KR102350025B1 - Heat Exchanger for Cooling Electric Element - Google Patents

Abstract

The present invention relates to a heat exchanger for cooling an electric element, and more particularly, multi-stage coupling of a tube-type cooling flow passage part is possible. It relates to a heat exchanger for cooling electrical elements that can minimize the difference in cooling capacity of

Description

Heat Exchanger for Cooling Electric Element

The present invention relates to a heat exchanger for cooling an electric element, and more particularly, multi-stage coupling of a tube-type cooling flow passage part is possible. It relates to a heat exchanger for cooling electrical elements that can minimize the difference in cooling capacity of

Vehicles such as hybrid vehicles, fuel cell vehicles, and electric vehicles using the driving force of a motor are generally equipped with a PCU (power control unit) that controls power supplied from a driving battery to be supplied to the motor in a desired state.

The PCU includes electrical devices such as inverters, smoothing capacitors, and converters, and since the electrical devices generate heat while power is supplied, a separate cooling device is required to cool them.

Japanese Laid-Open Patent Publication No. 2001-245478 (“Inverter Cooling Device”, 2001.09.07.) discloses an inverter using a semiconductor module including a semiconductor element such as an IGBT and a diode, and Japanese Patent Application Laid-Open No. 2008- No. 274283 (“Semiconductor Device”, 2008.12.04) discloses a heat sink that is installed so as to be in contact with a lower surface of a semiconductor element and is formed so that heat is exchanged while a fluid flows therein.

In the case of the single-sided cooling method described above, there is a limitation in cooling performance, and the double-sided cooling method is designed to improve this. It should be higher than the height, and in order to increase the heat transfer performance of the heat exchanger, both the element and the heat exchanger must be well compressed.

1 is a view showing a conventional double-sided cooling type heat exchanger, a tube 10 stacked in multiple stages, a connection plate 20 coupled to both ends of the tube 10, and a connection plate 20 coupled between the stacking plates It includes a block 30 forming a flow path in the direction and an inlet 41 and an outlet 42 through which the cooling fluid is introduced and discharged, and the electric device 50 is inserted between the tubes 10 stacked in multiple stages. and can be cooled by a cooling fluid.

At this time, as shown in FIGS. 1 and 2 , since the tube 10 formed at the lowermost and uppermost sides is in cross-section with the electric element 50, the cooling efficiency according to the flow of the cooling fluid is not high. , in the case of the tube 10 stacked in the central part except for the tube 10 formed on the lowermost and uppermost sides, it comes in contact with the electric element 50 on both sides, so that the tube 10 formed on the lowermost and uppermost sides is in contact with Compared to the electric element 50 , the electric element 50 formed in the central portion has relatively lower cooling efficiency.

In particular, it is inserted into the tube 10 formed at the lowermost side, the electric element 50-1 formed in a position close to the inlet 41 into which the cooling fluid flows, and the tube 10 formed in the central portion. , there is a large difference in surface temperature between the inlet 410 through which the cooling fluid is introduced and the electric element 50-2 formed at a distant location, which has a problem in that the cooling of the electric element is non-uniform depending on the number of stages.

Japanese Laid-Open Patent Publication No. 2001-245478 (“Inverter cooling device”, 2001.09.07.) Japanese Laid-Open Patent Publication No. 2008-274283 (“Semiconductor Device”, 2008.12.04)

The present invention has been devised to solve the above-described problems, and an object of the present invention is a double-sided cooling method in which a tube-type cooling passage unit is stacked in at least three stages, and an electric element inserted between the cooling passage units is included. In a heat exchanger for cooling an electric element with a heat exchanger, by first supplying and flowing the cooling fluid flowing in through the inlet to at least one cooling flow passage except for the cooling passage portions located at the uppermost and lower sides, and then flowing it to the remaining cooling passages, each It relates to a heat exchanger for cooling an electric element that can minimize the difference in the cooling capacity of the electric element in the stage.

