KR101503983B1 - Housing structure and housing method of Battery Module Assembly - Google Patents

Abstract

The present invention relates to a housing structure and a housing method of a battery module assembly for housing a plurality of cell module assemblies, wherein the housing structure of the battery module assembly includes a plurality of cell module assemblies, A pair of end plates which are respectively pressed and supported from front and rear sides of the base plate and have protrusions protruded downward; And a base plate having an engaging groove portion for fixing each of the cell module assemblies supported by the pair of end plates downward and engaging with the projecting portion of the end plate to fix each of the end plates downwardly, . As described above, the present invention simplifies the assembling process by combining the end plates and the base plate by their own shapes, thereby improving the manufacturing efficiency and reducing the manufacturing cost by reducing the number of fastening parts for fixing.

Description

[0001] The present invention relates to a housing structure and a housing method of a battery module assembly,

The present invention relates to a housing structure and a housing method of a battery module assembly (BMA), and more particularly, to a housing structure and a housing method of a battery module assembly constituting a battery applied to a vehicle.

A battery module assembly (BMA) applied to a hybrid and an electric vehicle is generally made by combining a plurality of cell module assemblies (CMAs).

Generally, a battery module assembly has a structure for fixing two end plates, which hold stacked cell module assemblies on both sides, to the base plate so as to couple and house a plurality of cell module assemblies.

However, the housing structure of the battery module assembly for housing such a cell module assembly can be simplified by increasing the number of assembling processes and the number of components by using a fastening member such as a weld nut, bolt, or the like to fix the end plate to the base plate The manufacturing efficiency is lowered and the manufacturing cost is increased.

KR 10-0783871 B, Dec. 10, 2007

It is an object of the present invention to simplify the assembling process by performing the joining by the own shape of the end plate and the base plate while minimizing the use of the fastening member for fixing the end plate and the base plate in the related art, To provide a housing structure and a housing method of a battery module assembly.

According to an aspect of the present invention, there is provided a housing structure of a battery module assembly for housing a plurality of cell module assemblies.

The housing structure of the battery module assembly includes: a pair of end plates, each of which presses and supports the cell module assemblies from the front and rear in the stacking direction, and has a protrusion formed downward; And a base plate having an engaging groove portion for fixing each of the cell module assemblies supported by the pair of end plates downward and engaging with the projecting portion of the end plate to fix each of the end plates downwardly, .

Wherein the coupling grooves are formed in a central region of the base plate so as to be bent along the longitudinal direction, the lower side surfaces of the laminated cell module assemblies being in contact with the left and right regions of the base plate except for the coupling groove portions, May be fixed to the left and right regions of the base plate by fastening members.

The protrusions of the front end plates for pressing the cell module assemblies from the front in the stacking direction are bent and protruded from the left and right regions except for the center of the lower side of the front end plate so as to be in contact with both sides of the coupling groove And protrusions of the rear end plate for pressing the cell module assemblies from the rear in the stacking direction may be formed by bending and protruding the central region of the rear end plate so as to contact both the side surfaces and the bottom surface of the coupling groove.

The width of the rear side of the coupling groove portion may be smaller than the entire width of the coupling groove portion.

The cell module assembly has a fixing piece formed to extend outwardly from a lower end of both side portions, and a fastener corresponding to the fastening member may be formed on the fastening piece.

According to another aspect of the present invention, there is provided a method of housing a battery module assembly for housing a plurality of cell module assemblies.

A method of housing a battery module assembly includes the steps of: preparing a front end plate and a rear end plate having protrusions protruded downward; Pressing and supporting the cell module assemblies from the front and rear sides in the lamination direction using the front end plate and the rear end plate, respectively; Preparing a base plate having an engaging groove for fixing each of the end plates downward; The lower side surfaces of the cell module assemblies supported by the end plates are disposed so as to be in contact with the left and right regions of the base plate except for the engagement groove portions, the protrusion portions are coupled to the engagement groove portions, Determining the position of the cell module assemblies supported by the end plates relative to the base plate by moving the cell module assemblies; And fixing each of the cell module assemblies to the left and right regions of the contacted base plate using a fastening member at an arrangement position determined relative to the base plate,
The upper and lower ends of the pair of end plates are connected by installing a plurality of upper support bars and a plurality of lower end support bars to compress and support the cell module assemblies.

