JP2016225530A - Liquid-cooled cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid-cooled cooling device which can be made compact, while suppressing increase in the pressure loss when the cooling liquid flows through a casing.SOLUTION: A liquid-cooled cooling device 1 includes a casing 2 through which cooling liquid flows, and a heat dissipator 3 fixed to the casing 2. The outer surface of the top wall 2a of the casing 2 becomes a heating element attachment surface 4. The heat dissipator 3 consists of a heat dissipation substrate 14, and a plurality of pin fins 15A, 15B provided integrally with the heat dissipation substrate 14, and scattered entirely in the casing 2. On the bottom wall 2b of the casing 2, a cooling liquid inflow section 12 and a cooling liquid outflow section 13 are formed to face a portion of the heat dissipator 3 where the pin fin 15A is provided. The height of the pin fin 15A existing in a range of the cooling liquid inflow section 12 and cooling liquid outflow section 13 is set to 2/3 or less of the internal height of the casing 2 at a portion where the pin fins 15A, 15B are provided.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a liquid cooling type cooling device that cools a heating element made of an electronic component such as a semiconductor element.

  In this specification and claims, the top and bottom of FIG.

  For example, as a liquid-cooled cooling device for cooling a power device (semiconductor element) such as an IGBT (Insulated Gate Bipolar Transistor) used in a power conversion device mounted on an electric vehicle, a hybrid vehicle, a train, etc., First, a casing having a top wall and a bottom wall, in which a cooling liquid flows, and a radiator fixed to the casing are provided, and an opening is formed in the top wall of the casing to dissipate heat. A radiator disposed in the opening of the casing and fixed to the casing, the first surface facing the casing and the second surface serving as a heating element mounting surface, and the first surface of the radiation substrate The heating element is provided with a plurality of pin fins integrally provided so as to protrude into the casing and scattered throughout the casing, and is attached to the heating element mounting surface. Luo emitted heat is proposed a liquid-cooling type cooling device which is radiated to the cooling fluid flowing through the casing via the heat sink substrate and pin fins of the radiator (see Patent Document 1).

  However, the liquid cooling type cooling device described in Patent Document 1 has a problem that the pressure loss when the cooling liquid flows in the casing increases.

  In order to solve such a problem, an inlet header portion is provided at one end portion in the casing, an outlet header portion is provided at the other end portion, and a coolant flow path is provided between both header portions. It is conceivable that an opening is formed at a portion facing the coolant flow path in the case, and the pin fin of the radiator is provided so as to protrude only into the coolant flow path of the casing. However, in such a liquid cooling type cooling device, pin fins are not provided, and therefore the portions of the inlet header portion and the outlet header portion that do not contribute to heat radiation to the cooling liquid become useless spaces, and the liquid cooling type cooling device The entire apparatus becomes large, which is not preferable depending on the installation state of the liquid cooling type cooling apparatus.

JP 2009-277768 A

  An object of the present invention is to provide a liquid cooling type cooling apparatus that can solve the above-described problems and can be reduced in size while suppressing an increase in pressure loss when the cooling liquid flows in the casing.

  In order to achieve the above object, the present invention comprises the following aspects.

1) A casing having a top wall and a bottom wall, in which a coolant flows, and a radiator fixed to the casing, whichever of the top wall outer surface and the bottom wall outer surface of the casing are provided. One of these is a heating element mounting surface, and the radiator is provided integrally with the heat dissipation board, which receives heat generated from the heating element mounted on the heating element mounting surface, and is scattered throughout the casing. A liquid cooling type cooling device comprising a plurality of pin fins, wherein heat generated from a heating element mounted on a heating element mounting surface is dissipated to a coolant flowing in a casing via a heat dissipation board and pin fins of the radiator. ,
Cooling liquid that causes the cooling liquid to flow into the casing into the wall where the inner height of the casing where the pin fins are provided is constant and the outer surface of the top and bottom walls of the casing is not the heating element mounting surface An inflow part and a cooling liquid outflow part for allowing the cooling liquid to flow out of the casing are formed so as to face a portion where the pin fins of the radiator are provided. An inlet pipe that is fed in and an outlet pipe that leads to the cooling outflow portion and sends out the cooling liquid from the casing are connected, and the pin fins present within the range of the cooling liquid inflow portion and the cooling liquid outflow portion are provided with pin fins. A liquid-cooling type cooling device that is 2/3 or less of the internal height of the casing of the part.