The heat exchanger for cooling an electric element according to the present invention includes a cooling flow passage part 100 in which a cooling fluid flows, and at least three layers are stacked; a connection plate 200 coupled to both ends and a predetermined region in the longitudinal direction of the cooling flow path part 100 to form a cooling fluid space communicating with the cooling flow path part 100; an outlet 400 connected to any one of the connection plates 200 and including an inlet 410 through which the cooling fluid flows and an outlet 420 through which the cooling fluid is discharged; A connection flow path is formed between the plurality of stacked connection plates 200 in the stacking direction, and the cooling fluid flowing in through the inlet 410 is at least except for the cooling flow path part 100 formed at the uppermost and lowermost sides. It is characterized in that it includes; a connection block 300 formed to flow first to one or more cooling passages 100 .

In addition, the heat exchanger 1000 for cooling the electric element is characterized in that at least two electric elements 1 are inserted between the cooling passage parts 100 in the longitudinal direction.

In addition, the inlet and outlet 400 is connected in a stacking direction to at least one selected from among the connection plates 200 in which the inlet 410 and the outlet 420 are formed at the uppermost and lowermost sides in the stacking direction, the connection By the control of the block 300, the cooling fluid flowing in through the inlet 410 is preferentially flowed to at least one cooling passage part 100 except for the cooling passage part 100 formed at the uppermost and lowermost sides. characterized in that

In addition, the inlet and outlet 400 is connected to any one or more connecting plates 200 selected except for the connecting plate 200 in which the inlet 410 is formed at the uppermost and lower sides in a direction perpendicular to the stacking direction, The cooling fluid flowing in through the inlet 410 under the control of the connection block 300 is preferentially directed to at least one cooling passage part 100 excluding the cooling passage part 100 formed at the uppermost and lowermost sides. It is characterized in that it is made to flow.

In addition, the connection block 300 includes a communication hole 330 including a first communication hole and a second communication hole communicating with the connection plate 200 in a stacking direction, the first communication hole and the second communication hole. It is characterized in that the flow path of the cooling fluid is selected depending on whether the communication hole is opened or closed.

In addition, the connection block 300 controls the first communication hole and the second communication hole so that the cooling fluid flowing through at least one cooling passage part 100 formed in the center flows in both directions in the stacking direction. do it with

In addition, the connection block 300 includes the first communication hole and the second communication hole so that the cooling fluid finally flows into the cooling passage part 100 formed on the uppermost side and the lowermost side and is discharged through the outlet part 420 . It is characterized in that the communication hole is controlled.

In addition, when the electric element 1 is provided with a plurality of different calorific values, the remaining connection plates 200 except for the cooling passage part 100 formed at the uppermost and lowermost sides of the electric element 1 having a relatively high calorific value. ) is inserted into the

The heat exchanger for cooling electric elements according to the present invention can increase the number of stacked cooling passages according to the number of required electric elements, so it is advantageous for cooling a large number of electric elements, and the cooling application range can be expanded as much as selected There is this.

In addition, the heat exchanger for cooling electric elements according to the present invention can preferentially flow the cooling fluid to the cooling passages stacked in the central part of the multi-layered cooling passages, so that the cooling efficiency of the electric elements is uniform.

1 is a view showing a conventional heat exchanger for cooling electrical elements;
Figure 2 is a view showing a problem of the conventional heat exchanger for cooling electrical elements.
3 is a view showing a heat exchanger for cooling an electric element according to an embodiment of the present invention;
4 is another view showing a heat exchanger for cooling an electric element according to an embodiment of the present invention;
5 is a view showing an embodiment of a flow path of a heat exchanger for cooling an electric element according to an embodiment of the present invention;
6 is another view showing an embodiment of a flow path of a heat exchanger for cooling an electric element according to an embodiment of the present invention.