The protrusions of the front end plate are respectively bent and protruded in a part of the left and right regions except the center of the lower side of the front end plate so as to be in contact with both sides of the coupling groove, The protruding portion of the rear end plate may be formed by bending and protruding the central region of the rear end plate so as to be in contact with both side surfaces and the bottom surface of the coupling groove portion.

The width of the rear side of the coupling groove portion may be smaller than the entire width of the coupling groove portion.

The cell module assembly has a fixing piece formed to extend outwardly from a lower end of both side portions, and a fastener corresponding to the fastening member may be formed on the fastening piece.

As described above, the present invention simplifies the assembling process by combining the end plate and the base plate by their own shapes, thereby improving the manufacturing efficiency and reducing the number of fastening parts for fixing, thereby reducing the manufacturing cost.

In addition, when the cell module assemblies are not fixed to the base plate, the protrusions of the front and rear end plates are slid along the engaging groove to adjust the arrangement position of the cell module assemblies relative to the base plate, have.

Further, the present invention can contribute to improvement of the cooling function of the cell module assemblies because the central region of the projecting portion of the front end plate does not contact the inner bottom surface of the engaging groove portion.

1 and 2 are perspective views of a housing structure of a battery module assembly according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA of FIG.
4 is a cross-sectional view taken along line BB in Fig.
5 is a cross-sectional view taken along CC in Fig.
6 is a flowchart of a method of housing a battery module assembly in accordance with an embodiment of the present invention.

Hereinafter, a housing structure and a housing method of a battery module assembly according to one embodiment of the present invention will be described with reference to the accompanying drawings.

1 and 2 are perspective views of a housing structure of a battery module assembly according to an embodiment of the present invention, FIG. 3 is a cross-sectional view taken along AA of FIG. 1, 2 is a cross-sectional view taken along line CC in Fig.

The housing structure of the battery module assembly 1 is for housing a cell module assembly.

1 and 2, the housing structure of the battery module assembly 1 includes a front end plate 20 and a rear end plate 30 for pressing and supporting the cell module assemblies 10 from the front and rear directions, respectively, And a base plate 40 for fixing them downward.

The stacked cell module assemblies 10 are supported by a front end plate 20 and a rear end plate 30. The lower side of the stacked cell module assemblies 10 is in contact with the left and right regions 44 of the base plate 40 except for the engaging grooves 42 and each of the cell module assemblies 10 is fastened by the fastening members 14 And is fixed to the left and right regions 44 of the base plate 40.

3, the cell module assembly 10 includes a fixing piece 12 formed to extend outwardly from the lower ends of both side portions, and the fixing piece 12 corresponds to the fastening member 14 Can be formed.

For example, the fastening members 14 are bolted to fasten the fastening pieces 12 of the cell module assembly 10 to the left and right regions 44 of the base plate 40 through the fastening holes.

The front end plate 20 and the rear end plate 30 have protrusions 22 and 32 protruded downward, respectively.

The protruding portions 22 and 32 are formed corresponding to the engaging groove portions 42 of the base plate 40 and engage with the engaging groove portions 42 to connect the front end plate 20 and the rear end plate 30 to the base plate 40 ).

The front end plate 20 is for pressing the cell module assemblies 10 from the front in the stacking direction. The upper end support plate 310 is configured to support the upper ends of the front end plate 20 and the rear end plate 30, A lower support bar 320 is formed. The upper support bar 310 includes a first upper support bar 310-1 and a second upper support bar 310-2 and the lower end support bar 311 includes a first lower support bar 311-1, And a second lower support bar 311-2.

4, the protruding portions 22 of the front end plate 20 are formed so as to be in contact with both side surfaces 422 of the engaging groove portion 42, in the right and left regions except for the center of the lower side surface of the front end plate 20. [ Are partially bent and protruded.

