KR20170054755A - Submodule for high voltage battery - Google Patents

Abstract

The present invention relates to a high-voltage battery submodule capable of efficiently cooling a high-voltage battery cell. The high-voltage battery submodule comprises: a plurality of high-voltage battery cells; a plurality of fixing frames; and a cooling module. The high-voltage battery cells store power to be supplied to a high-voltage battery system and are stacked in the Y-axis direction on the XY plane, wherein an electrode tap is extended from both sides of an edge surface in the X-axis direction on the XY plane. The fixing frames are in surface contact with the high-voltage battery cells and are formed into a square ring shape to expose, to the outside, one surface and the other surface of the high-voltage battery cell in surface contact, wherein an electrode tap mounting part for mounting the electrode tap is extended at a position corresponding to the electrode tap in the X-axis direction on the XY plane. The cooling module is formed from a heat sink which is installed on the upper part of the fixing frame and cools the high-voltage battery cell; and a plurality of heat pipes which are spaced from the lower part of the heat sink in the X-axis direction on the ZX plane and are integrally formed with the heat sink. On the upper surface of the fixing frame, a pair of first fixing plates is extended in the X-axis direction on the XY plane and is spaced apart from each other in the Y-axis direction on the XY plane. On the upper surface of the fixing frame, a pair of cooling module support parts is extended to a length shorter than the length of the first fixing plate from the upper part of the fixing plate, is bent to the outside of the first fixing plate, and supports the lower surface of the heat sink in the case of mounting the cooling module.

Description

A high voltage battery sub-module (SUBMODULE FOR HIGH VOLTAGE BATTERY)

The present invention relates to a high-voltage battery sub-module, and more particularly, to a high-voltage battery sub-module capable of efficiently cooling the heat of a high-voltage battery cell.

Generally, a hybrid electric vehicle, a fuel cell vehicle, and an electric vehicle are all driven by an electric motor, and a high voltage battery that supplies driving electric power to the electric motor is essentially installed.

The high-voltage battery is configured to supply the necessary power while repeating charging and discharging while the vehicle is running.

Such a high voltage battery typically comprises a plurality of battery modules.

Each of the plurality of battery modules includes a plurality of battery submodules, and each of the plurality of submodules includes a plurality of high voltage battery cells.

A plurality of such high voltage battery cells are typically joined by an upper housing and a lower housing that support the upper and lower portions, respectively.

At this time, a plurality of high-voltage battery cells are inserted into the lower housing so as to be stacked on the mutually-facing surfaces, and the upper housing is disposed on the upper portion of the high-voltage battery cells.

The high-voltage battery cell can be manufactured in various forms. In particular, among the various types of high-voltage battery cells, a POUCHED TYPE high-voltage battery cell, which is widely used, is made of an aluminum laminate sheet having flexibility, And has a shape capable of warping.

Such pouch type high voltage battery cells are attracting much attention due to their advantages such as small weight and low manufacturing cost.

On the other hand, in order to cool the heat generated from the battery cells, a flow path groove is formed on the outer surface of the battery submodule, and these submodules are in close contact with each other to form a flow path portion.

That is, for example, a direct cooling method in which gas introduced from the outside directly contacts the surface of the battery cell to cool the heat generated from the battery cell is widely known.

But. Since the gas contacts the surface of the battery cell to cool the heat of the battery cell, the channel through which the gas flows must be ensured to be equal to or larger than a certain size between each battery cell, thereby limiting the number of cells inserted per unit volume.

In order to solve this problem, as shown in FIG. 3 of Patent Publication No. 10-01428383 (2014, 08, 01), an interfacial plate is inserted between battery cells so that heat generated from the battery cells can be discharged to the outside And a heat sink was connected to the upper surface of the interface plate.

However, in the conventional battery module as described above, the heat pipe upper heat sinks arranged at regular intervals are individually arranged so that the heat sink having the upper heavy object is instantaneously moved to one side There is a problem that the heat pipe is biased or cracked.

For the above reasons, in the related art, a battery module can be efficiently cooled and a heat sink can be firmly fixed. However, up to now, satisfactory results have not been obtained.

An object of the present invention is to provide a high voltage battery sub module that can efficiently cool a battery module and prevent a heat sink from being bent or cracked from the top of the heat pipe by vibration or shock transmitted to an outer rotor.