Hereinafter, a heat exchanger for cooling an electric device according to an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

3 to 4 , the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention is largely a cooling flow passage 100 , a connection plate 200 , an outlet 400 and a connection. It is formed to include a block 300 .

The cooling passage 100 may be manufactured in a tube type through an extrusion process, and the cooling passage 100 includes a cooling passage through which a cooling fluid flows therein, and is formed so that both ends in the longitudinal direction are open.

In this case, the cooling flow path part 100 may have an inner fin (not shown) therein to improve cooling efficiency if necessary, and in the extrusion process of the cooling flow path part 100, in the width direction of the cooling flow path. A partition wall (not shown) that separates the space may be formed to extend in the longitudinal direction.

In addition, the cooling passage part 100 of the heat exchanger 1000 for cooling an electric device according to an embodiment of the present invention is formed by stacking at least three stages.

The connection plate 200 is inserted into both ends in the longitudinal direction of the cooling flow passage part 100 to form a cooling fluid flow space communicating with the cooling flow passage part 100 .

The connection plate 200 may include an upper plate 210 and a lower plate 220, and the upper plate 210 is coupled to upper surfaces of both ends of the cooling passage part 100 so that a predetermined area overlaps, and the The lower plate 220 is coupled to the lower surface of both ends of the cooling passage part 100 so that a predetermined area overlaps.

The upper plate 210 and the lower plate 220 may be coupled through brazing in a state in which coupling portions protruding flat to the outside are formed at edges, respectively, and assembled at both ends of the cooling passage 100 .

In this case, the upper plate 210 and the lower plate 220 may be integrally formed and fitted to both ends of the cooling passage part 100 and then coupled through brazing.

The inlet and outlet 400 includes an inlet 410 and an outlet 420 , and the inlet 410 is connected to any one of the connection plates 200 so that the cooling fluid flows in, and the outlet 420 may be connected to any one of the connection plates 200 and the cooling fluid may be discharged.

The inlet 410 and the outlet 420 may be formed on the same connection plate 200, or formed on different connection plates 200, etc., provided that the flow of the cooling fluid is not obstructed, various formation positions An embodiment of is possible.

At this time, the inlet 410 and the outlet 420 may be connected to the connection plate 200 in the stacking direction of the cooling flow passage 100 to flow the cooling fluid, and the cooling flow passage 100 may be stacked in the stacking direction. It can be connected to the connection plate 200 in a direction perpendicular to the flow, and the cooling fluid can be introduced thereinto.

In addition, the inlet 410 and the outlet 420 can be connected to various types of inlet and outlet passages such as an inlet pipe and an outlet pipe in the form of a pipe can be further coupled, of course.

The connection block 300 may be in communication with the inlet/outlet 400 and may form a connection flow path through which the cooling fluid flows in the stacking direction between the plurality of stacked connecting plates 200 .

At this time, the connection block 300 may preferentially supply the cooling fluid flowing in through the inlet 410 to at least one cooling flow passage 100 excluding the cooling passage 100 formed at the uppermost and lowermost sides. is formed

That is, in the heat exchanger for cooling an electric element according to an embodiment of the present invention, the cooling passage part 100 is formed by stacking at least three or more stages, and the electric element 1 is inserted therebetween, and the above-described electric element ( In order to minimize the variation in cooling efficiency of 1), it is preferentially supplied to the cooling flow path part 100 formed in the central part having a lower cooling efficiency than the cooling flow path part 100 formed at the uppermost and lowest sides to flow.