The projecting portion 22 of the front end plate 20 can be fixed to the engaging groove portion 42 by the elastic force acting in the transverse direction in the lamination direction through the contact surface of the both side surfaces 422. [

The protrusion 22 of the front end plate 20 can also contribute to the improvement of the cooling function of the cell module assemblies 10 because the central region 24 does not contact the inner lower surface of the engaging groove 42.

The rear end plate 30 is for pressing the cell module assemblies 10 from behind in the laminating direction. In addition, the upper support bar (310 of FIG. 3) is installed inside the upper end of the front end plate 20 and the rear end plate 30, and is fastened and assembled using fastening means 410 such as screws or bolts Lt; / RTI > Of course, the lower support bar (311 of FIG. 3) is similarly installed inside the lower end of the front end plate 20 and the rear end plate 30, and then assembled using the fastening means.

5, the projecting portion 32 of the rear end plate 30 is bent in such a manner that the central region of the rear end plate 30 is bent so as to contact both the side surfaces 422 and the bottom surface 424 of the engagement groove portion 42, .

The projecting portion 32 of the rear end plate 30 can be fixed to the engaging groove portion 42 by an elastic force acting through the contact surfaces of the both side surfaces 422 and the lower surface 424. [

The projecting portion 32 of the rear end plate 30 can be fixed to the engaging groove portion 42 with a greater elastic force than the projecting portion 22 of the front end plate 20. [

The protrusion 32 of the rear end plate 30 is formed such that the width of the rear side of the engaging groove 42 is smaller than the entire width of the engaging groove so that the rear end plate 30 extends rearward along the engaging groove 42 It can serve as a mechanical stopper for restricting sliding.

The base plate 40 fixes each of the stacked cell module assemblies 10 downward and engages with the projections 32 of the front and rear end plates 30 to move each of the end plates 20, And has an engaging groove portion (42) for fixing.

The engaging groove portion 42 may be formed in a central region of the base plate 40 in a bent shape along the longitudinal direction.

When the cell module assemblies 10 are not fixed to the base plate 40 by the structure of the engaging grooves 42, the projections 22 and 32 of the front and rear end plates 20 and 30 are engaged with the engaging recesses 22 and 32, And can be slid along the base 42 to adjust the location of the stacked cell module assemblies 10.

2, since the width of the rear groove is smaller than the overall width of the engagement groove 42, the backward movement of the rear end plate 30 can be restricted, thereby improving the safety and efficiency of the assembly process .

Hereinafter, a method of housing a battery module assembly according to an embodiment of the present invention will be described with reference to FIG.

A method of housing a battery module is for housing a plurality of cell module assemblies. First, a front end plate 20 and a rear end plate 30 having protrusions 22 and 32 protruded downward (S62).

The protruding portions 22 of the front end plate 20 are formed so that portions of the left and right regions except for the center 24 of the lower side of the front end plate 20 are respectively bent The protruding portion 32 of the rear end plate 30 is bent so that the central region of the rear end plate 30 is bent so as to contact both the side surfaces 422 and the bottom surface 424 of the engaging groove 42, As shown in FIG.

Next, the front and rear end plates 20 and 30 are used to press the cell module assemblies 10 from the front and rear sides in the laminating direction (S63).

The base plate 40 having the engagement grooves 42 for fixing the respective end plates 20 and 30 downward is prepared (S65).

 The base plate 40 has a base plate 40 and a base plate 40. The base plate 40 has a base plate 40 and a base plate 40. The base plate 40 has a base plate 40, As shown in FIG.

The lower side surfaces of the cell module assemblies 10 supported by the pair of end plates 20 and 30 are arranged so as to be in contact with the left and right regions 44 of the base plate 40 except for the engaging grooves 42 The pair of end plates 20 (20, 32) for the base plate 40 are formed by engaging the projections 22, 32 with the engaging recesses 42 and sliding the projections 22, 32 along the engaging recesses 42 , 30) of the cell module assemblies 10 (S67).

The cell module assemblies 10 are fixed to the left and right regions 44 of the base plate 40 in contact with each other using the fastening members 14 at a position determined with respect to the base plate 40 in operation S69.

