KR101929988B1 - Heat exchanger for battery cooling - Google Patents

Abstract

The present invention relates to a heat exchanger for cooling a battery. A pair of flat tube type cooling tubes is provided between the first header pipe and the second header pipe. An auxiliary cooling tube is interposed between the cooling tubes. The entire parts of the first and second header pipes, the first and second inlet pipes, the first and second outlet pipes, the baffle, the cooling tube and the auxiliary cooling tube are integrally fabricated through brazing. So, the fabrication of the heat exchanger can be facilitated. At the same time, the outer surface of the cooling tube through which a fluid for cooling is circulated and the one surface of the battery are directly in close contact with each other. So, the cooling efficiency of the battery can be remarkably increased. In addition, it is possible to expand the close contact area with the battery for cooling by putting the auxiliary cooling tube between the cooling tubes, thereby further improving the cooling efficiency of the battery.

Description

[0001] Heat exchanger for battery cooling [

The present invention relates to a battery-cooling heat exchanger, and more particularly, to a heat exchanger for cooling a battery, and more particularly, to a heat exchanger for battery cooling, 1, the second header pipe, the first and second inlet pipes, the first and second outlet pipes, the baffle, the cooling tube, and the auxiliary cooling tube are integrally fabricated through brazing to facilitate the manufacture of the heat exchanger The outer surface of the cooling tube through which the fluid for cooling is circulated and the one surface of the battery are directly brought into close contact with each other. Thus, the cooling efficiency of the battery can be remarkably increased. In addition, And more particularly to a heat exchanger for battery cooling which can further improve the cooling efficiency of the battery.

With the advent of modern society, interest in environmental vehicles using electricity has increased due to environmental problems and high oil prices. Such environment vehicles have been developed as electronic vehicles and hybrid electric vehicles, for example, and commercialized In fact.

[0003] Electric vehicles and hybrid electric vehicles (hereinafter, referred to as electric vehicles) are usually manufactured from a plurality of lithium-ion cells and rechargeable high-voltage batteries are applied.

Such a high voltage battery is one of the key components of an electric vehicle, and generates heat at a high temperature during charging and discharging, which is a key factor that has a considerable influence on the performance and efficiency of a battery.

Accordingly, in most electric vehicles, a cooling system is provided in the battery pack, and the heat of the battery is managed by the forced air-cooling system through the cooling system.

That is, the air inside the vehicle flows into the duct through the blower motor and passes through the inside of the battery pack, thereby cooling the heat of the battery pack.

However, the cooling system using the blower motor as described above has a problem in that it has a limitation in increasing the air volume due to a structural limitation in the capacity increase as well as a large volume next to the battery in the high voltage battery electric equipment.

In addition, there is a limit in that the temperature of the cooling air can not be adjusted to the optimum temperature by cooling the air in the vehicle interior, and if dust or water flows into the duct from the inside of the vehicle, There was also a fatal problem.

On the other hand, during driving of the vehicle, heat generation due to the discharge of the battery is not significant, and running wind is generated according to the running speed of the vehicle, so that the heat of the battery can be cooled only by the running wind. Therefore, the necessity of a cooling system is reduced during traveling.

However, a system capable of cooling the heat of the battery is essential because the amount of heat generated by the battery is large at the time of charging the vehicle (particularly, rapid charging), and the running wind is not generated when the vehicle is stopped.

Accordingly, there is a problem in that the electric vehicle is required to be provided with a battery cooling system in order to prepare for the heat generation such as when the vehicle is charged, despite the problem of the cooling system.

In order to solve the above-described problems, a heat exchanger for a battery according to the circulation of the cooling fluid has been developed and used.

The conventional heat exchanger for a battery includes a heat exchange pipe in which a fluid for cooling flows in and out so as to circulate through the inner space and is bent several times in a refraction type and an insertion groove is formed in a bottom surface so that the upper outer surface of the heat exchange pipe is closely contacted. And a lower plate which is opposed to the upper plate and which is assembled through a coupling member and in which an insertion groove is formed on the upper surface so that the lower outer surface of the heat exchange pipe is closely contacted.