As an embodiment for preferentially supplying the cooling fluid to the cooling flow path part 100 formed in the central part through the inflow and outflow part 400 and the connection block 300 described above, the inflow part 400 is the inlet part 410 . and the outlet 420 may be connected to any one or more selected among the connection plates 200 formed at the uppermost and lowermost sides in the stacking direction. (See Fig. 5)

At this time, the inlet 410 and the outlet 420 are connected to the connecting plate 200 formed at the uppermost and lowermost sides, and in order to supply the cooling fluid to the cooling passage part 100 in the central part, the connecting block By the control of 300, the cooling fluid flowing in through the inlet 410 is preferentially flowed to at least one cooling passage part 100 excluding the cooling passage part 100 formed at the uppermost and lowermost sides. can

In addition, the inlet and outlet 400 may be vertically connected to one selected connecting plate 200 except for the connecting plate 200 in which the inlet 410 is formed at the uppermost and lowermost sides in the stacking direction. (See Fig. 6)

The outlet portion 420 is preferably connected to the connection plate 200 formed at the uppermost and lowermost sides in the stacking direction, but is not limited thereto.

At this time, the inlet 410 is vertically connected to the stacking direction to one or more connecting plates 200 selected except for the connecting plates formed at the uppermost and lowermost sides, and the cooling fluid is directed to the cooling passage part 100 in the central part. In order to supply the cooling fluid flowing in through the inlet 410 under the control of the connection block 300, at least one or more cooling passages except for the cooling passages 100 formed at the uppermost and lowermost sides. (100) can be made to flow first.

The formation of the flow path of the cooling fluid through the above-described connection block 300 will be described in more detail.

The connection block 300 forms a connection passage for flowing the cooling fluid, and for this, the connection plate 200 and the connection block 300 communicate with each other.

At this time, the upper plate 210 of the connection plate 200 is formed with an upper plate through hole 211, which is a passage through which the cooling fluid flows to the adjacent cooling passage part 100, and the lower plate 220. The lower plate through hole 221 is formed.

At this time, the connection block 300 is formed of an upper connection block 310 and a lower connection block 320 , the upper connection block 310 is in contact with the lower surface of the lower plate 220 , and the lower plate through hole 221 . ) and a communication hole 330 to communicate with.

In addition, the lower connection block 320 is in contact with the upper surface of the upper plate 210 and includes a communication hole 330 communicating with the upper plate through hole 211 .

In addition, the connection block 300 may further include a sealing member 340 provided in an area where the upper connection block 310 and the lower connection block 320 are coupled to prevent leakage of the cooling fluid, and the sealing member Reference numeral 340 may be a rubber gasket, or a member that is cured, such as a liquid gasket.

The connection block 300 is formed to have the same height as the height of the electric element 1 , so that both sides of the electric element 1 and the cooling passage part 100 are in surface contact with each other.

That is, in the heat exchanger 1000 for cooling an electric device according to an embodiment of the present invention, the cooling fluid flowing into the inlet 410 passes through the connection plate 200 and flows through the cooling passage 100 in the stacking direction. In order to move to the cooling flow path part 100 adjacent to Through the upper plate through hole 211 or the lower plate through hole 221 connected to one or the other end of the flow passage 100 , it can move to the adjacent cooling passage 100 .

In this case, the communication hole 330 is formed with two holes, a first communication hole and a second communication hole, and a selected flow path for the cooling fluid may be formed depending on whether the first communication hole and the second communication hole are opened or closed.

That is, the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention can form a selected flow path of the cooling fluid by controlling the opening and closing of the first communication hole and the second communication hole, the uppermost and the lowermost By preferentially supplying and flowing a cooling fluid to at least one cooling flow path part 100 formed in the central part except for the cooling flow path part 100 formed in the can be minimized.

At this time, in the heat exchanger 1000 for cooling an electric device according to an embodiment of the present invention, the cooling fluid is preferentially applied to at least one cooling passage part 100 stacked in the central part through the control of the first communication hole and the second communication hole. is supplied and the flowing cooling fluid flows to the non-flowing cooling flow path part 100 , and the cooling fluid flows to the cooling flow path part 100 formed in both directions in the height direction through the control of the first communication hole and the second communication hole. It is preferable to minimize the variation in cooling efficiency of the electric element 1 by flowing the .