  2) The coolant inlet and the coolant outlet are circular, centered on the center of the coolant inlet and outlet and 1.5 times the diameter of the coolant inlet and outlet. The liquid cooling type cooling apparatus according to 1) above, wherein the height of the pin fins located in a circle having a diameter is 2/3 or less of the internal height of the casing of the portion where the pin fins are provided.

  3) The liquid-cooling type cooling device according to 1) or 2), wherein the height of the pin fins which are lowered is not more than ½ of the internal height of the casing where the pin fins are provided.

  4) The liquid cooling type according to any one of 1) to 3) above, wherein the heat dissipation board of the radiator also serves as a wall in which the outer surface of the top wall and bottom wall of the casing is a heating element mounting surface. Cooling system.

  5) Two circular through holes are formed on the wall of the top wall and bottom wall of the casing whose outer surface is not a heating element mounting surface, and the inlet pipe is inserted into one of the circular through holes. And the outlet pipe is inserted into the other circular through hole and joined to the casing, and the portion of the pipe inserted into the circular through hole of the inlet pipe serves as a coolant inflow portion, and in the circular through hole of the outlet pipe. The liquid cooling type cooling device according to any one of 1) to 4) above, wherein a portion of the pipe line inserted into the is a coolant outflow portion.

  6) The tip of the pin fin which is not lowered is joined to the inner surface of the wall whose outer surface is not the heating element mounting surface of the top wall and the bottom wall of the casing. The liquid cooling type cooling apparatus as described.

  According to the liquid cooling type cooling apparatus of 1) to 6) above, the height of the pin fins existing within the range of the coolant inflow portion and the coolant outflow portion is between the coolant inflow portion and the coolant outflow portion. Since the coolant is lower than the height of the pin fin located in the middle portion, the coolant passes through the coolant inflow portion from the inlet pipe, and the tip of the low pin fin in the casing and the wall provided with the coolant inflow portion After flowing into the space between the other high pin fins, it is diverted to all the cooling liquid flow gaps between the high fins and flows to the cooling liquid outflow side, and the tip of the low pin fin and the cooling liquid inflow part are provided in the casing. After flowing into and joining the space between the walls, it is sent out to the outlet pipe through the coolant outlet. Therefore, the coolant flows uniformly throughout the casing, the flow rate of the coolant is constant, and an increase in pressure loss when the coolant flows in the casing can be suppressed. In addition, there is no need to provide an inlet header portion and an outlet header portion that do not contribute to heat dissipation to the cooling liquid in the casing because pin fins are not provided, and the liquid cooling type cooling device as a whole can be downsized. Space saving of the installation space of the liquid cooling type cooling device can be achieved.

  According to the liquid cooling type cooling apparatus of 2) and 3) above, it is possible to effectively suppress an increase in pressure loss when the cooling liquid flows in the casing.

  According to the liquid cooling type cooling device of the above 4), the thermal conductivity from the heating element attached to the heating element mounting surface to the pin fin is improved, and as a result, the heat generated from the heating element is transferred to the coolant flowing in the casing. Heat dissipation performance is improved.

  According to the liquid cooling type cooling device of the above 6), the pressure resistance of the casing is improved.

It is a disassembled perspective view which shows the liquid cooling type cooling device of this invention. FIG. 2 is a vertical sectional view of the liquid cooling type cooling device of FIG. 1. It is the sectional view on the AA line of FIG. It is a perspective view which shows the heat radiator used for the liquid cooling type cooling device of FIG. It is a figure equivalent to FIG. 3 which shows the modification of the casing and heat radiator of a liquid cooling type cooling device.

  Embodiments of the present invention will be described below with reference to the drawings.

  In this specification, the term “aluminum” includes aluminum alloys in addition to pure aluminum.

  Further, in the following description, the left and right in FIG. 2 are referred to as left and right, the upper side in FIG.

  1 to 3 show a liquid cooling type cooling device, and FIG. 4 shows a radiator used in the liquid cooling type cooling device.

  1 to 3, the liquid cooling type cooling device (1) is fixed to an aluminum casing (2) having a top wall (2a), a bottom wall (2b) and a peripheral wall (2c), and the casing (2). An aluminum radiator (3), and one of the top wall (2a) and bottom wall (2b) of the casing (2), here the outer surface of the top wall (2a) is a heating element. A mounting surface (4) is provided.