According to the heat exchanger of the present invention comprising the heat exchanger pipe and the upper and the lower plates, the cooling of the battery, which is in close contact with the upper plate or the lower plate through the upper plate and the lower plate from the heat exchange pipe, Can be made more efficiently.

However, in the battery heat exchanger according to the related art as described above, after the upper plate, the lower plate and the heat exchange pipe are processed, the heat exchange pipe is interposed between the upper plate and the lower plate, There is a problem that the manufacturing process is complicated.

In addition, there is a problem that the cooling efficiency of the battery is deteriorated because heat is exchanged from the fluid for cooling circulated inside the heat exchange pipe through the upper plate or the lower plate from the battery side.

Therefore, there is a need for research and development of a battery-cooling heat exchanger which is easy to manufacture, and in which a battery is directly brought into close contact with an outer surface of a member through which a fluid circulates for cooling, thereby remarkably increasing the cooling efficiency of the battery.

Korea Public Utility Model No. 2013-0002117 Issue 2013.04.03.

In order to solve the above-mentioned problems, the present invention is characterized in that a pair of flat tube type cooling tubes are provided between the first header pipe and the second header pipe, an auxiliary cooling tube is interposed between the cooling tubes, The entire components of the two header pipes, the first and second inlet pipes, the first and second outlet pipes, the baffle, the cooling tube and the auxiliary cooling tube are integrally manufactured through the brazing to facilitate the manufacture of the heat exchanger, And an object of the present invention is to provide a battery cooling heat exchanger in which the outer surface of a cooling tube through which a fluid for cooling circulates and one surface of the battery are directly brought into close contact with each other,

Another object of the present invention is to provide a cooling system for a refrigerator which comprises a pair of flat tube type cooling tubes between a first header pipe and a second header pipe, So that the cooling efficiency of the battery can be further improved.

The present invention for achieving the above-mentioned objects is as follows. That is, the battery-cooling heat exchanger according to the present invention is a battery-cooling heat exchanger which is in close contact with one surface of a battery of an electric vehicle to cool the battery. The heat exchanger has a cross- The first and second inflow holes are formed at predetermined distances from both sides to the center side to connect the first and second inflow pipes, and the first and second inflow pipes are formed on one surface orthogonal to the first and second inflow ports, A first header pipe through which an insertion hole of the baffle is inserted and a baffle is coupled and fixed at both ends in the longitudinal direction and at a central portion thereof and the internal space is divided by the baffle; The first and second outflow ports are formed at opposite sides of the first header pipe and spaced from each other by a predetermined distance from both sides of the square pipe, And a baffle is coupled and fixed at both ends in the longitudinal direction and at a central portion of the baffle. The baffle is connected to the first and second outflow pipes, A second header pipe in which an inner space is divided by the baffle; Wherein the first header pipe and the second header pipe are fixedly inserted into the first header pipe and the second header pipe, respectively, and the fluid introduced through the first and second inlet pipes is inserted into the first header pipe A cooling tube having a plurality of flow passages formed at predetermined intervals so as to correspond to a longitudinal direction of the insertion hole so as to be guided through the first and second outflow pipes through the inner spaces on both sides of the inner tube; And both sides of the cooling tube are in close contact with the opposing side surfaces of the cooling tube, and both longitudinal ends of the cooling tube are respectively disposed between the surfaces between the insertion holes of the first header pipe and the second And an auxiliary cooling tube spaced a distance from an insertion hole of the header pipe.

At this time, the cooling tube has a hemispherical shape on both sides in the width direction so that the conduction area for the cold air through the fluid circulation for cooling the cooling tube to the auxiliary cooling tube side is expanded, while the auxiliary cooling tube has the cooling And a hemispherical groove corresponding to the tube is formed to be recessed.

Moreover, the first header pipe, the first inlet pipe, the second inlet pipe, the second header pipe, the first outlet pipe, the second outlet pipe, the baffle, the cooling tube and the auxiliary cooling tube are tightly fixed to each other via brazing It is preferable that they are integrally manufactured.

Further, it is preferable that the cooling tube and the auxiliary cooling tube are made of aluminum and are manufactured by extrusion molding.

In addition, the auxiliary cooling tube may be provided in a hollow tube shape, and one side orthogonal to the side of the cooling tube which is in close contact with the opposing side surface may be opened.