In this case, the first communication hole and the second communication hole described above are communication holes independent of each other, and the position is not limited, but for the explanation of the first communication hole and the second communication hole, the communication hole on the left shown in the drawing is the first communication hole. As a communication hole, the communication hole shown on the right is referred to as a second communication hole.

An embodiment of the flow of the cooling fluid using the first communication hole and the second communication hole of the above-described connection block 300 will be described.

The heat exchanger 1000 for cooling an electric device according to an embodiment of the present invention shown in FIG. 5 is formed by connecting an inlet 410 and an outlet 420 to the connection plate 200 in the stacking direction, and left The first communication hole and the second communication hole formed in the third from the bottom are closed to flow the cooling fluid flowing in from the inlet 410 to the cooling passage 100 formed in the center, and the cooling passage formed in the center As for the cooling fluid flowing through the unit 100, the first communication holes formed in the second and third from the lower direction on the right are opened, and the first communication holes formed in the first and fourth from the lower direction are closed, The cooling fluid flows in both directions in the height direction where the cooling fluid does not flow.

Accordingly, by opening the second communication holes formed in the first and second from the lower direction on the left side, the cooling fluid flows in the direction of the outlet 420 to be discharged.

That is, in the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention, the electric element 1 is in contact with the end face of the electric element 1 and is formed at the uppermost and lowermost sides with high cooling efficiency except for the center of the heat exchanger 1000 . The cooling fluid is first supplied to the cooling flow path part 100 formed in the By flowing, it is possible to minimize the variation in the cooling efficiency of the entire electric element 1 of the heat exchanger.

The heat exchanger 1000 for cooling an electric device according to an embodiment of the present invention shown in FIG. 6 is formed by connecting an inlet 410 and an outlet 420 to the connection plate 200 perpendicular to the stacking direction, , by opening the second communication holes formed in the first and fourth from the lower left to flow the cooling fluid flowing in from the inlet 410 to the cooling passage 100 formed in the center, and the cooling passage formed in the center The cooling fluid flowing through the unit 100 opens both the first and second communication holes on the right side, thereby allowing the cooling fluid to flow in both directions in the height direction in which the cooling fluid does not flow.

Accordingly, by controlling all of the first communication holes on the left to be opened so that the cooling fluid is discharged through the outlet 420 formed in the lower left side, the cooling fluid flowing through the cooling passage part 100 is discharged.

That is, the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention shown in FIG. 6 also comes into contact with the electric element 1, and the cooling passage part 100 is formed at the uppermost and lowermost sides with high cooling efficiency. ), the cooling fluid is first supplied to the cooling flow path part 100 formed in the center except for, and the cooling flow path formed at the top and bottom sides before discharging the cooling fluid that flows while exchanging heat through the outlet part 420 . By flowing into the part 100, it is possible to minimize the variation in the cooling efficiency of the overall electric element 1 of the heat exchanger.

In other words, the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention has various cooling methods capable of minimizing the variation in the cooling efficiency of the electric element 1 depending on whether the first communication hole and the second communication hole are opened or closed. A fluid flow path may be formed.

In addition, since the heat exchanger 1000 for cooling an electric element according to an embodiment of the present invention first supplies a cooling fluid to the cooling passage part 100 formed in the center through the above-described configuration, the electric element 1 having a different calorific value ), a device with a high heating value is inserted so as to face the cooling flow path part 100 formed in the center, and a device with a relatively low heating value is inserted so as to face the other cooling flow path part 100, so that efficient electricity Cooling of the element 1 can be made possible.

The present invention is not limited to the above-described embodiments, and the scope of application is varied, and without departing from the gist of the present invention as claimed in the claims, those of ordinary skill in the art to which the present invention pertains It goes without saying that variations are possible.

