KR20130123013A - Cooling apparatus used in electric powered vehicle - Google Patents

Abstract

A cooling apparatus for an electric vehicle which cools down heating elements installed in the electric vehicle is disclosed. The cooling apparatus for an electric vehicle includes: a first cooling plate which comes in contact with a first heating element which is one of the heating elements; a second cooling plate which forms a flow path by being formed to face the first cooling plate and which comes in contact with a second heating element which is one of the heating elements; a middle plate which is installed between the first cooling plate and the second cooling plate and which divides the flow path into two layers; a cooling water inlet which is connected to the flow path and at which cooling water flows in; and a cooling water outlet which is connected to the flow path and at which the cooling water flows out. Therefore, many components can be cooled with a small volume.

Description

Cooling apparatus used in Electric powered vehicle}

The present invention relates to a cooling device, and more particularly to a cooling device for a power vehicle driven based on power.

An electric vehicle is a vehicle that generates and drives a direct or indirect 'high power electric power' using electricity, fuel electricity, etc., not fossil fuel, and includes a vehicle driven based on electric power.

Electric vehicles (EVs) driven by the power of batteries and electric motors, plug-in hybrid vehicles (PHEVs) that can be charged from the outside by installing electric motors and internal combustion engines in parallel, and electricity generated when driving internal combustion engines Hybrid vehicles (HEV) for storage and utilization, and fuel cell vehicles (FCEV), which are driven by producing electricity based on hydrogen and oxygen using fuel cells.

Many such heating devices include inverters that convert DC high voltages output from batteries and batteries into AC voltages, supply them to drive motors, and perform various kinds of control. Is provided. Therefore, in order for these elements to operate properly, a cooling device for cooling them is essential.

However, the conventional electric vehicle cooling device is simply attached to these heat generating elements, and has a configuration in which it cools, and thus there is a problem in that it is bulky and heavy in weight to cool many parts at once.

Embodiments of the present invention have been made to solve the above problems, and to provide a cooling device for a power vehicle is reduced in volume and light weight.

An embodiment of the present invention, in order to solve the above problems, in the power vehicle cooling apparatus for cooling the heating element installed in the power vehicle, the first cooling plate in contact with the first heating element which is one of the heating elements; A second cooling plate which is formed to face the first cooling plate to form a flow path, and is in contact with a second heating element which is one of the heating elements; An intermediate plate disposed between the first cooling plate and the second cooling plate to divide the flow path into two layers; A coolant inlet communicating with the flow path and into which coolant is introduced; And a cooling water outlet through which the cooling water flows and communicates with the flow path.

It is preferable that the surface of the at least one of the first cooling plate and the second cooling plate facing the flow path is formed to protrude a rigid increase rib, and the rigid increase rib is formed at a portion where the flow path is not formed.

At least one of the first heat generating element and the second heat generating element includes a cooling fin that is directly in contact with the flow path and is cooled, and the first cooling plate and the second cooling plate are exposed to the flow path through the cooling fin. The load through-hole is formed through at least one of the, the outer circumferential surface of the load through-hole sealing ring for sealing with the heating element having the cooling fin;

Sealing ribs which abut against each other are formed to protrude from the surfaces of the first cooling plate and the second cooling plate that face each other, and the sealing ribs are connected without a broken portion.

The first cooling plate and the second cooling plate are sealed by brazing between the sealing ribs facing each other.

The cooling water inlet is formed to be partially opened on a surface opposite to the surface facing the second cooling plate of the first cooling plate.

The cooling water inlet is preferably formed outside the edge of the intermediate plate.

It is effective that the cooling water inlet is formed with an inlet guide for guiding the cooling water toward the edge of the intermediate plate.

The cooling water outlet may be partially opened at an opposite surface on which the sealing rib of the first cooling plate is formed.

On the other hand, the cooling water inlet and the cooling water outlet is preferably arranged in a straight line.

Here, the intermediate plate height adjustment protrusion formed on the surface facing the flow path of the first cooling plate to support the intermediate plate; preferably further comprises a.