At this time, it is preferable that the auxiliary cooling tube is provided in the shape of a hollow tube, and one side orthogonal to the side which is in close contact with the opposite side of the cooling tube is opened and a reinforcing rib protruding in the widthwise center is further formed.

The effect of the battery-cooling heat exchanger according to the present invention is as follows.

First, a pair of flat tube type cooling tubes are provided between the first header pipe and the second header pipe, an auxiliary cooling tube is interposed between the cooling tubes, and the first and second header pipes, the first and second inflow pipes The entire part of the pipe, the first and second outlet pipes, the baffle, the cooling tube and the auxiliary cooling tube are integrally manufactured through the brazing, thereby facilitating the manufacture of the heat exchanger, The outer surface and one side of the battery are directly brought into close contact with each other, so that the cooling efficiency of the battery can be remarkably increased.

Second, a pair of flat tube type cooling tubes are provided between the first header pipe and the second header pipe, and an auxiliary cooling tube is interposed between the cooling tubes to expand the close contact area with the battery for cooling, The efficiency can be further improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a heat exchanger for cooling a battery according to the present invention. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchanger for cooling a battery.
3 is a cross-sectional view taken along the line AA of Fig.
4 is a cross-sectional view taken along the line BB of Fig.
5 is a view illustrating an example of a usage state of a heat exchanger for cooling a battery according to the present invention.
FIGS. 6 and 7 are views showing other embodiments of a recessed auxiliary cooling tube in a heat exchanger for battery cooling according to the present invention; FIG.

Hereinafter, preferred embodiments of the battery-cooling heat exchanger according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a heat exchanger for cooling a battery according to the present invention, and FIG. 2 is a perspective view illustrating a heat exchanger for cooling a battery according to the present invention.

Fig. 3 is a cross-sectional view taken along the line A-A in Fig. 2, and Fig. 4 is a cross-sectional view taken along the line B-B in Fig.

5 is a view illustrating a state of use of the battery-cooling heat exchanger according to the present invention.

As shown in FIGS. 1 to 5, a battery-cooling heat exchanger according to a preferred embodiment of the present invention is closely attached to one surface of a battery B of an electric vehicle to cool the battery. 100, a second header pipe 200, cooling tubes 410, 420, and an auxiliary cooling tube 500.

Specifically, the first header pipe 100 has a rectangular cross-section having a predetermined length and overlapped to form a first and a second inflow hole 110 and 120 at a predetermined distance from both sides of the square pipe. So that the first and second inlet pipes 110 'and 120' are connected.

The first header pipe 100 may be formed in such a manner that a long hole type insertion hole 130 is formed at a predetermined interval on one side of the first header pipe 100, which is perpendicular to the first and second inlet ports 110 and 120, And a baffle 310 is coupled and fixed at both ends in the longitudinal direction and at a central portion so that the internal space is divided and formed by the baffle 310.

In other words, the first header pipe 100 is formed with a coupling hole (not shown) at both ends and a central portion for coupling and fixing the baffle 310, and the baffle 310 is connected through the coupling hole It is preferable to fix them together.

Meanwhile, the second header pipe 200 is disposed opposite to the first header pipe 100 at a predetermined interval, and has a rectangular cross-section having a predetermined length overlapping with the first header pipe 200, The first and second outlets 210 and 220 are formed at predetermined distances to connect the first and second outflow pipes 210 'and 220'.

The second header pipe 200 has a long hole type insertion hole 230 formed at a predetermined distance on one side of the second header pipe 200 which is perpendicular to the first and second outlets 210 and 220, The baffle 320 is coupled and fixed to the both ends in the longitudinal direction and the central portion, and the internal space is divided and formed by the baffle 320.

In other words, the second header pipe 200 is formed with a coupling hole (not shown) at both ends and a central portion for coupling and fixing the baffle 320, and the baffle 320 is coupled It is preferable to fix it.

The cooling tubes 410 and 420 are provided in pairs so that both ends of the cooling tubes 410 and 420 are connected to the first header pipe 100 and the second header pipe 200 through the insertion hole 130 of the first header pipe 100 and the insertion hole 230 of the second header pipe 200, Insert the length will be fixed.