The high-voltage battery sub-module according to an embodiment of the present invention stores power to be supplied to the high-voltage battery system, and is stacked in the Y-axis direction on the XY plane, and the electrode tabs extend from both sides of the frame surface in the X- A plurality of extended high voltage battery cells; The battery pack according to any one of claims 1 to 3, wherein the battery pack includes a plurality of battery cells, each of the plurality of battery cells including a plurality of battery cells, A plurality of fixed frames extending in the X-axis direction on the XY plane; And a heat sink mounted on the fixed frame to cool the heat of the high voltage battery cell and a plurality of heat pipes spaced apart from each other in the X axis direction on the ZX plane in a lower portion of the heat sink and integrally formed with the heat sink A pair of first fixing plates extending in the X-axis direction on the XY plane and spaced apart from each other in the Y-axis direction on the XY plane, and a pair of second fixing plates extending from the top of the first fixing plate, A pair of cooling module support portions extending for a length shorter than the length of the first fixing plate and bent toward the outside of the first fixing plate to support the lower surface of the heat sink when the cooling module is mounted on the fixing frame, .

A cooling module mounting groove in which the cooling module is seated at a position corresponding to the heat pipe between a pair of the first fixing plates to penetrate the heat pipe is formed on the fixing frame, A pipe insertion groove into which the heat pipe penetrated from the cooling module seat groove is inserted is formed.

A mounting protrusion is formed on a lower surface of the heat sink at a position corresponding to the depth of the cooling module mounting groove and inserted into the mounting groove of the cooling module.

A bottom surface of the mounting protrusion is provided with a pipe mounting groove on which the upper portion of the heat pipe is mounted. The upper portion of the heat pipe is coupled to the pipe mounting groove by fusion bonding.

In the fusion bonding method, a solder paste is applied to an upper portion of the heat pipe, and the heat pipe and the mounting protrusion are integrally fused to each other by heating the solder paste.

A second fixing protrusion spaced apart from the mounting protrusion and spaced apart from each other in the Y-axis direction on the XY plane is formed on the bottom surface of the heat sink, and the first fixing plate is interposed between the second fixing protrusion and the mounting protrusion .

Wherein a first fastening hole is formed in the first fastening plate so as to overlap between the second fastening protrusion and the seating projection and a second fastening hole communicating with the first fastening hole and fastened to the first fastening hole is formed in the second fastening protrusion, Wherein the first fixing member fastens the first fastening hole and the second fastening hole in a horizontal direction so that the cooling module remains fixed to the fixing frame.

Wherein a pair of first fixing protrusions are formed on the upper surface of the fixed frame and arranged at both ends in the X-axis direction on the XY plane of the first fixing plate extending in the X-axis direction on the XY plane, A second fixing plate is formed at a position corresponding to the first fixing protrusion, and the first fixing protrusion and the second fixing plate are fixed by vertical fastening of the second fixing member.

The electrode tab includes a first cell extension extending in the X-axis direction from the side of the rim of the high-voltage battery cell, and a first bend extending from the first cell extension in the Y- One electrode tab; A second cell extension extending in the X-axis direction on the XY plane from a side opposite to the first electrode tab at the rim of the high-voltage battery cell, and a second cell extension extending from the second cell extension in the Y- And a second electrode tab formed of two bent portions.

The high-voltage battery sub-module according to the present invention is characterized in that a plurality of heat pipes are mounted on one heat sink so that the heat sink is integrally coupled to the upper end of the heat pipe due to momentary inertia in the case of external vibration or impact, So that the heat pipe can be prevented from being bent or cracked.

By directly exposing the high voltage battery cell to the cooling module, the heat generated from the high voltage battery cell can be cooled more efficiently.

The first electrode tab and the second electrode tab are arranged in such a manner as to enclose a pair of first bent portions and second bent portions which are in mutual contact with the outer side surface of the electrode tab seating portion so that the first electrode tab and the second electrode tab are not bent or broken by an external force The first electrode tab and the second electrode tab can be firmly supported.

The heat sink and the heat pipe can be firmly coupled by applying the solder paste to the upper end of the sink pipe which is coupled to the connection protrusion of the sink heat by the fusion splicing manner and the heat pipe can be firmly coupled with the heat sink, Is prevented.