The coolant divider is formed at a position adjacent to the inlet, and divides the incoming coolant into a plane.

As described above, according to the present invention, various effects including the following can be expected. However, the present invention does not necessarily achieve the following effects.

In one embodiment of the present invention, by attaching a heat source element on both sides of the first cooling plate and the second cooling plate can be cooled, it is possible to reduce the volume of the cooling device.

In addition, by providing the intermediate plate, by dividing the cooling water into the first cooling plate and the second cooling plate, it is possible to prevent the cooling of only one of them.

And, by providing the intermediate plate height adjustment protrusion, by adjusting the position of the intermediate plate, it is possible to vary the amount of cooling water divided up and down.

In addition, by providing the coolant divider, the coolant can be divided and flow in the planar direction.

1 is an exploded perspective view of a cooling device for an electric vehicle of an embodiment of the present invention;
2 is a perspective view of a state in which the cooling apparatus for the power vehicle of FIG. 1 is coupled;
3 is a cross-sectional view taken along the line III-III in Fig. 2
4 is a bottom perspective view of the first cooling plate of FIG. 1;

As described in the prior art, an electric vehicle is a vehicle that generates and drives a direct or indirect 'high power electric power' by using electricity, fuel electricity, etc., not fossil fuel. The concept to include.

Electric vehicles (EVs) driven by the power of batteries and electric motors, plug-in hybrid vehicles (PHEVs) that can be charged from the outside by installing electric motors and internal combustion engines in parallel, and electricity generated when driving internal combustion engines Hybrid vehicles (HEV) used for storage and fuel cell vehicles (FCEV), which are driven by producing electricity on a hydrogen and oxygen basis using fuel cells. Vehicles of the type.

An apparatus for cooling a power vehicle according to an embodiment of the present invention is an apparatus encompassing an apparatus for cooling a heat generating element for driving electric power, such as an inverter of an electric vehicle, an IGBT, and the like. Hereinafter, the cooling apparatus for electric power vehicles attached to an inverter and an IGBT is demonstrated to an example.

1 is an exploded perspective view of a power vehicle cooling apparatus according to an embodiment of the present invention, FIG. 2 is a bottom view of a state in which the power vehicle cooling apparatus of FIG. 1 is coupled, and FIG. 3 is a cross-sectional view taken along the cutting line III-III of FIG. .

As shown in these drawings, the cooling device for an electric vehicle according to an embodiment of the present invention includes a first cooling plate 100 in contact with the first heating element 1, which is one of the heating elements, and the first cooling plate 100. ) Is formed to face the second cooling plate 200 and the first cooling plate 100 and the second cooling element 200 in contact with the second heating element 2 which is one of the heat generating elements to form the flow path (11, 12) Intermediate plate 300, which is installed between the second cooling plates 200, divides the flow paths 11 and 12 into two layers, and communicates with the flow paths 11 and 12, and the coolant inlet 110 through which the coolant flows. And a cooling water outlet 120 communicating with the flow paths 11 and 12 and through which the cooling water flows.

As described above, the first heat generating element 1 and the second heat generating element 2 may be various components of the inverter or an IGBT. One embodiment of the present invention can be cooled by attaching such a heating element on both sides of the first cooling plate 100 and the second cooling plate 200, has the advantage of taking up less volume, two layers of cooling water Since the first cooling plate 100 and the second cooling plate 200 are separated and cooled by being transferred to the flow path divided into two parts, the cooling efficiency does not decrease.

The first heat generating element 1 is, for example, an IGBT element including a cooling fin 1a that is directly contacted and cooled by the flow paths 11 and 12. That is, in the case of a heat generating element having a large amount of heat generation, a cooling fin is attached, the cooling fin is exposed to the cooling water flow path, and the cooling water is directly cooled, thereby increasing the cooling efficiency. In the exemplary embodiment of the present invention, only the first heating element 1 is provided with a cooling fin, but the present invention is not limited thereto, and the second heating element 2 also includes cooling fins to be directly exposed to the flow path. It may be.