The cooling tubes 410 and 420 may be configured such that the fluid flowing through the first and second inlet pipes 110 'and 120' flows through the inner spaces on both sides of the first header pipe 100, It is preferable that a flat tube type in which a plurality of flow passages are formed at predetermined intervals corresponding to the longitudinal direction of the insertion holes 130 and 230 so as to be guided through the second outflow pipes 210 'and 220' .

The auxiliary cooling tubes 500 are disposed between the opposing sides of the cooling tubes 410 and 420 provided in a pair so that both sides of the auxiliary tubes 500 are in close contact with the opposing side surfaces of the cooling tubes 410 and 420, Both ends of the first header pipe 100 are separated from the surface between the insertion holes 130 of the first header pipe 100 and the insertion hole 230 of the second header pipe 200 by a predetermined distance.

That is, by applying the auxiliary cooling tube 500 as described above, the gap GAP generated between the pair of the cooling tubes 410 and 420 is filled up, (GAP) without any gap.

In other words, by applying the auxiliary cooling tube 500, the gap GAP generated between the facing surfaces of the cooling tubes 410 and 420 is filled, and the gap GAP when the electric vehicle is in close contact with the one surface of the battery B So that the close contact area with the battery B for cooling can be extended to further improve the cooling efficiency of the battery B.

In the meantime, the battery-cooling heat exchanger according to the present invention having the above-described structure is arranged so that the conduction area for cool air through the fluid circulation for cooling the cooling tubes 410 and 420 is extended toward the auxiliary cooling tube 500 It is important to do.

The cooling tubes 410 and 420 have hemispherical shapes on both sides in the width direction while the auxiliary cooling tubes 500 are formed on both sides of the cooling tubes 410 and 420 to form hemispherical grooves .

In other words, the cooling tubes 410 and 420 having both hemispherical shapes on both sides in the width direction and the auxiliary cooling tubes 500 having hemispherical grooves corresponding to the cooling tubes 410 and 420 on both sides are formed The conduction efficiency to the cold air through the fluid circulation for cooling the cooling tubes 410 and 420 to the auxiliary cooling tube 500 side can be further improved.

In addition, the auxiliary cooling tube 500 is provided on both sides with a hemispherical groove corresponding to the cooling tubes 410 and 420, and is provided in a hollow tube shape.

Furthermore, the cooling tubes 410 and 420 and the auxiliary cooling tube 500 in the heat exchanger for battery cooling according to the present invention as described above are preferably made of aluminum and are preferably manufactured by extrusion molding.

FIGS. 6 and 7 are views showing other embodiments of the recessed auxiliary cooling tube in the heat exchanger for battery cooling according to the present invention. FIG.

Referring to FIG. 6, the auxiliary cooling tube 500, which is a major part of the heat exchanger for battery cooling according to the present invention, is provided in a hollow tube shape, Which is orthogonal to the side on which the side is formed.

That is, the auxiliary cooling tube 500 provided with the above-described structure can be assembled in the form of a clip between the opposing sides of the cooling tubes 410 and 420, and is easy to assemble. Of course, after assembling the auxiliary cooling tube 500 Are preferably mutually fixed via a brazing process.

7, an auxiliary cooling tube 500, which is a substantial part of the heat exchanger for battery cooling according to the present invention, is provided in the shape of a hollow tube and is in close contact with the opposing side surface of the cooling tubes 410 and 420 And a reinforcing rib 510 protruding from the center in the width direction is further formed.

According to the auxiliary cooling tube 500 in which the reinforcing rib 510 is further formed, the strength of the auxiliary cooling tube 500 can be reinforced through the reinforcing rib 510, and the strength of the auxiliary cooling tube 500 can be enhanced. And the heat radiating fins radiating the heat generated from the battery B which is in close contact with the open opposite side can be also performed.

According to the battery-cooling heat exchanger of the present invention, a pair of flat tube type cooling tubes are provided between the first header pipe and the second header pipe, and an auxiliary cooling tube is interposed between the cooling tubes. And the entire parts of the first and second header pipes, the first and second inlet pipes, the first and second outlet pipes, the baffle, the cooling tube and the auxiliary cooling tube are integrally fabricated through brazing, And the outer surface of the cooling tube, through which the fluid for cooling is circulated, and one side of the battery are brought into direct contact with each other, so that the cooling efficiency of the battery can be remarkably increased.

