KR20170049654A - Battery module - Google Patents

Abstract

Disclosed is a battery module. The battery module comprises: a battery cell; a heat control plate having a heat exchange passage in which a heat transmission medium flows to be disposed alternately with the battery cell, and controlling temperature of the battery cell by heat exchange with the heat transmission medium; a bonding part tightly bonding the battery cell and the heat control plate; and a module cover covering a cell laminate formed by the battery cell and the heat control plate laminated to each other.

Description

Battery module {BATTERY MODULE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery module, and more particularly, to a battery module formed by stacking a plurality of battery cells.

As interest in air pollution increases, efforts are constantly being made to develop vehicles using clean fuel. Electric vehicles developed as a part of this effort are driven by electricity generated from batteries. A battery included in an electric vehicle is manufactured by forming a module in a form of a module by electrically connecting a plurality of batteries (hereinafter, referred to as 'battery cells') to each other due to problems such as limited capacity and size .

In each of the battery cells, heat is generated every time the battery pack is repeatedly charged and discharged. If such heat can not be properly cooled in the battery module, deterioration of each battery cell may occur and overall performance of the battery module may deteriorate. In order to overcome such a problem, a cooling system for uniformly cooling a battery cell using a heating medium such as cooling water has been developed.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2013-0042430 (titled, battery module and middle- and large-sized battery module including the same, disclosed in Mar. 26, 2013).

It is an object of the present invention to provide a battery module capable of efficiently controlling heat generated from a plurality of battery cells and ensuring durability by modularizing a plurality of battery cells by stacking them together.

A battery module according to the present invention includes: a battery cell; A heat control plate having a heat exchange channel through which a heat transfer medium flows and alternately disposed with the battery cell and adjusting a temperature of the battery cell by heat exchange with a heat transfer medium; A coupling unit for tightly coupling the battery cell and the thermal control plate; And a module cover covering the cell stack formed by stacking the battery cell and the thermal control plate.

The thermal control plate may further include: a first sheet; A second sheet disposed in parallel with the first sheet; And an adhesive sheet adhering the first sheet and the second sheet to each other and having a thickness capable of forming the heat exchange channel between the first sheet and the second sheet.

The binding unit may include a bracket disposed between the battery cell and the thermal control plate, the bracket having a frame shape corresponding to an edge of the battery cell and the thermal control plate. A sealing member coupled to the bracket and forming a flow path between the plurality of heat control plates and communicating with the heat exchange flow path; And a binding member for binding the plurality of the brackets so as to tightly bond the thermal control plate to the battery cell and the watertight sealing member.

The bracket may include a first bracket having a rear portion in contact with a front portion of the battery cell and a front portion in contact with a rear portion of the thermal control plate; And a second bracket disposed alternately with the first bracket and having a rear portion contacting the rear portion of the thermal control plate and a front portion contacting the rear portion of the other battery cell.

Further, the bracket includes a bracket body portion having a frame shape; An inflow channel portion formed at one side of the bracket body portion and connected to the inflow hole portion formed in the thermal control plate via the sealing material; A discharge flow path formed on the other side of the bracket body and connected to the discharge hole formed in the thermal control plate through the sealing material; And a binding hole portion formed to penetrate the inflow channel portion and the discharge channel portion and to which the binding member is coupled.

The inlet passage portion may include an inlet passage connection hole formed to pass through a position corresponding to the inlet hole portion, And an inflow end step portion protruding inwardly on an inner surface portion of the inflow path connection hole portion and forming a stopping protrusion for catching the sealing member, wherein the discharge flow path portion is formed to penetrate at a position corresponding to the discharge hole portion A discharge hole connected to the discharge hole; And an outlet end protrusion formed to protrude inwardly on the inner surface of the discharge path connection hole and forming a stop protrusion for the sealing member to be caught.

Further, the sealing member may include a ring portion having a ring shape and fitted in the inflow passage connection hole portion, the discharge passage connection hole portion, A latching groove portion formed to be recessed around the ring portion and engaged with the inflow end step portion or the discharge end step portion; And an adhesion enhancing portion formed on the end of the ring portion that is exposed to the outside of the bracket and elastically contacted with the heat control plate or other sealing material.

In addition, the binding member may include: a first binding member which is inserted through the inflow channel portion; A second coupling member which is inserted through the discharge passage portion and is engaged; A third binding member coupled through one side of the bracket body at a position spaced apart from the first binding member; And a fourth binding member which is inserted through the other side of the bracket body at a position spaced apart from the second binding member.

Further, the present invention may further comprise a module connecting member for forming a flow path for communicating with the other cell stacked body or the fluid circulating apparatus outside the cell stacked body, It is preferable that the bracket is continuously penetrated and both end portions are bound to the module connecting member.

The module connecting member may include a finishing bracket portion having a width corresponding to the inflow channel portion and the discharge channel portion and to which the binding member is coupled; And a connection pipe part protruding from the finishing bracket part and having a passage through which the heat transfer medium can pass.

The module connecting member may include a first inlet connecting member disposed at one end of the cell stack body and forming an inlet through which the heat transfer medium flows; A second inflow passage connecting member disposed on the other end of the cell stack body, and a second inflow passage connecting member arranged continuously with the inflow hole portion; A first discharge path connecting member disposed at one side of one end and the other end of the cell stack body and constituting an outlet through which the fluid having passed through the thermal control plate is discharged; And a second discharge path connecting member disposed on the other one of the one end and the other end of the cell stack, and the first discharge path connecting member and the second discharge path connecting member disposed continuously with the discharge hole portion.