  The casing (2) constitutes a box-shaped aluminum lower component member (5) opened upward and constituting a bottom wall (2b) and a peripheral wall (2c), and a peripheral wall (2c) of the lower component member (5) It consists of a plate-like aluminum upper component member (6) brazed to an outward flange provided at the upper end of the part and constituting the top wall (2a).

  Circular through-holes (7) and (8) are respectively formed at the left and right ends of the central portion in the front-rear direction of the bottom wall (2b) of the casing (2). The end of the aluminum inlet pipe (9) having a circular cross section for feeding the coolant into the casing (2) is inserted into the left circular through hole (7), and the right circular through hole (8) is inserted. An aluminum outlet pipe (11) with a circular cross section that sends out the coolant from the inside of the casing (2) is connected, and both pipes (9) and (11) are brazed to the bottom wall (2b) of the casing (2). . The portion of the pipe inserted into the circular through hole (7) of the inlet pipe (9) becomes a circular coolant inflow portion (12) for allowing the coolant to flow into the casing (2), and the outlet pipe ( A portion of the pipe line inserted into the circular through hole (8) of 11) forms a circular coolant outflow portion (13) through which coolant flows out of the casing (2).

  As shown in FIGS. 2 to 4, the radiator (3) is integrally provided on the lower surface of the heat radiating board (14) and the heat radiating board (14) so as to protrude downward, and is attached to the entire inside of the casing (2). It consists of a plurality of existing cylindrical pin fins (15A) (15B). The heat radiating board (14) also serves as the upper component (6) of the casing (2), that is, the top wall (2a), and its lower peripheral edge is brazed to the outward flange at the upper end of the peripheral wall of the lower component (5). It is attached. The upper surface of the heat radiating board (14) is a heating element mounting surface (4), and further to power devices such as IGBTs, IGBT modules integrated with a control circuit and housed in the same package, and IGBT modules A heating element (P) composed of an intelligent power module and the like integrated with a protection circuit and housed in the same package is attached to the heating element mounting surface (4) via the insulating member (I). The pin fins (15A) and (15B) are provided within a quadrangular range where the four sides are located in the vicinity of the peripheral wall (2c) in the portion of the heat dissipation board (14) facing the casing (2). In the rectangle, the left side is outside (left side) of the coolant inflow portion (12), and the right side is outside (right side) of the coolant outflow portion (13). Further, the distance between the front and rear sides of the quadrangle and the front and rear side walls of the peripheral wall (2c) is substantially equal to the distance between the left and right sides of the quadrangle and the left and right side walls of the peripheral wall (2c). preferable. The internal height of the casing (2) where the pin fins (15A) (15B) are provided is constant. In this embodiment, the internal height of the casing (2) is the same and constant throughout.

  When the liquid cooling type cooling device (1) is viewed from above or below, the heights of the plurality of first pin fins (15A) existing within the range of the coolant inflow portion (12) and the coolant outflow portion (13) are Further, it is 2/3 or less of the internal height of the casing (2) where the pin fins (15A) and (15B) are provided, and preferably 1/2 or less. Therefore, a first space (16) for diverting the coolant is formed between the coolant inflow portion (12) and the tip of the first pin fin (15A), and the coolant outflow portion (13) and the first pin fin (15A) are formed. ), A second space (17) for joining the coolant is formed. Here, the first pin fin (15A) is not only within the range of the coolant inflow portion (12) and the coolant outflow portion (13), but also in the circular coolant inflow portion (12) and the coolant outflow portion (13). It is preferably provided in a circle having a diameter 1.5 times the diameter of the coolant inflow portion (12) and the coolant outflow portion (13). The heights of the second pin fins (15B) are all equal, and the tip of the second pin fins (15B) is preferably brazed to the bottom wall (2b) of the casing (2). The height of the second pin fin (15B) of the second pin fin (15B) is different from the height of the remaining second pin fin (15B) and the tip is not brazed to the bottom wall (2b) of the casing (2) May be present.

  In the liquid cooling type cooling device (1) having the above-described configuration, the cooling liquid flows from the inlet pipe (9) through the cooling liquid inflow portion (12) into the first space (16) in the casing (2). , Diverts to all the coolant flow gaps between the second pin fins (15B), flows to the coolant outflow portion (13) side, joins in the second space (17), then the coolant outflow portion (13) It is sent to the outlet pipes (11) and (18). The heat generated from the heating element (P) is generated by the insulating member (I), the top wall (2a) of the casing (2), that is, the heat dissipation board (14) and the pin fins (15A) (15B) (24 ) Through the casing (2), and the heat generating body (P) is cooled.