1 is a perspective view of a high-voltage battery sub-module according to an embodiment of the present invention;
FIG. 2 is an exploded perspective view of the high-voltage battery cell and the cooling module of the high-voltage battery sub-module shown in FIG. 1; FIG.
3 is a cross-sectional view taken along line A-A 'shown in Fig.
4 is a cross-sectional view taken along line B-B 'shown in FIG. 2;
FIG. 5 is a flowchart showing a procedure of combining high-voltage battery sub-modules according to an embodiment of the present invention; FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. And is provided to fully convey the scope of the invention to those skilled in the art, and the present invention is defined by the claims. It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. It is noted that " comprises, " or "comprising," as used herein, means the presence or absence of one or more other components, steps, operations, and / Do not exclude the addition.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In order to facilitate understanding of the present invention, the high-voltage battery sub-module according to an embodiment of the present invention will be described as being stacked in the horizontal direction.

FIG. 1 is a perspective view of a high-voltage battery sub-module according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the high-voltage battery sub- 2 ', and FIG. 4 is a cross-sectional view taken along the line B-B' shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In order to facilitate understanding of the present embodiment, the high-voltage battery sub-module according to an embodiment of the present invention will be described as being stacked in the horizontal direction.

1 to 4, the high voltage battery sub module according to the present embodiment includes a high voltage battery cell 100, a fixed frame 200, and a cooling module 300.

The high-voltage battery cell 100 stores power to be supplied to the high-voltage battery system, and a plurality of the high-voltage battery cells 100 are stacked in the Y-axis direction on the XY plane as shown in FIG.

A plurality of high voltage battery cells 100 are assembled into a battery submodule and can be manufactured in various shapes. In the embodiment of the present invention, the high voltage battery cells 100 are preferably pouch-shaped.

The pouch type is mainly used for a battery for a vehicle in which a shape of the pouch type can relatively freely be formed and the weight thereof is light and a large number of high voltage battery cells 100 are to be constructed.

The high-voltage battery cell 100 is formed in a pouch shape, thereby reducing the weight of the battery submodule.

The high-voltage battery cell 100 has electrode tabs 110 formed at both ends thereof, each having a positive terminal and a negative terminal.

The electrode tab 110 is formed of a negative electrode terminal and a positive electrode terminal and extends in the Y-axis direction on the XY plane from both sides of the rim of the high-voltage battery cell 100 as shown in FIG.

The electrode tab 110 is provided as a first electrode tab 111 and a second electrode tab 114.

The first electrode tab 111 extends in the X-axis direction on the XY plane from the side of one side of the rim of the high-voltage battery cell 100 as shown in Fig.

The first electrode tab 111 includes a first cell extension 112 extending in the X-axis direction from the side surface of the high voltage battery cell 100 and a second cell extension 112 extending from the first cell extension 112 in the XY plane And a first bent portion 113 bent in the axial direction is formed.

That is, the first electrode tab 111 has a rectangular cross-sectional shape.

The high-voltage battery cell 100 disposed at the outermost one of the plurality of high-voltage battery cells 100 laminated to be in mutual contact with each other, that is, the high-voltage battery cell 100 disposed at the outermost one of the one- The first electrode tab 111 is formed in a linear shape having a cross-sectional shape extending in the horizontal direction.

The first electrode tab 111 formed in a linear shape is electrically connected to the bus bar.

The first electrode tab 111 having a rectangular cross section is formed in the high voltage battery cell 100, that is, the second high voltage battery cell 100, which is in surface contact with the high voltage battery cell 100 at the outermost one end.

The first electrode tab 111 formed on the second high voltage battery cell 100 is bent in a direction perpendicular to the first cell extension 112 of the first bent portion 113.

The high voltage battery cell 100 in the second high voltage battery cell 100, which is in surface contact with the opposite surface of the first high voltage battery cell 100, that is, the first high voltage battery cell 100 formed in the third high voltage battery cell 100, The first bent portion 113 of the tab 111 is bent in a direction perpendicular to the first cell extension portion 112. [

Accordingly, the first bending portion 113 formed in the second high-voltage battery cell 100 and the first bending portion 113 formed in the third high-voltage battery cell 100 are overlapped with each other.

Thus, the first bending portion 113 formed in the second high-voltage battery cell 100 and the first bending portion 113 formed in the third high-voltage battery cell 100 are electrically connected to each other.