Also, the binding member may include: a first binding member that is coupled through the first inflow path connecting member and the second inflow path connecting member; And a second binding member coupled through the first discharge path connecting member and the second discharge path connecting member.

Further, the battery cell and the thermal control plate are stacked in the front-rear direction, and the module cover includes: a front panel that covers a front portion of the cell stack; And a rear panel covering a rear portion of the cell stack body, wherein the binding member is continuously connected to the front panel, the bracket, and the rear panel.

In the battery module according to the present invention, a plurality of battery cells and a heat transfer medium are alternately arranged, and a plurality of battery cells are stacked and bundled by a bundling unit and a module cover so as to be modularized. The heat generated in the battery cell can be efficiently controlled and durability can be ensured.

1 is a perspective view schematically showing a battery module according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of a battery module according to an embodiment of the present invention. FIG.
FIG. 3 is a perspective exploded perspective view showing a state in which the inner cover is further separated in FIG. 2;
Fig. 4 is an exploded perspective view showing a state in which the binding portion and the module connecting member are further separated in Fig. 3;
FIG. 5 is a perspective exploded perspective view schematically showing a cell stack of a battery module according to an embodiment of the present invention. FIG.
FIG. 6 is a perspective exploded perspective view schematically showing a thermal control plate of a battery module according to an embodiment of the present invention. FIG.
FIG. 7 is a perspective exploded perspective view schematically showing a bracket of a battery module according to an embodiment of the present invention. FIG.
8 is a conceptual diagram illustrating an electrical connection structure between a battery cell and a bus bar of a battery module according to an embodiment of the present invention.
FIG. 9 is a perspective exploded perspective view illustrating an assembling process of connecting a cell terminal of a battery cell of a battery module according to an embodiment of the present invention to a bus bar.
10 is a perspective view schematically showing an outer cover of a battery module according to an embodiment of the present invention.

Hereinafter, an embodiment of a battery module according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view schematically showing a battery module according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of a battery module according to an embodiment of the present invention, 3 is a perspective exploded perspective view showing a state in which the inner cover is further separated in Fig.

FIG. 4 is an exploded perspective view showing a state in which the binding portion and the module connecting member are further separated from each other in FIG. 3, and FIG. 5 is an exploded perspective view of the battery module according to the embodiment of the present invention, And FIG. 6 is a perspective exploded perspective view schematically showing a thermal control plate of a battery module according to an embodiment of the present invention.

FIG. 7 is an exploded perspective view schematically showing a bracket of a battery module according to an embodiment of the present invention, FIG. 8 is a perspective view illustrating an electrical connection structure between a battery cell and a bus bar of a battery module according to an embodiment of the present invention FIG. 9 is a perspective exploded perspective view illustrating an assembling process of connecting a cell terminal of a battery cell of a battery module according to an embodiment of the present invention to a bus bar, and FIG. 10 is a cross- 1 is a perspective view schematically showing an outer cover of a battery module according to an example.

1 and 5, a battery module according to an embodiment of the present invention includes a battery cell 10, a thermal control plate 20, a binding portion 30, a module cover 40, a module connecting member 50 ).

The battery cell 10 has a flat front panel and a rear panel as a whole, and a pair of cell terminals 11 are disposed apart from each other. One of the cell terminals 11 functions as a positive electrode and the other cell functions as a negative electrode.

The heat control plate 20 includes a heat exchange channel 24 through which a heat transfer medium flows, and is arranged alternately with the battery cell 10 in the front-rear direction. The heat control plate 20 has a flat panel shape in which the front and rear portions are in flat contact with the battery cell 10 and the heat emitted from the battery cell 10 is conducted to the thermal control plate 20. [ The temperature control plate 20 is cooled or warmed by heat exchange with the heat transfer medium passing through the heat exchange channel 24 therein. Here, a phase change material (PCM) can be applied as a heat transfer medium.

The binding unit 30 binds the plurality of battery cells 10 and the plurality of thermal control plates 20 in close contact with each other. The module cover 40 covers the cell stack body 1a formed by stacking the battery cell 10 and the thermal control plate 20. [ The module connecting member 50 is connected to the battery module according to the present invention by a bundle 30 and a module cover 40 to form a packaged cell stack 1a, Thereby forming a flow path for communicating with the fluid circulation device. Here, the fluid circulating device collectively refers to a device for supplying and circulating heat transfer medium to a battery module.

Referring to FIG. 6, a thermal control plate 20 according to an embodiment of the present invention includes a first sheet 21, a second sheet 22, and an adhesive sheet 23.

The first sheet 10 and the second sheet 20 are arranged facing each other in a flat plate shape. The first sheet 10 and the second sheet 20 are made of a metal material capable of heat transferring heat from the battery cell 10 to the heat transfer medium on the heat exchange path 24. The adhesive sheet 30 is an element that adheres the first sheet 10 and the second sheet 20 to each other and can form a heat exchange channel 24 between the first sheet 10 and the second sheet 20 Thickness. For example, when the adhesive sheet 30 having a thickness of 1 mm is applied, a heat exchange channel 24 having a height of 1 mm is formed between the first sheet 10 and the second sheet 20.

The heat control plate 20 is provided with an inlet hole portion 25 serving as a passage through which the heat transfer medium flows into the heat exchange passage 24 formed between the first sheet 10 and the second sheet 22, The discharge hole portion 26 forming a passage through which the heat transfer medium on the heat control plate 20 is discharged to the outside of the heat control plate 20 is formed.

