depth, a return passage portion and a return conversion portion may be formed.

In the supply passage, the upper plate guide 16 is provided in the upper plate passage groove 15 and the upper plate passage connection groove 17 to disperse the refrigerant, and a middle plate member corresponding to the upper plate passage groove 15 and the upper plate passage connection groove 17 Since at least one of the middle plate guides provided in a part of the 20 to disperse the refrigerant is included, the cooling effect of the battery module 200 can be improved and the battery module 200 can be uniformly cooled through the dispersion of the refrigerant. have.

In the return passage, a lower plate guide 36 provided in the lower plate passage groove 35 and the lower plate passage connection groove 37 to disperse the refrigerant, and a middle plate member corresponding to the lower plate passage groove 35 and the lower plate passage connection groove 37 Since at least one of the middle plate guides provided in a part of 20 to disperse the refrigerant is included, the heat dissipation effect of the refrigerant can be improved through the dispersion of the refrigerant.

In the fifth embodiment of the present invention, it is illustrated that the upper plate guide 16 and the lower plate guide 36 are provided. At this time, the top plate guide 16 is recessed on top of at least one of the top plate passage groove 15 and the top plate passage connection groove 17, so that at least one of the top plate passage groove 15 and the top plate passage connection groove 17 is formed. It is formed to protrude one lower part so as to be supported by the middle plate member 20. In addition, the lower plate guide 36 is recessed under at least one of the lower plate passage groove 35 and the lower plate passage connection groove 37, so that at least one of the lower plate passage groove 35 and the lower plate passage connection groove 37 is formed. It is formed to protrude one upper part so that it is supported by the middle plate member 20.

According to the above-described battery cooling system and a battery pack using the same, the cooling efficiency of the battery module 200 can be improved while stably forming a passage of a refrigerant moving along a zigzag shape.

In addition, the supply connection part and the return connection part can be made clear through the coupling relationship between the connection grooves, and the circulation of the refrigerant can be smoothed.

In addition, the position of the connection groove is limited through the coupling relationship between the protruding members, while the positions of the supply connection part and the return connection part are limited, and the refrigerant is stably moved through the supply connection part and the return connection part.

In addition, when the refrigerant is returned through the arrangement of the connection grooves, the relatively expanded refrigerant can be stably accommodated, while the supply and return of the refrigerant can be smoothly performed.

In addition, the refrigerant in the supply passage is stably transferred to the return passage through the coupling relationship of the passage connection part 22 .

In addition, the position of the supply passage part, the supply conversion part, the return passage part, and the return conversion part is limited through the first coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, while the supply passage part It is possible to stably contact or adhere to the battery module 200, and to improve heat dissipation in the return flow passage and the return conversion unit.

In addition, the structure of the upper plate groove part is clarified through the first coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, and the contact or close contact with the battery module 200 is clarified, It is possible to smoothly move the refrigerant in the supply passage part.

In addition, through the first coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, the effect of dispersing the refrigerant in the supply passage is shown, and the battery module 200 is smoothly cooled by the dispersed refrigerant. can make it

In addition, through the first coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, the structure of the lower plate groove part is clarified, the heat dissipation effect in the battery cooling system is clarified, and the return passage part The movement of the refrigerant can be smoothly performed.

In addition, through the first coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, the effect of dispersing the refrigerant in the return passage is shown, and the heat dissipation of the refrigerant in the battery cooling system is promoted by the dispersed refrigerant. can make it

In addition, the position of the supply passage part, the supply conversion part, the return passage part, and the return conversion part is limited through the second coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, while the supply passage part It is possible to stably contact or adhere to the battery module 200, and to improve heat dissipation in the return flow passage and the return conversion unit.

In addition, through the second coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, the effect of dispersing the refrigerant in the supply passage is shown, and the battery module 200 is smoothly cooled by the dispersed refrigerant. can make it

In addition, through the second coupling relationship between the upper plate member 10, the middle plate member 20, and the lower plate member 30, the effect of dispersing the refrigerant in the return passage is shown, and the heat dissipation of the refrigerant in the battery cooling system is promoted by the dispersed refrigerant. can make it

In addition, by limiting the depression depth in the upper plate member 10 and the middle plate member 20, the height of the supply passage is kept constant, the movement of the refrigerant in the supply passage is smooth, and the battery module 200 is uniformly cooled. can make it

In addition, by limiting the depression depth in the middle plate member 20 and the lower plate member 30, the height of the return passage is kept constant, the movement of the refrigerant in the return passage is smooth, and the heat dissipation effect of the refrigerant after heat exchange is improved. can make it

In addition, while the battery module 200 is easily cooled through the coupling relationship of the battery pack, the battery module 200 can be stably fixed in place in the housing 100 .

In addition, while the battery module 200 or the cooling module 500 is stably supported through the coupling relationship of the cover module, the movement of the battery module 200 or the cooling module 500 is prevented, and the battery module 200 or the cooling module 200 is cooled. The heat dissipation effect of the module 500 can be improved.