In this manner, the even-numbered high-voltage battery cells 100 and the odd-numbered high-voltage battery cells 100 arranged close to each other in the high-voltage battery cells 100 are repeatedly stacked in mutual contact with each other, The first bent portions 113 are in electrical contact with each other.

The second electrode tab 114 extends in the X-axis direction on the XY plane as shown in FIG. 2 from the opposite side of the side of the rim of the high voltage battery cell 100 where the first electrode tab 111 is formed .

The second electrode tab 114 includes a second cell extension 115 extending from the side surface of the high voltage battery cell 100 in the X-axis direction on the XY plane and a second cell extension 115 extending from the second cell extension 115 on the XY plane Y And a second bent portion 116 that is bent in the axial direction is formed.

That is, the second electrode tab 114 has a rectangular cross-sectional shape like the first electrode tab 111.

The second electrode tab 114 having a rectangular cross-sectional shape is formed in the high voltage battery cell 100 at the outermost one end, that is, the first high voltage battery cell 100 in the one end direction.

The second electrode tab 114 formed on the first high voltage battery cell 100 is bent in a direction perpendicular to the second cell extension 115 of the second bent portion 116.

The second bending portion 116 of the second electrode tab 114 formed in the second high voltage battery cell 100 is connected to the first high voltage battery cell 100 in the surface contact with the first high voltage battery cell 100, Cell extension portion 115 in the direction of the first high-voltage battery cell 100.

Accordingly, the second bending portion 116 formed in the first high-voltage battery cell 100 and the second bending portion 116 formed in the second high-voltage battery cell 100 are overlapped with each other.

The second bend 116 formed in the first high voltage battery cell 100 and the second bend portion 116 formed in the second high voltage battery cell 100 are electrically connected to each other.

In this manner, the odd-numbered high-voltage battery cells 100 and the even-numbered high-voltage battery cells 100 arranged close to each other in the high-voltage battery cell 100 are repeatedly stacked in mutual contact with each other, And the second bent portions 116 are electrically connected to each other.

As a result, the first electrode tab 111 and the second electrode tab 114 are stacked in a zigzag shape on the XY plane as shown in FIG.

The fixed frame 200 is formed of an insulating material such as plastic, and can electrically insulate the electricity between the high-voltage battery cells 100, and can improve weight and durability due to the characteristics of the material.

The stationary frame 200 is formed in a rectangular ring shape so that the one surface and the other surface of the high voltage battery cell 100 in surface contact with the high voltage battery cell 100 are exposed to the outside.

The fixed frame 200 is formed in a rectangular ring shape and is directly exposed to the cooling module 300 for cooling the high voltage battery cell 100 by exposing the surface of the adjacent high voltage battery cell 100 to the outside.

Thus, the fixed frame 200 directly exposes the high voltage battery cell 100 to the cooling module 300, so that the heat generated from the high voltage battery cell 100 can be cooled more efficiently than in the prior art.

A plurality of fixed frames 200 are provided between the even-numbered high-voltage battery cell 100 and the odd-numbered high-voltage battery cell 100, respectively.

The fixing frame 200 includes an electrode tab seating portion 210, a first fixing plate 220, a cooling module supporting portion 230, a cooling module seating groove 240, a pipe insertion groove 250, And includes a first fixing protrusion 260.

The electrode tab seating portion 210 protrudes in the X axis direction on the XY plane as shown in FIG. 2 from the edge surface of the fixed frame 200 corresponding to the first electrode tab 111 and the second electrode tab 114 do.

The electrode tab seating portion 210 seats the first electrode tab 111 and the second electrode tab 114 to expose the first bending portion 113 and the second bending portion 116 to the outside.

The outer surface of the electrode tab seating portion 210 is disposed in such a shape as to enclose a pair of first bent portions 113 and second bent portions 116 which are in mutual contact with each other.

Therefore, the electrode tab seating portion 210 is formed with the first electrode tab 111 and the second electrode tab 114 so that the first electrode tab 111 and the second electrode tab 114 are not bent or damaged by an external force, It can be firmly supported.

The first fixing plate 220 protrudes upward from the upper surface of the fixed frame 200 and is formed as a pair and is spaced apart from each other in the Y axis direction on the XY plane and extends in the X axis direction on the XY plane.