The inlet hole portion 25 and the discharge hole portion 26 are positioned so as to correspond to the one end and the other end of the heat exchange passage 24 and are formed to communicate with the heat exchange passage 24. A part of the heat transfer medium passing through the inlet hole portion 25 enters the heat exchange passage 24 and is heat-exchanged with the heat control plate 20 while passing through the heat exchange passage 24, (20).

4 and 5, the binding unit 30 according to an embodiment of the present invention includes a bracket 31, a sealing member 32, and a binding member 33. [

The bracket 31 has a frame shape corresponding to the edge portions of the battery cell 10 and the thermal control plate 20 and is disposed between the battery cell 10 and the thermal control plate 20. [ Referring to FIG. 5, a bracket 31 according to an embodiment of the present invention includes a first bracket 31A and a second bracket 31B.

The rear portion of the first bracket 31A contacts the front portion of the battery cell 10 and the front portion of the first bracket 31A contacts the rear portion of the thermal control plate 20. [ The second bracket 31B is disposed alternately with the first bracket 31A and the rear portion thereof is in contact with the rear portion of the thermal control plate 20 and the front portion thereof is in contact with the rear portion of the other battery cell 10. The first bracket 31A and the second bracket 31B may be formed by alternately arranging the brackets 31 having the same structure in the front and rear directions so that the front and rear portions thereof are reversed can do.

Each of the brackets 31 has a thickness equal to one half of the thickness of the battery cell 10 plus one half of the thickness of the thermal control plate 20. [ If the plurality of brackets 31 are connected to each other while the battery cells 10 and the thermal control plate 20 are alternately disposed between the plurality of brackets 31, 20 are in close contact with each other, and a plurality of brackets 31 having a rectangular frame shape are continuously connected in forward and backward directions, thereby forming a hexahedral box shape in which the upper and lower portions and the left and right side portions are closed.

The thickness of the battery cell 10 and half of the thickness of the thermal control plate 20 is set to be a thickness corresponding to the half of the thickness of the battery cell 10 and the half of the thickness of the thermal control plate 20. [ It is not necessary to additionally provide a separate cover member for covering the upper and lower portions and the right and left portions of the cell stack body 1a by continuously connecting the plurality of brackets 31 having the brackets 31, The upper and lower portions and the left and right side portions of the side walls 1a and 1b can be continuously covered.

7, the bracket 31 includes a bracket body portion 311, an inflow passage portion 312, a discharge passage portion 315, and a binding hole portion 318. The bracket 311,

The bracket body 311 has a rectangular frame shape corresponding to the edge portions of the battery cell 10 and the thermal control plate 20 and has a half thickness of the battery cell 10 and a thickness of the heat control plate 20 Half the total thickness.

The inflow channel portion 312 is formed on the upper portion of the right side portion of the bracket body portion 311 and communicates with the inflow hole portion 25 formed in the thermal control plate 20 via the sealing material 32. Referring to FIG. 7, the inflow channel portion 312 according to an embodiment of the present invention includes an inflow path connection hole portion 313 and an inflow end portion 314.

The inflow path connection hole portion 313 is formed to pass through a position corresponding to the inflow hole portion 25. The inlet end stop portion 314 is formed to protrude inwardly on the inner surface portion of the inflow path connection hole portion 313 and forms a stopping hook for catching the stopping groove portion 322 of the sealing member 32. [

The discharge flow path portion 315 is formed on the upper portion of the left side portion of the bracket body portion 311 and communicates with the discharge hole portion 26 formed in the thermal control plate 20 via the sealing member 32. Referring to FIG. 7, the discharge passage portion 315 according to an embodiment of the present invention includes a discharge passage connection hole portion 316 and a discharge end portion 317.

The discharge passage connection hole portion 316 is formed so as to pass through a position corresponding to the discharge hole portion 26. The discharge end stop portion 317 is formed to protrude inwardly on the inner surface portion of the discharge hole portion 316 to form a stopping portion for catching the stopping groove portion 322 of the sealing member 32. [

The binding hole portion 318 is a portion through which the binding member 33 is penetrated and connected to the right and left lower portions of the inlet channel portion 312 and the drain channel portion 315 and the bracket body portion 311, As shown in FIG. When forming the binding hole 318 on the inflow channel 312, a pair is spaced apart with the inflow channel connecting hole 313 therebetween. When the binding hole 318 is formed on the discharge channel portion 315, a pair of the discharge hole portion 316 is spaced apart from each other.

A plurality of binding hole portions 318 formed in each of the brackets 31 form a linear hole portion extending in the front and rear direction together with the plurality of brackets 31 arranged in the front and rear direction, (33) is assembled and coupled so as to continuously penetrate the linear hole portion formed by the plurality of binding hole portions (318).

The sealing member 32 is a member that connects the plurality of thermal control plates 20 in a watertight manner and is fitted and inserted into the inlet passage connection hole portion 313 and the discharge passage connection hole portion 316 of the bracket 31. The sealing member 32 is made of a non-metallic elastic material such as rubber, silicone, or the like. The sealing member 32 attached to each of the brackets 31 forms a flow path communicating with the heat exchange flow path 24 between the plurality of the thermal control plates 20 in a state in which the plurality of brackets 31 are in close contact with each other. The seal member 32 coupled to the discharge passage connection hole portion 313 forms a continuous linear flow passage with the inlet hole portion 25 and the sealing member 32 coupled to the discharge passage connection hole portion 316 is connected to the discharge hole portion 26 To form a continuous linear flow path.