As described above, the preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art can make various modifications to the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. may be modified or changed.

10: top plate member 11: entrance 12: exit
13-1: Unit supply groove 13-2: Upper plate connecting jaw 13-4: Upper plate distribution jaw
14-1: Top plate conversion jaw 14-2: Top plate distribution unit 15: Top plate flow path
16: top plate guide 17: top plate passage connection groove
20: middle plate member 21: middle plate protruding member 211: supply connection groove
22: passage connection part 23-2: middle plate connection groove 23-3: first middle plate distribution part
24-1: middle plate conversion groove 24-2: second middle plate dispersion unit 26-1: first middle plate guide
26-2: Second middle plate guide
30: lower plate member 31: lower plate protruding member 311: return connection groove
33-1: unit return home 33-2: lower plate connection groove 33-3: first lower plate dispersion unit
34-1: lower plate conversion groove 34-2: second lower plate dispersion unit 35: lower plate flow path
36: lower plate guide 37: lower plate passage connection groove
100: housing 110: module space 120: dummy space
130: refrigerant hole 200: battery module 210: unit battery
300: upper cover 310: upper compartment 400: lower cover
410: lower compartment 500: cooling module

Claims (15)

An upper plate member having an inlet on one side through which a refrigerant flows in and an outlet spaced apart from the inlet through which the refrigerant is discharged;
a middle plate member laminated to a lower portion of the upper plate member;
a lower plate member laminated to a lower portion of the middle plate member;
Forming a zigzag movement path of the refrigerant introduced from the inlet formed between the upper plate member and the middle plate member, two or more supply passage parts disposed in parallel with each other, and a supply connection part connecting the inlet and the supply passage part; a supply passage including a supply conversion unit connecting two supply passage sections adjacent to each other to form a zigzag movement path of the refrigerant;
A return connection portion formed between the middle plate member and the lower plate member to form a zigzag movement path of the refrigerant discharged to the outlet, and connecting two or more return passage portions disposed in parallel with each other, and connecting the outlet and the return passage portion; a return flow path including a return conversion unit connecting two adjacent return path units to form a zigzag movement path of the refrigerant; and
A connection passage communicating the supply passage portion and the return passage portion at an end of the supply passage and an end of the return passage;
The supply connection part is disposed parallel to the return connection part in a state separated from the return connection part,
The supply passage part is formed so as to overlap the upper part of the return connection part in a state of being separated from the return passage part through the intermediate plate member,
The battery cooling system, characterized in that the supply conversion unit is formed to overlap the upper portion of the return conversion unit in a state of being separated from the return conversion unit via the intermediate plate member.
According to claim 1,
In some of the middle plate members,
A supply connection groove protruding from the upper part of the middle plate member to form the supply connection part by being depressed from the upper part of the middle plate member; included,
In part of the lower plate member,
The battery cooling system according to claim 1, wherein a return connection groove protrudes from the lower portion of the lower plate member as it is recessed from the upper portion of the lower plate member to form the return connection portion.
According to claim 2,
At the edge of the middle plate member,
Corresponding to the inlet, a middle plate protruding member is protrudingly formed,
The supply connection groove,
Included in the middle plate protruding member and a part of the middle plate member from which the middle plate protruding member protrudes,
At the edge of the lower plate member,
Corresponding to the outlet, a lower plate protruding member is protrudingly formed,
The return connection groove,
The battery cooling system, characterized in that included in the lower plate protruding member and a part of the lower plate member from which the lower plate protruding member protrudes.
According to claim 3,
The battery cooling system, characterized in that the middle plate protruding member is laminated to a part of the lower plate protruding member.
According to claim 1,
The battery cooling system, characterized in that the passage connecting portion for forming the connection passage is formed through the middle plate member or formed in a depression from an edge of the middle plate member.
According to claim 1,
In the upper plate member,
two or more top plate grooves protruding from the top of the top plate member as they are recessed from the bottom of the top plate member; and
It includes a top plate conversion step formed between two mutually adjacent top plate grooves,
In the middle plate member,
A middle plate conversion groove protruding from the upper part of the middle plate member to the lower part of the middle plate member according to the upper plate shifting jaw; is included.
In the lower plate member,
two or more lower plate grooves protruding from the lower part of the lower plate member as they are recessed from the upper part of the lower plate member in correspondence with the upper plate groove part; and
A lower plate conversion groove formed between two mutually adjacent lower plate grooves corresponding to the upper plate conversion jaw and protruding from the lower plate member to the lower part of the lower plate member as it is formed more recessed than the lower plate groove part from the upper part of the lower plate member; included,
The upper plate groove part communicates with the supply connection part, communicates with the middle plate conversion groove, or communicates with the connection passage to form the supply passage part;
The middle plate conversion groove forms the supply conversion portion by communicating two adjacent upper plate groove portions;
The lower plate groove part forms the return passage part as it communicates with the return connection part, communicates with the lower plate conversion groove, or communicates with the connection passage;