Meanwhile, the first fastening hole 221 through which the first fastening member 400 is fastened is passed through the first fastening plate 220.

That is, the first fixing member 400 passing through the cooling module 300 is fixed to the first fixing plate 220 so that the cooling module 300 can be held in the fixed frame 200, The cooling module 300 can be easily fixed to the stationary frame 200 by being fastened to the stationary frame 221.

The cooling module support part 230 supports the cooling module 300 by contacting the upper surface of the fixing frame 200 with the lower surface of the cooling module 300 when the cooling module 300 is mounted on the fixing frame 200, The first fixing plate 220 and the second fixing plate 220 are respectively extended to a length shorter than the length of the first fixing plate 220 and bent outwardly of the first fixing plate 220.

The cooling module support portion 230 can firmly support the load of the cooling module 300 when the cooling module 300 is mounted on the fixed frame 200. [

The cooling module seating grooves 240 are formed in the upper frame of the stationary frame 200 and are formed between a pair of first stationary plates 220 spaced apart from each other.

The cooling module mounting grooves 240 are preferably formed in a rectangular shape and are formed with a plurality of spaced apart from one another along the X axis direction on the XY plane on the upper surface of the fixed frame 200.

Thus, the cooling module seating groove 240 can easily mount the cooling module 300 mounted on the stationary frame 200.

The cooling module seating groove 240 can easily penetrate the heat pipe 320 of the cooling module 300 to be described later when the cooling module 300 is mounted on the stationary frame 200.

The pipe insertion grooves 250 are formed on the inner surface of the lower frame of the fixed frame 200 and are formed in the same number as the cooling module seating grooves 240.

Therefore, when the cooling module 300 is mounted on the stationary frame 200, the heat pipe 320 penetrating through the cooling module seating groove 240 can be easily inserted.

The size of the pipe insertion groove 250 is preferably the same as the cross-sectional area of the heat pipe 320 of the cooling module 300.

This prevents the heat pipe 320 inserted into the pipe insertion groove 250 from being shaken by external vibration.

The first fixing protrusions 260 protrude upward from the upper surface of the stationary frame 200 and are formed as a pair and extend in the XY plane on the XY plane of the first fixing plate 220 extending in the X- And is disposed at both ends in the axial direction.

The cooling module 300 is mounted on the upper portion of the stationary frame 200 to discharge heat generated from the high-voltage battery cell 100 to the outside to cool the high-voltage battery cell 100.

The cooling module 300 includes a heat sink 310 and a heat pipe 320.

The heat sink 310 is formed by stacking a plurality of heat radiation fins 311 and is mounted between the first fixing protrusions 260 at the upper portion of the fixing frame 200.

On the other hand, the radiating fins 311 forming the heat sink 310 are stacked in a state of being spaced apart from each other in the X axis direction on the ZX plane as shown in FIG.

Accordingly, a gap is formed in the X-axis direction on the XY plane of the heat radiating fin 311, and an external gas flows through the gap, so that a wider area in the high voltage battery cell 100 can be cooled.

That is, the heat sink 310 can efficiently cool the high-voltage battery cell 100.

The heat sink 310 includes a second fixing protrusion 312, a seating protrusion 314, and a second fixing plate 317.

The second fixing protrusions 312 protrude downward from the lower surface of the heat sink 310 and are spaced from each other in the Y-axis direction on the XY plane.

A first fixing plate 220 is disposed between mutually spaced second fixing protrusions 312.

The second fixing protrusion 312 is communicated with the first fixing hole 221 and penetrates the second fixing hole 313 through which the first fixing member 400 passes.

That is, the mutually spaced apart second fixing protrusions 312 are formed in such a manner that the first fixing member 400 penetrates through the second fixing holes 313 so that the first fixing holes 221 and the second fixing holes 313 extend in the horizontal direction Tightening.

The first fastening hole 221 and the second fastening hole 313 and the first fastening member 400 are fastened by a screw fastening method so that the first fastening member 400 is fastened to the first fastening hole 221 and the second fastening hole 400. [ And is preferably fastened to the fastening hole 313.

Thus, the second fixing protrusion 312 can easily hold the cooling module 300 mounted on the upper portion of the fixing frame 200 in a fixed state on the fixing frame 200.