7, the sealing member 32 according to an embodiment of the present invention includes a ring portion 321, a latching groove portion 322, and a contact strengthening portion 323. [

The ring portion 321 has a ring shape in which a hole for allowing a heat transfer medium to pass therethrough is formed, and is inserted into the inlet passage connecting hole portion 313 and the discharge passage connecting hole portion 316. The engaging groove portion 322 is formed to be depressed around the outer surface portion of the ring portion 321 and is engaged with the inlet end stop portion 314 or the discharge end stop portion 317 to be engaged. When the ring portion 321 is fitted into the inlet passage connection hole portion 313 and the discharge passage connection hole portion 316, the inlet end stop portion 314 or the discharge end stop portion 317 naturally fits into the engagement groove portion 322, The ring portion 321 is reliably held in the correct position on the inflow path connection hole portion 313 and the discharge path connection hole portion 316 while the flow is restricted.

The adhesion enhancing portion 323 is formed to protrude in the forward and backward directions on the front portion and the rear portion of the ring portion 321 exposed to the outside of the bracket 31. The sealing member 32 can be attached to the front or rear portion of the thermal control plate 20 and the other adjacent neighboring brackets 31 in a state in which the plurality of brackets 31 are in close contact with each other, The sealing member 32 can be firmly adhered to the heat control plate 20, thereby ensuring the watertightness of the flow path through which the heat transfer medium flows.

The binding member 33 binds the plurality of brackets 31 to bind the heat control plate 20 in close contact with the battery cell 10 and the watertight sealing member 32. As the binding member 33, a pin, a bolt, or the like that can continuously penetrate the plurality of brackets 31 can be used. 4, the binding member 33 according to the embodiment of the present invention includes a first binding member 331, a second binding member 332, a third binding member 333, a fourth binding member 334 ). The plurality of brackets 31 are firmly coupled to each other at four spaced apart positions where the first binding member 331, the second binding member 332, the third binding member 333 and the fourth binding member 334 are coupled do.

The first binding member 331 passes through the inflow channel portion 312 and is fastened. One pair of first binding members 331 are disposed with the inflow channel portion 312 therebetween. Accordingly, an adhesive force can be uniformly applied to the entire circumference of the sealing member 32 coupled to the inflow channel portion 312.

The first binding member 331 includes a second inflow passage connecting member 50B, a front panel 41, a binding hole 318 formed in the inflow channel portion 312 of each of the plurality of brackets 31, a bracket 31, The rear panel 42, and the first inlet connecting member 50A, which are disposed between the heat control plate 20,

The second coupling member 332 penetrates through the discharge passage portion 315 and is fastened. A pair of second coupling members 332 are disposed with the discharge passage portion 315 therebetween. Accordingly, an adhesive force can be evenly applied to the entire circumference of the sealing member 32 coupled to the discharge passage portion 315. [

The second binding member 332 includes a second discharge path connecting member 50D, a front panel 41, a binding hole 318 formed in the discharge channel portion 315 of each of the plurality of brackets 31, a bracket 31, The rear panel 42, and the first discharge path connecting member 50C, which are disposed between the first discharge path connecting member 50C and the second discharge path connecting member 50C.

 The both end portions of the first binding member 311 are connected to the second inlet connecting member 50B and the first inlet connecting member 50A by a method such as bolting, riveting, 332 are bound to the second discharge path connecting member 50D and the first discharge path connecting member 50C by a method such as bolting, riveting, clamping, joining, or the like, It is possible to stably cover the cell stack body 1a in the up-and-down direction, the left-right direction, and the back-and-forth direction by the bracket 31, the front panel 41 and the rear panel 42, And at the same time, a fluid connection part that can be connected to an external fluid circulation device or a flow path of another battery module can be formed.

The third coupling member 333 passes through the lower right portion of the bracket body portion 311 and is fastened. That is, the third binding member 333 is disposed on the lower side of the first binding member 331. The fourth binding member 334 passes through the lower left portion of the bracket body portion 311 and is fastened. That is, the fourth binding member 334 is disposed on the lower side of the second binding member 332.

4, the module connecting member 50 according to the embodiment of the present invention includes a first inlet connecting member 50A, a second inlet connecting member 50B, a first outlet connecting member 50C, And a second discharge path connecting member 50D.

The first inlet connecting member 50A is disposed on the right side of the rear portion of the cell stack body 1a and forms an inlet through which the heat transfer medium flows. The second inlet connecting member 50B is disposed continuously with the first inlet connecting member 50A and the inlet hole 25 at the right side of the point portion of the cell laminate 1a. The first coupling member 331 is coupled through the first inlet connection member 50A and the second inlet connection member 50B.

The first discharge path connecting member 50C is disposed at the left side of the rear portion of the cell stack 1a and constitutes an outlet through which the fluid that has passed through the thermal control plate 20 is discharged. The second discharge path connection member 50D is disposed at the left side of the front portion of the cell stack body 1a and is disposed continuously with the first discharge path connection member 50C and the discharge hole portion 26. [ The second coupling member 332 is coupled through the first discharge path connecting member 50C and the second discharge path connecting member 50D.

Referring to FIG. 4, a module connecting member 50 according to an embodiment of the present invention includes a finishing bracket portion 51 and a connecting pipe portion 52.

The finishing bracket portion 51 has a shape of a panel piece having a width corresponding to the inflow passage portion 312 and the discharge passage portion 315. The connecting pipe portion 52 is formed to protrude in the front-rear direction at a position corresponding to the inflow path connection hole portion 313 and the discharge path connection hole portion 316. The binding member 33 is fastened through the finishing bracket portion 51 with the connecting pipe portion 52 interposed therebetween.