Sealing ribs 101 and 201 protrude from the surfaces of the first cooling plate 100 and the second cooling plate 200 that face each other, and the sealing ribs 101 and 201 are connected without a broken portion. . In addition, the first cooling plate 100 and the second cooling plate 200 are sealed by brazing bonding between the sealing ribs 101 and 201 facing each other. That is, a metal with a low melting point is melted between the sealing ribs 101 and 201, fused, and sealed. Such brazing bonding not only eliminates the need for a sealing ring for sealing between the first cooling plate 100 and the second cooling plate, but also eliminates the need for numerous bolt and nut coupling holes for compressing the sealing ring. The advantage is that it can be simplified.

The first cooling plate 100 is formed in a flat plate shape and is formed by passing through a load through hole 130 through which the cooling fin 1a described above passes. In addition, a sealing ring 140 is disposed on the outer circumferential surface of the load through hole 130 to seal the heat generating element 1 having the cooling fin 1a. Therefore, as described above, since the cooling fin 1a is directly exposed to the flow path and cooled, the cooling efficiency can be increased.

The cooling water inlet 110 and the outlet 120 are formed by opening a portion of the opposite surface facing the second cooling plate 200 of the first cooling plate 100. That is, the inlet protrusion 251 and the outlet protrusion 252 protrude laterally to the second cooling plate 100, and correspondingly, the inlet forming portion 151 and the outlet forming portion ( 152 is formed to protrude. The coolant inlet 110 and the coolant outlet 120 are formed to penetrate the upper surfaces of the inlet forming unit 151 and the outlet forming unit 152, respectively, and the inlet guide unit (the upper surface of the inlet 110 and the outlet 120). 111 and the outlet guide portion 121 are combined.

The coolant inlet 110 and the coolant outlet 120 are formed outside the edges of the intermediate plate 300. Accordingly, the flow of the fluid guided by the inlet guide 111 may be uniformly divided into upper and lower flow paths 11 and 12 by the edges of the intermediate plate 300.

The coolant inlet 110 and the coolant outlet 120 are disposed in a straight line. That is, the coolant inlet 110 and the coolant outlet 120 are disposed on the corners facing each other, so that the fluid introduced through the coolant inlet 110 does not return and exits directly in a straight line, thereby loading the coolant flow. Do not take much.

In addition to the above-described portion, the first cooling plate 100 is provided with a plurality of fastening balls 105 and fastening bosses 107.

4 is a bottom perspective view of the first cooling plate 100 of FIG. 1.

Intermediate plate height adjustment protrusion 160 is formed on the surface (lower surface) facing the flow path of the first cooling plate 100 protruding to the surface facing the flow path of the first cooling plate to support the intermediate plate 300. And a coolant divider 161 formed to protrude from the end of the middle plate height adjustment protrusion 160 to divide the incoming coolant into a plane. That is, the middle plate height adjustment protrusion is formed by extending both ends to a position adjacent to the inlet and the outlet, the coolant divider 161 is formed to protrude in a streamline at the end of the middle plate height adjustment protrusion (160). Accordingly, the coolant divider 161 is formed at a position adjacent to the inlet, thereby dividing the incoming coolant into left and right regions I and II.

In addition to the inlet protrusion 251, the outlet protrusion 252, and the sealing rib 201 described above, the second cooling plate 200 is formed by protruding the rigid increase rib 202 on the surface facing the flow path. The rigid increase rib 202 is formed in a portion where the flow paths 11 and 12 are not formed. That is, the rigid increase rib 202 is formed in a region where the heat generating element is not coupled, to prevent cooling of the region where the cooling water is not needed.

In addition, the rigid increase rib 202 may be formed to a height that supports the intermediate plate 300. In addition, the guide protrusion 205 for guiding the flow of the fluid is formed to protrude, it is preferable that the height of the guide protrusion 205 is also formed to a height enough to support the intermediate plate (300).

As described above, one embodiment of the present invention, by attaching the heat source element on both sides of the first cooling plate and the second cooling plate can be cooled, it is possible to reduce the volume of the cooling device.