The seating protrusion 314 is inserted into the cooling module seating groove 240 when the cooling module 300 is mounted on the fixed frame 200 and has the same depth and the same position at the position corresponding to the cooling module seating groove 240 And protrudes from the lower surface of the heat sink 310 in a lengthwise direction.

Thus, the mounting protrusion 314 can be easily inserted into the cooling module seating groove 240.

On the other hand, the seating projections 314 are disposed between a pair of second fixing projections 312 spaced in the Y-axis direction on the XY plane.

The width of the seating protrusion 314 is formed to be narrower than the Y-axis direction spacing distance of the second fixing protrusion 312 on the XY plane.

A plate mounting groove 315 is formed between the mounting protrusion 314 and the second fixing protrusion 312 so that the first fixing plate 220 is inserted into the plate mounting groove 315.

The first fixing member 400 penetrating the first fixing hole 221 of the second fixing protrusion 312 is easily fastened to the first fixing plate 220 inserted into the plate mounting groove 315 .

The second fixing plate 317 protrudes from the side surface of the heat sink 310 in the X-axis direction on the ZX plane as shown in FIG. 4, and contacts the upper surface of the first fixing protrusion 260 on the lower surface.

The second fixing plate 317 is fastened with the first fixing protrusion 260 and the second fixing member 500 in a screwed manner when the cooling module 300 is mounted on the fixing frame 200 .

At this time, the second fixing member 500 is mutually fixed by vertically tightening the second fixing plate 317 and the first fixing protrusion 260.

The second fixing plate 317 of the cooling module 300 and the first fixing protrusions 260 of the fixing frame 200 are mutually fixed to each other even if vibration or impact is transmitted from the outside to the cooling module 300. [ The cooling module 300 can be firmly fixed to the stationary frame 200 by being fixed via the member 500. [

The heat pipe 320 is formed in a square shape in cross section, and a plurality of tubes extending in the Z-axis direction on the ZX plane shown in FIG. 4 are stacked one on the other in the X-axis direction on the ZX plane.

A plurality of heat pipes 320 are formed in a lower portion of the heat sink 310 in the X-axis direction on the XY plane as shown in FIG.

More specifically, the heat pipes 320 are formed in the same number at the corresponding positions with the seating projections 314.

The upper end of the heat pipe 320 is mounted on the seating protrusion 314 so that the cooling module 300 is inserted into the pipe insertion groove 250 when the cooling module 300 is mounted on the fixed frame 200, do.

The heat pipe 320 is connected to the lower portion of the heat sink 310 and the heat generated from the battery cell through the heat pipe 320 inserted between the battery cells And cooled.

The heat pipe 320 is coupled to the mount protrusion 314 in a fusion-bonding manner.

More specifically, a pipe mounting groove 316 is formed on the lower surface of the mounting protrusion 314 so that the upper end of the heat pipe 320 can be easily inserted.

Solder paste is applied to an area of the heat pipe 320 to be inserted into the pipe mounting groove 316 and an area to which the solder paste is applied is inserted into the pipe mounting groove 316.

The heat sink 310 and the heat pipe 320 are heat-treated at a temperature at which the solder paste melts to bond the heat sink 310 and the heat pipe 320 to each other.

Accordingly, the heat sink 310 and the heat pipe 320 are formed integrally with each other via the solder paste.

Thereby, the heat pipe 320 is prevented from being detached from the mount projection 314 by external vibration.

Since the heat sink 310 and the heat pipe 320 are formed integrally with each other through the solder paste, the heat sink 310 and the heat pipe 320 do not have an interface between the heat sink 310 and the heat pipe 320, 320 is lowered.

Accordingly, the heat pipe 320 can be efficiently cooled. [0041] Meanwhile, the heat pipe 320 is preferably formed of an aluminum material having excellent heat transfer.

As a result, the heat generated from the battery cell is cooled through the heat pipe 320 inserted between the battery cells.

The heat pipes 320 are formed on the lower surface of the heat sink 310.

That is, the plurality of heat pipes 320 may be mounted on one heat sink 310 of the cooling module 300.

Accordingly, the heat sink 310, which is integrally coupled to the upper end of the heat pipe 320 due to momentary inertia when the vehicle vibrates or impacts, is biased to one side, so that the heat pipe 320 is bent or cracked .