In the interior of the connecting pipe portion 52, a flow path through which the heat transfer medium can pass is opened in the front-rear direction. The connecting pipe portion 52 is connected to the inlet connecting hole portion 313 and the outlet connecting hole portion 313 in a state where the module connecting member 50 is tightly bound to the cell stack body 1a by using the binding member 33. [ 316, respectively.

2 to 4, a module cover 40 according to an embodiment of the present invention includes a front panel 41, a rear panel 42, an inner cover 43, a bus bar 44, an outer cover 45).

The front panel 41 has a panel shape capable of covering the front portion of the cell stack body 1a. The rear panel 42 has a panel shape capable of covering the rear portion of the cell stack body 1a. The binding member 33 is continuously penetrated through the front panel 41, the plurality of brackets 31, the plurality of thermal control plates 20 disposed between the brackets 31, and the rear panel 42.

The inner cover 43 has a through hole portion 431a through which the cell terminal 11 of the battery cell 10 can pass and is joined to the upper portion of the cell stack body 1a. The inner cover 43 includes an insulating material such as a synthetic resin material that can not conduct electricity. The cell terminal 11 protrudes upward from the inner cover 43 through the inner cover 43 in a state where the inner cover 43 is coupled to the upper portion of the cell stack body 1a. 3, the inner cover 43 according to an embodiment of the present invention includes a seat portion 431, a bus bar mounting portion 432, a bracket connecting portion 435, and an external connecting portion 436 .

The seating portion 431 is seated on the cell stacked body 1a with a width enough to cover a plurality of cell terminals 11 disposed on the top of the cell stacked body 1a. A through-hole portion 431a through which the cell terminal 11 can pass is formed on the seating portion 431.

The bus bar mounting portion 432 is a portion on which the bus bar 44 is seated and installed and is formed to cross the through hole portion 431 on the seating portion 431. Referring to FIG. 9, the bus bar mounting portion 432 according to an embodiment of the present invention includes a seating leg 433 and a mounting jaw 434.

The seating leg portion 433 is a portion on which the bus bar 44 is seated and is arranged so as to cross the passage hole portion 431a in the left-right direction between the cell terminals 11. The assembly jaw 434 restrains the movement of the bus bar 44 seated on the seating leg 433 and projects upwardly at a position corresponding to the end of the bus bar 44 in the seating leg 433 . The bus bar 44 can be easily positioned in the correct position on the seating leg 433 by positioning the bus bar 44 so as to be in contact with the assembly step 434.

The bracket coupling portion 435 is a portion that binds the seating portion 431 to the bracket 31 and is formed to protrude downward on the seating portion 431. Referring to FIG. 3, the bracket fastening part 435 according to an embodiment of the present invention includes a first elastic body part 435a and a second elastic body part 435b.

The first elastic body part 435a is formed to protrude downward on the right side of the seating part 431. [ More specifically, the first elastic body part 435a extends from the right side of the seating part 431 to the lower end of the inflow channel part 312 protruding to the right on the right side of the bracket body part 311, And a latching protrusion protruding leftward from a lower end of the extending leg portion. The first elastic body portion 435a is engaged with the lower end portion of the inflow channel portion 312 and is fastened.

The second elastic body part 435b is formed symmetrically with the first elastic body part 435a on the left side of the seating part 431. [ More specifically, the second elastic body portion 435b extends from the left side portion of the seating portion 431 to the left side portion of the bracket body portion 311 and extends downward to the lower end portion of the discharge channel portion 315, And a shoulder portion protruding to the right from the lower end of the extending leg portion. The second elastic body part 435b is engaged with the discharge channel part 315 while facing the first elastic body part 435a.

The first elastic body part 435a and the second elastic body part 435b are naturally opposed to each other so that the inlet channel part 312 and the discharge channel part 315, the assembly of the seat part 431 and the cell stack body 1a can be facilitated.

The first cover member 435a and the second cover member 435b are moved away from the inflow passage portion 312 and the discharge passage portion 315 to move the inner cover 43 to the cell stack 1a. ≪ / RTI > When the bus bar 44 and the outer cover 45 are coupled to the inner cover 43 and the inner cover 43 is separated from the cell stack body 1a as described above, The outer cover 45 can be easily detached from the cell laminate 1a together.

The outer fastening portion 436 is a portion for fastening the outer cover 45 to the inner cover 43 and is formed to protrude upward on the seat cover 431 toward the outer cover 45. Referring to FIG. 3, the outer fastening portion 436 according to an embodiment of the present invention includes a circumferential fastening portion 436A and an intermediate fastening portion 436B. The peripheral fastening portion 436A is disposed at the edge portion of the seating portion 431 having a rectangular panel shape, that is, disposed at the left side portion and the right side portion, the front portion and the rear portion, and is fastened to the outer cover 45. The intermediate piece 436B is disposed in the middle portion of the seat portion 431 and is fastened to the outer cover 45. [

9, the outer fastening part 436 according to an embodiment of the present invention has the first snap fastening part 437 and the second snap fastening part 436B, that is, the peripheral fastening part 436A and the intermediate fastening part 436B, (438).