In addition, by providing the intermediate plate, by dividing the cooling water into the first cooling plate and the second cooling plate, it is possible to prevent the cooling of only one of them.

And, by providing the intermediate plate height adjustment protrusion, by adjusting the position of the intermediate plate, it is possible to vary the amount of cooling water divided up and down.

In addition, by providing a coolant divider, the coolant can be divided and flow in the planar direction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

1: first heating element 100: first cooling plate
2: second heating element 200: second cooling plate
300: middle plate 11, 12: euro
110: cooling water inlet 120: cooling water outlet
202: rigidity increase rib 1a: cooling fin
130: load through hole 140: sealing ring
101, 201: sealing rib 111: inlet guide
160: middle plate height adjustment protrusion 161: coolant divider

Claims (14)

In the power vehicle cooling device for cooling the heat generating element installed in the power vehicle,
A first cooling plate in contact with the first heating element which is one of the heating elements;
A second cooling plate which is formed to face the first cooling plate to form a flow path, and is in contact with a second heating element which is one of the heating elements;
An intermediate plate disposed between the first cooling plate and the second cooling plate to divide the flow path into two layers;
A coolant inlet communicating with the flow path and into which coolant is introduced; And
A coolant outlet configured to communicate with the flow path and to allow coolant to flow out;
Cooling device for a power vehicle comprising a.
The method of claim 1,
Rigidity increase ribs are formed to protrude from the surface facing at least one of the first cooling plate and the second cooling plate,
The stiffness increasing rib is formed on a portion of the power vehicle cooling apparatus characterized in that the passage is not formed.
The method of claim 1,
At least one of the first heating element and the second heating element includes a cooling fin that is directly in contact with the flow path, and cooled
A load through hole is formed through at least one of the first cooling plate and the second cooling plate so that the cooling fins are exposed to the flow path.
A sealing ring for sealing the heat generating element having the cooling fin on an outer circumferential surface of the load through hole;
Cooling device for a power vehicle comprising a further.
The method according to any one of claims 1 to 3,
Cooling devices for power vehicles, characterized in that the sealing ribs in contact with each other protrudingly formed on the surfaces facing each other of the first cooling plate and the second cooling plate, the sealing ribs are connected without a broken portion.
5. The method of claim 4,
And the first cooling plate and the second cooling plate are sealed by brazing bonding between the sealing ribs facing each other.
5. The method of claim 4,
The cooling water inlet is formed in the opening portion on the opposite side facing the surface facing the second cooling plate of the first cooling plate, characterized in that the cooling device for a power vehicle.
The method according to claim 6,
The cooling water inlet is an electric vehicle cooling apparatus, characterized in that formed on the outer edge of the intermediate plate.
The method of claim 7, wherein
The cooling water inlet is formed in the cooling device for the electric power vehicle characterized in that the inlet guide portion for guiding the cooling water toward the edge of the intermediate plate.
5. The method of claim 4,
And the cooling water outlet is partially opened at an opposite surface on which the sealing rib of the first cooling plate is formed.
The method of claim 9,
The cooling water outlet is a power vehicle cooling device, characterized in that formed on the outer edge of the intermediate plate.
The method according to any one of claims 1 to 3,
And the cooling water inlet and the cooling water outlet are arranged in a straight line.
The method according to any one of claims 1 to 3,
An intermediate plate height adjustment protrusion protruding from a surface of the first cooling plate facing the flow path to support the intermediate plate;
Cooling device for a power vehicle comprising a further.
The method according to any one of claims 1 to 3,
A coolant divider formed at a position adjacent to the inlet and dividing the incoming coolant into a plane;
Cooling device for a power vehicle comprising a further.
13. The method of claim 12,
The end of the middle plate height adjustment protrusion is formed extending to a position adjacent to the inlet,
A coolant divider protruding from an end of the middle plate height adjusting protrusion to divide the incoming coolant into a plane;
Cooling device for a power vehicle comprising a further.

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