Further, a pair of flat tube type cooling tubes are provided between the first header pipe and the second header pipe, and an auxiliary cooling tube is interposed between the cooling tubes to expand the close contact area with the battery for cooling, The efficiency can be further improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, the invention is not limited thereto. Various modifications may be made by those skilled in the art. Are included in the scope of the present invention.

100: first header pipe 110: first inlet pipe
120: second inflow hole 110 ': first inflow pipe
120 ': second inflow pipe 130: insertion hole
200: second header pipe 210: first outlet hole
220: second outflow hole 210 ': first outflow pipe
220 ': second outflow pipe 230: insertion hole
310, 320: baffle 410, 420: cooling tube
500: auxiliary cooling tube 510: reinforcing rib
B: Battery

Claims (6)

The end portions of the first and second inflow holes 110 and 110 are formed in a shape of a square pipe having a flat cross-section, The first and second inlet pipes 110 'and 120' are connected to each other and have a predetermined interval on one side of the first and second inlet pipes 110 and 120, A first header pipe 100 through which an insertion hole 130 of a long hole type is inserted and a baffle 310 is coupled and fixed at both ends in the longitudinal direction and at a central portion thereof so that the internal space is divided by the baffle 310; The first header pipe 100 and the second header pipe 100 are disposed to face each other with a predetermined distance therebetween. The ends of the first and second header pipes 100 and 210 have a rectangular cross section, The first and second outflow pipes 210 and 220 are connected to each other and have a predetermined interval on one side of the first and second outflow pipes 210 and 220, A second header pipe 200 through which a long hole type insertion hole 230 is penetrated, a baffle 320 is fixedly coupled to both ends of the longitudinal direction, and the inner space is divided by the baffle 320; And both ends of the first header pipe 100 and the second header pipe 200 are inserted and fixed by a predetermined length through the insertion hole 130 of the first header pipe 100 and the insertion hole 230 of the second header pipe 200, So that the fluid introduced through the inlet pipes 110 'and 120' is guided through the first and second outlet pipes 210 'and 220' through the internal spaces on both sides of the first header pipe 100 (410, 420) having a flat tube type in which a plurality of flow passages are formed at predetermined intervals corresponding to the longitudinal direction of the insertion holes (130, 230); And a pair of cooling tubes (410, 420) provided in a pair so that both sides thereof are in close contact with the opposing side surfaces of the cooling tubes (410, 420), respectively, And an auxiliary cooling tube (500) spaced from the surface between the insertion hole (130) of the first header pipe (100) and the insertion hole (230) of the second header pipe (200)
The cooling tubes 410 and 420 are connected to the auxiliary cooling tubes 500 so that the conduction area for the cool air through the fluid circulation for cooling the cooling tubes 410 and 420 is extended,
The cooling tubes 410 and 420 are hemispherical on both sides in the width direction,
Wherein the auxiliary cooling tubes (500) are formed on both sides of the cooling tubes (410, 420) so that hemispherical grooves are recessed.
delete The method according to claim 1,
The first header pipe 100, the first inlet pipe 110 ', the second inlet pipe 120', the second header pipe 200, the first outlet pipe 210 ', the second outlet pipe 220 ), The baffles (310, 320), the cooling tubes (410, 420) and the auxiliary cooling tubes (500) are tightly fixed to one another through brazing.
The method according to claim 1,
Characterized in that the cooling tubes (410, 420) and the auxiliary cooling tubes (500) are made of aluminum and are manufactured by extrusion molding.
The method according to claim 1,
The auxiliary cooling tube 500 is provided in the form of a hollow tube,
Wherein one side of the cooling tube (410, 420) that is orthogonal to a side of the cooling tube (410, 420) that is in close contact with the opposite side surface is opened.
6. The method of claim 5,
The auxiliary cooling tube 500 is provided in the shape of a hollow tube and is open at one side orthogonal to the side of the cooling tube 410 or 420 that is in close contact with the opposing side surface,
And a reinforcing rib (510) protruding from the center in the width direction of the heat exchanger.

Images