The first snap engagement portion 437 is formed to protrude upward from the seating portion 431 and has a latching portion formed at an upper end thereof to engage with the outer cover 45. The second snap engagement portion 438 has a shape symmetrical to the first snap engagement portion 437 and is spaced apart from the first snap engagement portion 437. The upper end edge portions of the first snap engagement portion 437 and the second snap engagement portion 438 are formed so that the tapered portion for guiding downward movement of the fastening hole portion 452 of the outer cover 45 is inclined.

Accordingly, when the outer cover 45 is seated on the inner cover 43, the first and second snap engagement portions 437 and 437, which are in contact with the edge portions of the fastening hole portions 452 formed in the outer cover 45, 438 are passed through the fastening hole 452 while being spaced apart from each other by the elastic force of the first and second snap fastening portions 437, 438.

The first snap engagement portion 437 and the second snap engagement portion 438 are brought into close contact with the inner surface portion of the fastening hole portion 452 by the restoring force while the fastening tuck portion passes through the fastening hole portion 452 as described above, The engaging jaw portion remains in the engaged state on the upper surface of the edge portion of the fastening hole portion 452.

When the outer cover 45 is seated on the upper portion of the inner cover 43, the inner cover 43 and the outer cover 43 are pressed against each other by the elastic force of the first and second snap-engagement portions 437 and 438, 45 can be easily assembled. The operation of bringing the upper portion of the first snap engagement portion 437 and the upper portion of the second snap engagement portion 438 close to each other exposes the outer cover 45 to the inner cover 43 ). ≪ / RTI >

The bus bar 44 electrically connects a plurality of cell terminals 11 and an electromagnetic device disposed outside the battery module 1 such as a power supply device or a circuit board and includes a conductive material such as a metal material And is installed in the inner cover 43. 8 and 9, a bus bar 44 according to an embodiment of the present invention includes an inner bus bar 441, a circumscribed bus bar 445, and a cell terminal holding member 448.

The inner bus bar 441 electrically connects the plurality of cell terminals 11 inside the outer cover 45. Referring to FIG. 9, an internal bus bar 441 according to an embodiment of the present invention includes a first internal bus bar 441a and a second internal bus bar 441b.

The first internal bus bar 441a has a flat panel shape and is seated on the inner cover 43. The second internal bus bar 441b has the same shape as the first internal bus bar 441a and is stacked on top of the first internal bus bar 441a. Between the first internal bus bar 441a and the second internal bus bar 441b, the ends of the pair of cell terminals 11 positioned in front of and behind the first internal bus bar 441a are fitted.

The end of the cell terminal 11 located in front of the first internal bus bar 441a is bent backward and the end of the cell terminal 11 located at the rear of the first internal bus bar 441a is bent forward The first inner bus bar 441a and the second inner bus bar 441b are stacked on the first inner bus bar 441a and the second inner bus bar 441b on the upper side thereof, The pair of cell terminals 11 are constrained.

The cell terminal fixing member 448 sequentially passes through the second internal bus bar 441b, the pair of front and rear cell terminals 11 and the first internal bus bar 441a and is fastened to the bus bar mounting portion 432 . The cell terminal 11 is connected to the first internal bus bar 441a and the second internal bus 442 in a state where the internal bus bar 441 is bound to the bus bar mounting portion 432 with the cell terminal fixing member 448, So that it can be electrically and stably connected to the internal bus bar 441 in a state in which the both sides are in close contact with the bar 441b.

Referring to FIG. 9, an internal bus bar 441 according to an embodiment of the present invention includes a first extension portion 442, a second extension portion 443, and a connection portion 444.

The first extending portion 442 has a straight line shape extending in the left-right direction. The second extension portion 443 is disposed in parallel with the first extension portion 442 in front of or behind the first extension portion 442. The connection portion 444 connects the first extension portion 442 and the second extension portion 443. Due to the shape of the first extending portion 442, the second extending portion 443, and the connecting portion 444, the internal bus bar 441 has a U-shape as a whole.

Referring to FIG. 8, a plurality of internal bus bars 441 are arranged in the front-rear direction so as to electrically connect a plurality of battery cells 10 in the front-rear direction. The internal bus bars 441 are arranged to form a left column arranged in a line at a position corresponding to the left cell terminal 11 and a right column arranged in a line at a position corresponding to the right cell terminal 11. [

The left column and the right column show the first extended portion 442 of the inner bus bar 441 constituting the left column and the second extended portion 443 of the inner bus bar 441 constituting the right column form the same row I.e., in contact with one battery cell 10. A pair of cell terminals 11 adjacent to each other in the front-rear direction is connected to each first extended portion 442. A pair of cell terminals 11 connected to the first extending portion 442 and another pair of cell terminals 11 neighboring in the back and forth direction are connected to the respective second extending portions 443.

The outer bus bar 445 electrically connects the cell terminal 11 and the electromagnetic device outside the outer cover 45. The external bus bar 445 is connected to the battery cell 10 connected to the rearmost internal bus bar 441 and the anode bus bar 445A connected to the battery cell 10 connected to the foremost internal bus bar 441, And a negative bus bar 445B.

8, the current flowing into the positive bus bar 445A flows through a pair of right cell terminals 11 connected to the positive bus bar 445A into a pair of battery cells 10 located at the forefront And flows to the left cell terminal 11 of the battery cell 10 through the inside of the battery cell 10. Next, the current flows into the first extended portion 442 of the internal bus bar 441 which is disposed on the left side of the anode bus bar 445A and connected to the left cell terminal 11 of the battery cell 10, And flows to the second extended portion 443 via the connection portion 444 of the corresponding internal bus bar 441.