The battery cooling system, characterized in that the lower plate conversion groove forms the return conversion portion by communicating two mutually adjacent lower plate groove portions.
According to claim 6,
The top plate groove,
two or more unit supply grooves protruding from the top of the top plate member as they are recessed from the bottom of the top plate member; and
an upper plate connecting step formed between two unit supply grooves adjacent to each other and formed to cross the moving direction of the refrigerant moving in the supply passage; and
an upper plate distribution step formed in parallel with the moving direction of the refrigerant moving in the supply passage and formed between two mutually adjacent unit supply grooves;
It further includes at least one of
In the middle plate member,
A middle plate connecting groove protruding from the bottom of the middle plate member as it is recessed from the upper part of the middle plate member corresponding to at least one of the upper plate connecting jaw and the upper plate distribution jaw; is included,
The middle plate connection groove is a battery cooling system, characterized in that for communicating two or more unit supply grooves.
According to claim 6,
In the supply passage,
a supply distributing unit provided on at least one of a portion of the top plate groove and a portion of the middle plate member corresponding to the upper plate groove to disperse the refrigerant; and
a supply switching/distributing unit provided on at least one of a part of the upper plate converting jaw and a part of the middle plate converting groove to disperse the refrigerant;
A battery cooling system, characterized in that at least one of the included.
According to claim 6,
The lower plate groove,
Including; two or more unit return grooves protruding from the lower portion of the lower plate member as they are recessed from the upper portion of the lower plate member;
a lower plate connection groove formed between two unit return grooves adjacent to each other and crossed with the moving direction of the refrigerant moving in the return passage; and
a first lower plate dispersion unit formed in parallel with the moving direction of the refrigerant moving in the return passage and formed between two mutually adjacent unit return grooves;
It further includes at least one of
In the middle plate member,
In correspondence with at least one of the lower plate connection groove and the first lower plate dispersion unit, a middle plate connection groove protruding from the lower part of the middle plate member as it is recessed from the upper part of the middle plate member; is included,
At least one of the lower plate connection groove and the lower plate distribution groove communicates two or more unit return grooves.
According to claim 6,
In the return path,
a return dispersion unit provided on at least one of a portion of the lower plate groove and a portion of the middle plate member corresponding to the lower plate groove to disperse the refrigerant; and
a return conversion/dispersion unit provided in at least one of a part of the lower plate conversion groove and a part of the middle plate conversion groove to disperse the refrigerant;
A battery cooling system, characterized in that at least one of the included.
According to claim 1,
In the upper plate member,
two or more upper plate passage grooves protruding from the upper part of the upper plate member as they are recessed from the lower part of the upper plate member; and
An upper plate flow passage connection groove protruding from the lower portion of the top plate member in the same manner as the upper plate passage groove and protruding from the upper plate member is included.
In the lower plate member,
two or more lower plate passage grooves protruding from the lower portion of the lower plate member as they are recessed from the upper portion of the lower plate member in correspondence with the upper plate passage groove; and
Corresponding to the upper plate passage connection groove, a lower plate passage connection groove protruding from the lower part of the lower plate member as it is recessed from the upper part of the lower plate member in the same manner as the lower plate passage groove; is included,
The upper plate passage groove communicates with the supply connection part or with the connection passage to form the supply passage part;
The top plate passage connection groove forms the supply switching unit by communicating two mutually adjacent top plate passage grooves;
The lower plate passage groove communicates with the return connection portion or communicates with the connection passage to form the return passage portion;
The battery cooling system, characterized in that the lower plate passage connection groove forms the return conversion portion by communicating two mutually adjacent lower plate passage grooves.
According to claim 11,
In the supply passage,
an upper plate guide provided in the upper plate passage groove and the upper plate passage connection groove to disperse the refrigerant; and
a mid-plate guide provided on a part of the mid-plate member corresponding to the upper plate passage groove and the upper plate passage connection groove to disperse the refrigerant;
A battery cooling system, characterized in that at least one of the included.
According to claim 11,
In the return path,
a lower plate guide provided in the lower plate passage groove and the lower plate passage connection groove to disperse the refrigerant; and
a middle plate guide provided on a part of the middle plate member to correspond to the lower plate passage groove and the lower plate passage connection groove to disperse the refrigerant;
A battery cooling system, characterized in that at least one of the included.
At least one battery module in which power is charged;
a housing in which the battery module is inserted and supported;
a cover module detachably coupled to the housing to open and close at least one of upper and lower portions of the housing; and
A cooling module that is laminated and supported on at least one of an upper part of the housing and a lower part of the housing so as to contact or come into close contact with the battery module and cool the battery module according to the circulation of the refrigerant;
The cooling module,
A battery pack comprising the battery cooling system according to at least one of claims 1 to 13.
According to claim 14,
In the cover module,
The battery pack, characterized in that the cover compartment is provided to correspond to the arrangement shape of the battery module or the protruding shape of the cooling module.

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