Hereinafter, the assembling procedure of the high voltage battery sub-module according to the embodiment of the present invention will be described.

FIG. 5 is a flowchart illustrating an assembling procedure of a high-voltage battery sub-module according to an embodiment of the present invention.

The solder paste is applied to the upper end of the heat pipe 320 in step S510 and the area to which the solder paste is applied is mounted on the plate mounting groove 315 of the mount projection 314 in step S520.

The heat pipe 320 on which the solder paste is applied and the heat sink 310 on which the heat pipe 320 is mounted are melted through heat treatment to fuse the heat pipe 320 and the heat sink 310 to each other.

Here, the heat treatment temperature of the heat pipe 320 and the heat sink 310 is heat treated to a temperature at which the solder paste melts (S530) to form a cooling module.

A cooling module 300 including a heat pipe 320 and a heat sink 310 is mounted on the upper end of the fixed frame 200 (S540).

The cooling module 300 is inserted between the second fixing protrusions 312 of the cooling module 300 and the seating protrusions 314 of the cooling module 300 so that the second fixing protrusions 312 The first fixing protrusion 260 of the fixing frame 200 and the second fixing plate 317 of the cooling module 300 are fixed by the horizontal fixing of the first fixing protrusion 260 passing through the fixing frame 200, And are mutually fixed (S560) by vertical fastening of the second fixing member 500. [

Thus, the cooling module 300 mounted on the fixed frame 200 is prevented from being shaken by external vibration or being released to the outside.

Also, since the heat pipe 320 formed in the cooling module 300 passes through the stationary frame 200, the heat of the high-voltage battery cell 100, which is in surface contact with the stationary frame 200, can be easily cooled.

Then, a pair of high-voltage battery cells 100 are brought into contact with each other on both sides of the ZY plane in the Y-axis direction on the fixed frame 200 (S570).

2, the electrode tab seating portion 210 protrudes from both sides of the fixed frame 200 in the X-axis direction on the ZX plane. The electrode tab seating portion 210 protrudes from both sides of the edge surface of the high voltage battery cell 100, The first electrode tab 111 and the second electrode tab 114 are provided.

The first electrode tab 111 and the second electrode tab 114 are respectively seated on the electrode tab seating portion 210.

The first electrode tab 111 of the high voltage battery cell 100 disposed at one side of the pair of high voltage battery cells 100 disposed in the fixed frame 200 is formed in a straight line in cross section, And the first electrode tab 111 of the high voltage battery cell 100 disposed on the other side is formed in a right angle.

The second electrode tabs 114 of the pair of high voltage battery cells 100 disposed in the fixed frame 200 are formed in a rectangular shape and the second bent tabs 116 of the second electrode tabs 114 are connected to the second electrode tabs 114, Are in contact with each other.

Accordingly, the first electrode tab 111 and the second electrode tab 114 are connected to each other in a planar zigzag shape.

As described above, in the high-voltage battery sub-module according to the present invention, a plurality of heat pipes 320 are mounted on one heat sink 310, It is possible to prevent the heat pipe 310, which is integrally bonded to the upper portion thereof, from being biased to one side, so that the heat pipe 320 is not bent or cracked.

By directly exposing the high voltage battery cell 100 to the cooling module 300, the heat generated from the high voltage battery cell 100 can be more efficiently cooled.

The electrode tab seating portion 210 is disposed so as to surround the pair of first bent portions 113 and the second bent portions 116 which are in contact with the outer surface of the electrode tab seating portion 210, The first electrode tab 111 and the second electrode tab 114 can be firmly supported to prevent the first electrode tab 111 and the second electrode tab 114 from being bent or damaged by an external force.

The heat sink 310 and the heat pipe 320 are firmly coupled to each other by applying a solder paste to the upper end of the heat pipe 320 coupled to the connection protrusion of the heat sink 310 in a fusion- And the heat pipe 320 is prevented from being detached from the seat cushion 314 due to external vibration.

The present invention is not limited to the above-described embodiments, and various modifications may be made within the scope of the technical idea of the present invention.