1000: heat exchanger for cooling electric elements
100: cooling passage part
200: connection plate
210: upper plate 211: upper plate through hole
220: lower plate 221: lower plate through hole
300: connection block
310: upper connection block 320: lower connection block
330: communication hole
400: inlet and outlet
410: inlet 420: outlet

Claims (8)

The cooling fluid flows therein, and the cooling passage part 100 is stacked in at least three stages;
a connection plate 200 coupled to both ends and a predetermined region in the longitudinal direction of the cooling passage 100 to form a cooling fluid space communicating with the cooling passage 100;
an outlet 400 connected to any one of the connection plates 200 and including an inlet 410 through which the cooling fluid flows and an outlet 420 through which the cooling fluid is discharged;
A connection flow path is formed between the plurality of stacked connection plates 200 in the stacking direction, and the cooling fluid flowing in through the inlet 410 is at least except for the cooling flow path part 100 formed at the uppermost and lowermost sides. Including; and a connection block 300 that is formed to flow first to one or more cooling passage units 100 ,
At least two or more electric elements 1 are inserted in the longitudinal direction between the cooling passage parts 100,
The inlet and outlet 400 is,
The inlet 410 and the outlet 420 are connected in a stacking direction to at least one selected from among the connection plates 200 formed at the uppermost and lowermost sides in the stacking direction, and by the control of the connecting block 300 , the The cooling fluid flowing in through the inlet 410 first flows to at least one cooling flow path part 100 except for the cooling flow path part 100 formed at the top and bottom sides,
The connection block 300 is
and a communication hole 330 including a first communication hole and a second communication hole communicating with the connection plate 200 in a stacking direction,
A heat exchanger for cooling an electric element, characterized in that forming a flow path for a cooling fluid according to whether the first communication hole and the second communication hole are opened or closed.
delete delete delete The cooling fluid flows therein, and the cooling passage part 100 is stacked in at least three stages;
a connection plate 200 coupled to both ends and a predetermined region in the longitudinal direction of the cooling passage 100 to form a cooling fluid space communicating with the cooling passage 100;
an outlet 400 connected to any one of the connection plates 200 and including an inlet 410 through which the cooling fluid flows and an outlet 420 through which the cooling fluid is discharged;
A connection flow path is formed between the plurality of stacked connection plates 200 in the stacking direction, and the cooling fluid flowing in through the inlet 410 is at least except for the cooling flow path part 100 formed at the uppermost and lowermost sides. Including; and a connection block 300 that is formed to flow first to one or more cooling passage units 100 ,
At least two or more electric elements 1 are inserted in the longitudinal direction between the cooling passage parts 100,
The inlet and outlet 400 is,
The inlet 410 is connected perpendicularly to the stacking direction to any one or more connection plates 200 selected except for the connection plates 200 formed at the uppermost and lower sides, and the control of the connecting block 300 is First, the cooling fluid introduced through the inlet 410 flows to at least one or more cooling passages 100 except for the cooling passages 100 formed at the uppermost and lowermost sides by the
The connection block 300 is
and a communication hole 330 including a first communication hole and a second communication hole communicating with the connection plate 200 in a stacking direction,
A heat exchanger for cooling an electric element, characterized in that forming a flow path for a cooling fluid according to whether the first communication hole and the second communication hole are opened or closed.
6. The method of claim 1 or 5,
The connection block 300 is
Heat exchanger for cooling an electric element, characterized in that the first communication hole and the second communication hole are controlled so that the cooling fluid flowing through at least one cooling passage part (100) formed in the center flows in both directions in the stacking direction.
7. The method of claim 6,
The connection block 300 is
Characterized in that the first communication hole and the second communication hole are controlled so that the cooling fluid finally flows into the cooling passage part (100) formed at the uppermost side and the lowest side and is discharged through the outlet part (420). Heat exchanger for cooling electrical elements.
8. The method of claim 7,
The electric device 1 is
Electricity characterized in that when a plurality of different heating values are provided, the electrical element (1) having a relatively high heating value is inserted into the remaining connection plates (200) except for the cooling passage part (100) formed on the uppermost and lowermost sides. Heat exchanger for element cooling.

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