The current flows into the pair of left cell terminals 11 connected to the second extension portion 443 and flows into the right cell terminal 11 of the battery cell 10 through the inside of the battery cell 10 Flow. Next, the current flows into the first extended portion 442 of the inner bus bar 441 disposed on the right side of the second extended portion 443 of the inner bus bar 441 disposed at the foremost position, And flows to the second extending portion 443 through the connecting portion 444 of the second connecting portion 441. The current is repeatedly passed through all of the plurality of battery cells 10 to reach the negative bus bar 445B.

8 and 9, the outer bus bar 445 according to an embodiment of the present invention includes a first outer bus bar 445a and a second outer bus bar 445b. The first external bus bar 445a has a flat panel shape and is seated in the bus bar mounting portion 432. The second external bus bar 445b has the same shape as the first external bus bar 445a and is stacked on top of the first external bus bar 445a. Between the first external bus bar 445a and the second external bus bar 445b, the ends of the pair of cell terminals 11 positioned in front of and behind the first external bus bar 445a are fitted.

The end of the cell terminal 11 positioned at the front of the first external bus bar 445a is bent backward and the end of the cell terminal 11 positioned at the rear of the first external bus bar 445a is bent forward The first outer bus bar 445a and the second outer bus bar 445b are stacked on the upper side in such a manner that the first outer bus bar 445a and the second outer bus bar 445b are stacked, The pair of cell terminals 11 are constrained.

The cell terminal fixing member 448 sequentially passes through the second external bus bar 445b, the pair of front and rear cell terminals 11 and the first external bus bar 445a and is fastened to the bus bar mounting portion 432 . The cell terminal 11 is connected to the first external bus bar 445a and the second external bus 445a in a state where the external bus bar 445 is bound to the bus bar mounting portion 432 with the cell terminal fixing member 448, So that the outer bus bar 445 can be electrically and stably connected to the bar 445b in a state in which both surfaces are in close contact with each other.

Referring to FIGS. 8 and 9, the outer bus bar 445 according to an embodiment of the present invention includes an inner extension 446 and an outer extension 447.

The inner extension portion 446 is located inside the outer cover 45 with a straight line shape extending in the left-right direction. In the description of the present invention, it means that it is located at the position covered by the outer cover 45. [ The outer extension portion 447 is formed continuously with the inner extension portion 446 so as to extend outside the outer cover 45.

The inner extension 446 is connected to a pair of cell terminals 11 located adjacent to the front and rear of the inner extension 446 and the outer extension 447 is electrically connected to the electromagnetic device outside the outer cover 45 . Here, the electromagnetic device may be an electronic opportunity, a power supply, or a neighboring battery module.

The outer cover 45 is an insulating cover covering a plurality of cell terminals 11 and a plurality of bus bars 44 excluding the outer extending portion 447 so as to be insulated from the outside, do.

Referring to FIG. 10, the outer cover 45 according to an embodiment of the present invention includes a cover portion 451, a fastening hole portion 452, and a reinforcing rib portion 453.

The cover portion 451 has a panel shape in which a plurality of cell terminals 11 and a bus bar 44 can be covered or a box shape in which a lower portion is opened. The fastening hole portion 452 is a portion to be fastened to the external fastening portion 436 formed on the inner cover 43 and is formed to penetrate in the vertical direction on the cover portion 451. The outer engaging portion 436 formed in the inner cover 43 penetrates the fastening hole portion 452 from the lower side to the upper side and engages the upper end of the fastening hole portion of the fastening hole portion 452 at the end of the fastening hole portion 452, The fastening is achieved.

The reinforcing rib portion 453 is for reinforcing the flexural rigidity of the cover portion 451 having a panel shape and is provided on one side portion of the cover portion 451 and more specifically on the inner surface facing the inner cover 43 Respectively. A plurality of reinforcing rib portions 453 extend from one end to the other end of the cover portion 451 so as to extend in the left-right direction and the front-rear direction, and a plurality of the ribs 453 extending in the left- .

The lattice shape of the reinforcing rib portion 453 can stably reinforce the flexural rigidity of the cover portion 451 over the entire surface of the cover portion 451. By forming the reinforcing rib portion 453, It is possible to more reliably realize insulation of the bus bar 44 by the cover part 45 by preventing direct contact between the bus bar 44 and the cover part 451 coupled to the cover part 45 and forming a hollow clearance.

A plurality of battery cells 10 and a heat transfer medium 20 are alternately arranged and the bundle 30 and the module cover 40 form a plurality of batteries By bundling and covering the cells 10 to form a module, it is possible to efficiently control the heat generated in the battery cell 10 and realize durability in realizing a large capacity battery.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

1a: Cell laminate 10: Battery cell
11: cell terminal 20: thermal control plate
21: first sheet 22: second sheet
23: adhesive sheet 24: heat exchange channel
25: inflow hole portion 26: discharge hole portion
30: coupling portion 31: bracket
31A: first bracket 31B: second bracket
32: Sealing material 33:
40: Module cover 41: Front panel
42: rear panel 43: inner cover
44: bus bar 45: outer cover
50: a module connecting member 50A: a first inflow path connecting member
50B: second inlet connecting member 50C: first outlet connecting member
50D: second discharge path connecting member 51: finishing bracket part
52: connecting pipe part 311: bracket body part
312: Inflow channel portion 313: Inflow channel connection hole portion
314: Inflow end jaw 315:
316: connection to discharge outlet hole 317: outlet end jaw
318: tying hole portion 321:
322: latching groove portion 323:
331: first binding member 332: second binding member
333: third binding member 334: fourth binding member
431: seat part 431a: through hole part
432: bus bar mounting portion 433:
434: assembly jaw portion 435: bracket fastening portion
435a: first elastic body part 435b: second elastic body part
436: outer fastening part 436A:
436B: Intermediate assembly 437: First snap fit
438: Second snap fitting part 441: Inner bus bar
441a: first internal bus bar 441b: second internal bus bar
442: first extension part 443: second extension part
444: connection 445: external bus bar
445A: anode bus bar 445a: first outer bus bar
445B: cathode bus bar 445b: second external bus bar
446: inner extension part 447: outer extension part
448: Cell terminal fixing member 451: Cover part
452: fastening hole portion 453: reinforcing rib portion