100: high-voltage battery cell 110: electrode tab
111: first electrode tab 112: first cell extension
113: first bent portion 114: second electrode tab
115: second cell extension part 116: second bent part
200: stationary frame 210: electrode tab seat part
220: first fixing plate 221: first fastening hole
230: cooling module support part 240: cooling module seat groove
250: pipe insertion groove 260: first fixing projection
300: cooling module 310: heat sink
311: radiating fin 312: second fixing projection
313: second fastening hole 314:
315: plate mounting groove 316: pipe mounting groove
317: second fixing plate 320: heat pipe
400: first fixing member 500: second fixing member

Claims (9)

In a high voltage battery sub-module installed in a high voltage battery system,
A plurality of high voltage battery cells that store power to be supplied to the high voltage battery system and are laminated in a Y axis direction on an XY plane and electrode tabs extend from both sides of a rim surface in an X axis direction on an XY plane;
The battery pack according to any one of claims 1 to 3, wherein the battery pack includes a plurality of battery cells, each of the plurality of battery cells including a plurality of battery cells, A plurality of fixed frames extending in the X-axis direction on the XY plane; And
A heat sink mounted on the fixed frame to cool the heat generated by the high voltage battery cell and a plurality of heat pipes spaced apart from each other in the X axis direction on the ZX plane in a lower portion of the heat sink, Module,
On the upper surface of the fixed frame,
A pair of first fixing plates extending in the X-axis direction on the XY plane and spaced apart from each other in the Y-axis direction on the XY plane, and a pair of second fixing plates extending in a length shorter than the length of the first fixing plate, A pair of cooling module support portions that are respectively bent outwardly of the fixing plate and support the lower surface of the heat sink when the cooling module is mounted on the fixing frame
In high voltage battery submodule.
The method according to claim 1,
A cooling module mounting groove in which the cooling module is seated at a position corresponding to the heat pipe between a pair of the first fixing plates to penetrate the heat pipe is formed on the fixing frame, A pipe insertion groove into which the heat pipe penetrated from the cooling module seating groove is inserted
In high voltage battery submodule.
3. The method of claim 2,
Wherein a bottom surface of the heat sink is formed with a length corresponding to a depth of the cooling module mounting groove at a position corresponding to the mounting groove of the cooling module and is inserted into the mounting groove of the cooling module
In high voltage battery submodule.
The method of claim 3,
A pipe mounting groove for mounting an upper portion of the heat pipe is formed on a lower surface of the mounting projection,
And the upper portion of the heat pipe is coupled to the pipe mounting groove by fusion bonding
In high voltage battery submodule.
[5] The method of claim 4,
A solder paste is applied to an upper portion of the heat pipe and the heat pipe and the mounting protrusion are integrally fused to each other by heating the solder paste
In high voltage battery submodule.
The method of claim 3,
A second fixing protrusion that is spaced apart from the mounting protrusion in the outward direction and spaced apart from each other in the Y axis direction on the XY plane is formed on the bottom surface of the heat sink,
And the first fixing plate is inserted between the second fixing projection and the mounting projection
In high voltage battery submodule.
The method according to claim 6,
A first fastening hole is formed in the first fastening plate so that the first fastening hole overlaps between the second fastening protrusion and the fastening protrusion,
And a second fastening hole communicating with the first fastening hole and fastened to the first fastening member for fastening the fastening frame to the cooling module is passed through the second fastening protrusion,
Wherein the first fixing member fastens the first fastening hole and the second fastening hole in a horizontal direction so that the cooling module remains fixed to the fixed frame
In high voltage battery submodule.
The apparatus according to claim 1, wherein, on an upper surface of the fixed frame,
A pair of first fixing protrusions arranged at both ends in the X-axis direction on the XY plane of the first fixing plate extending in the X-axis direction on the XY plane are formed,
A second fixing plate is formed at a position corresponding to the first fixing projection in the heat sink,
Wherein the first fixing projection and the second fixing plate are fixed by vertical fastening of the second fixing member
In high voltage battery submodule.
The electrode assembly according to claim 1,
A first electrode tab extending from an edge of the high voltage battery cell in the X axis direction on the XY plane and a first electrode tab formed by a first bent portion bent in the Y axis direction on the XY plane from the first cell extension portion; And
A second cell extension extending in the X-axis direction on the XY plane from the side opposite to the first electrode tab at the rim of the high voltage battery cell; and a second cell extension extending from the second cell extension in the Y- And a second electrode tab formed as a bent portion
In high voltage battery submodule.

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