As described above, the housing structure and housing method of the battery module assembly 1 according to the embodiment of the present invention simplify the assembling process by performing the coupling by the shapes of the end plates 20 and 30 and the base plate 40 So that the manufacturing efficiency can be improved and the manufacturing cost can be reduced by reducing the number of fastening parts for fixing.

The housing structure and the housing method of the battery module assembly 1 according to the embodiment of the present invention are not limited to the structure and the method of the embodiments described above, and all or a part of the embodiments may be selectively combined .

1: Battery Module Assembly
10: Cell Module Assembly
12:
14: fastening member
20: Front end plate
22:
24: central area
30: rear end plate
32:
40: base plate
42:
422: Both sides
424: When
44: left and right area

Claims (9)

1. A housing structure of a battery module assembly for housing a plurality of cell module assemblies,
A pair of end plates for supporting the cell module assemblies from front and rear in the stacking direction, respectively, and having projections formed downward; And
And a base plate having a coupling groove portion for fixing each of the cell module assemblies supported by the pair of end plates downward and for engaging with the projecting portion of the end plate and fixing each of the end plates downwardly However,
Wherein the upper and lower ends of the pair of end plates are assembled and connected by providing a plurality of upper support bars and a plurality of lower support bars to compress and support the cell module assemblies. The method according to claim 1,
Wherein the coupling groove portion is formed in a central region of the base plate so as to be bent along the longitudinal direction,
Wherein a lower side of the stacked cell module assemblies is in contact with a left and right region of the base plate except for the engaging groove, and each of the cell module assemblies is fixed to left and right regions of the base plate by fastening members. The housing structure of the assembly. 3. The method of claim 2,
The protrusions of the front end plates for pressing the cell module assemblies from the front in the stacking direction are respectively bent and protruded from the lower ends of the front end plates so as to be in contact with both sides of the coupling recesses Lt; / RTI &
Wherein a protrusion of the rear end plate for pressing the cell module assemblies from the rear in the stacking direction is formed by bending a central region of the rear end plate so as to be in contact with both side surfaces and a lower surface of the coupling groove, The housing structure of the assembly. 3. The method of claim 2,
Wherein a width of a rear side of the engaging groove portion is smaller than an entire width of the engaging groove portion. 3. The method of claim 2,
Wherein the cell module assembly has a fixing piece formed to extend outwardly from a lower end of both side portions, and a fastening hole corresponding to the fastening member is formed on the fastening piece. A method of housing a battery module assembly for housing a plurality of cell module assemblies,
Preparing a front end plate and a rear end plate provided with protrusions protruding downward;
Pressing and supporting the cell module assemblies from the front and rear sides in the lamination direction using the front end plate and the rear end plate, respectively;
Preparing a base plate having an engaging groove for fixing each of the end plates downward;
The lower side surfaces of the cell module assemblies supported by the end plates are disposed so as to be in contact with the left and right regions of the base plate except for the engagement groove portions, the protrusion portions are coupled to the engagement groove portions, Determining the position of the cell module assemblies supported by the end plates relative to the base plate by moving the cell module assemblies; And
And fixing each of the cell module assemblies to the left and right regions of the contacted base plate using a fastening member at a determined position relative to the base plate,
The upper and lower ends of the pair of end plates may be assembled and connected by installing a plurality of upper support bars and a plurality of lower support bars to compress and support the cell module assemblies Wherein the battery module assembly is mounted on the housing. The method according to claim 6,
The protrusions of the front end plate are respectively bent and protruded in a part of the left and right regions except the center of the lower side of the front end plate so as to be in contact with both sides of the coupling groove, Wherein a protruding portion of the rear end plate for pressing against the rear end plate is formed by bending a central region of the rear end plate so as to be in contact with both side surfaces and a lower surface of the coupling groove portion. 8. The method of claim 7,
Wherein a width of a rear side of the engaging groove portion is smaller than an entire width of the engaging groove portion. 8. The method of claim 7,
Wherein the cell module assembly has a fixing piece formed to extend outwardly from a lower end of both side portions, and a fastener corresponding to the fastening member is formed on the fastening piece.

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