Claims (13)

A battery cell;
A heat control plate having a heat exchange channel through which a heat transfer medium flows and alternately disposed with the battery cell and adjusting a temperature of the battery cell by heat exchange with a heat transfer medium;
A coupling unit for tightly coupling the battery cell and the thermal control plate; And
And a module cover covering the cell stack formed by stacking the battery cell and the thermal control plate.
The method according to claim 1,
Wherein the thermal control plate comprises:
A first sheet;
A second sheet disposed in parallel with the first sheet; And
And an adhesive sheet adhering the first sheet and the second sheet to each other and having a thickness capable of forming the heat exchange channel between the first sheet and the second sheet.
The method according to claim 1,
The binding portion
A bracket disposed between the battery cell and the thermal control plate and having a frame shape corresponding to an edge of the battery cell and the thermal control plate;
A sealing member coupled to the bracket and forming a flow path between the plurality of heat control plates and communicating with the heat exchange flow path; And
And a binding member for binding the plurality of the brackets to tightly bond the thermal control plate to the battery cell and the watertight sealing member.
The method of claim 3,
The bracket
A first bracket having a rear portion in contact with a front portion of the battery cell and a front portion in contact with a rear portion of the thermal control plate; And
And a second bracket disposed alternately with the first bracket and having a rear portion contacting a rear portion of the thermal control plate and a front portion contacting a rear portion of the other battery cell.
5. The method of claim 4,
The bracket
A bracket body portion having a frame shape;
An inflow channel portion formed at one side of the bracket body portion and connected to the inflow hole portion formed in the thermal control plate via the sealing material;
A discharge flow path formed on the other side of the bracket body and connected to the discharge hole formed in the thermal control plate through the sealing material; And
And a coupling hole formed to penetrate through the inflow channel portion and the discharge channel portion and to which the coupling member is coupled.
6. The method of claim 5,
The inflow-
An inlet connection hole formed to pass through a position corresponding to the inlet hole; And
And an inflow end jaw portion formed to protrude inwardly on an inner surface portion of the inflow path connection hole portion and forming a stopping jaw for receiving the sealing member,
The discharge-
A discharge passage connecting hole formed to pass through the discharge hole at a position corresponding to the discharge hole; And
And a discharge end protrusion formed to protrude inward on the inner surface of the discharge passage connecting hole and forming a latching protrusion to which the sealing member is caught.
The method according to claim 6,
The sealing member
A ring portion having a ring shape and fitted in the inflow passage connection hole portion and the discharge passage connection hole portion;
A latching groove portion formed to be recessed around the ring portion and engaged with the inflow end step portion or the discharge end step portion; And
And a contact reinforcing portion protruding from an end of the ring portion exposed to the outside of the bracket and elastically contacting the heat control plate or other sealing material.
6. The method of claim 5,
The binding member
A first binding member which penetrates through the inflow channel portion and is fastened;
A second coupling member which is inserted through the discharge passage portion and is engaged;
A third binding member coupled through one side of the bracket body at a position spaced apart from the first binding member; And
And a fourth binding member coupled through the other side of the bracket body at a position spaced apart from the second binding member.
6. The method of claim 5,
Further comprising: a module connecting member for forming a flow path for communicating with the other cell stack or the fluid circulating device outside the cell stack,
The binding member
And the module connecting member and the bracket successively penetrate through the module connecting member, and both end portions are bound to the module connecting member.
10. The method of claim 9,
The module connecting member includes:
A finishing bracket portion having a width corresponding to the inflow channel portion and the discharge channel portion and to which the binding member is coupled; And
And a connection pipe part protruding from the finishing bracket part and having a passage through which the heat transfer medium can pass.
11. The method according to claim 9 or 10,
The module connecting member includes:
A first inlet connection member disposed at one end of the cell stack body and constituting an inlet through which the heat transfer medium flows;
A second inflow passage connecting member disposed on the other end of the cell stack body, and a second inflow passage connecting member arranged continuously with the inflow hole portion;
A first discharge path connecting member disposed at one side of one end and the other end of the cell stack body and constituting an outlet through which the fluid having passed through the thermal control plate is discharged; And
And a second discharge path connecting member disposed on the other one of the one end and the other end of the cell stack body and being connected to the first discharge path connecting member and the discharge hole portion.
12. The method of claim 11,
The binding member
A first binding member coupled through the first inlet connection member and the second inlet connection member; And
And a second coupling member coupled through the first discharge path connection member and the second discharge path connection member.
10. The method according to claim 3 or 9,
Wherein the battery cell and the thermal control plate are laminated in the front-rear direction,
The module cover includes:
A front panel covering a front portion of the cell stack body; And
And a rear panel covering a rear portion of the cell stack,
The binding member
And the front panel, the bracket, and the rear panel are continuously connected to each other.

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