  FIG. 5 shows a modification of the casing and the radiator.

  In FIG. 5, circular through holes (20) and (21) are formed in the left end portion of the front end and the right end portion of the rear end of the bottom wall (2b) of the casing (2), respectively. Other configurations are the same as those of the casing (2) of the above-described embodiment.

  Pin fins (15A) (15B) are provided at the height of the first pin fin (15A) existing within the range of the coolant inflow portion (12) and the coolant outflow portion (13) in the radiator (3). It is 2/3 or less and preferably 1/2 or less of the internal height of the casing (2) of the part. Therefore, a first space (16) for diverting the coolant is formed between the coolant inflow portion (12) and the tip of the first pin fin (15A), and the coolant outflow portion (13) and the first pin fin (15A) are formed. ), A second space (17) for joining the coolant is formed. Here, the first pin fin (15A) is not only within the range of the coolant inflow portion (12) and the coolant outflow portion (13), but also in the circular coolant inflow portion (12) and the coolant outflow portion (13). It is preferably provided in a circle having a diameter 1.5 times the diameter of the coolant inflow portion (12) and the coolant outflow portion (13). The heights of the second pin fins (15B) are all equal, and the tip of the second pin fins (15B) is preferably brazed to the bottom wall (2b) of the casing (2). The height of the second pin fin (15B) of the second pin fin (15B) is different from the height of the remaining second pin fin (15B) and the tip is not brazed to the bottom wall (2b) of the casing (2) May be present.

  In the casing (2) of the embodiment described above, circular through holes (7) and (8) are respectively formed at the left and right ends of the center portion in the front-rear direction of the bottom wall (2b), and as a result, the coolant inflow portion ( 12) is provided at the left end of the center part in the front-rear direction of the bottom wall (2b), and the coolant outflow part (13) is provided at the right end part of the center part in the front-rear direction of the bottom wall (2b). In the casing (2), circular through holes (20) and (21) are respectively formed in the left end portion of the front end and the right end portion of the rear end of the bottom wall (2b). 12) is provided at the left end of the front end of the bottom wall (2b), and the coolant outflow portion (13) is provided at the right end of the rear end of the bottom wall (2b). The position where (12) and the coolant outflow portion (13) are provided can be changed as appropriate so that the coolant flow in the entire casing (2) is uniform.

  In the above-described embodiment and modification, the inlet pipe (9) and the outlet pipe (11) are inserted into the circular through holes (7), (8), (20), and (21). The portion of the pipe line inserted into the circular through hole (7) of 9) becomes the cooling liquid inflow portion (12) for flowing the cooling liquid into the casing (2), and the circular through hole (11) of the outlet pipe (11) 8) The portion of the pipe inserted into the casing is a coolant outflow portion (13) through which the coolant flows out of the casing (2), but is equal in diameter to the circular through holes (7) and (9). The end faces of the inlet pipe (9) and the outlet pipe (11) having the inner diameter are arranged so that the end openings of the pipe lines of both pipes (9) and (11) are aligned with the circular through holes (7) and (8). In some cases, the bottom wall (2b) of 2) is brazed against the outer surface. In this case, the circular through holes (7) and (8) serve as the coolant inflow portion (12) and the coolant outflow portion (13).

  Further, in the embodiment described above, the heat dissipation board (14) of the radiator (3) also serves as the top wall (2a) of the casing (2), but instead, the heat dissipation board of the radiator (3). (14) and the top wall (2a) of the casing (2) may be separate, and the heat dissipation substrate (14) may be brazed to the lower surface of the top wall (2a). Further, the outer surface of the bottom wall (2b) of the top wall (2a) and the bottom wall (2b) of the casing (2) may be a heating element mounting surface (4).

  The liquid cooling type cooling device according to the present invention is suitably used for cooling a power device such as an IGBT used in a power conversion device mounted on an electric vehicle, a hybrid vehicle, a train or the like.

(1): Liquid cooling type cooling device
(2): Casing
(2a): Top wall
(2b): Bottom wall
(3): Heatsink
(4): Heating element mounting surface
(7) (8) (20) (21): Circular through hole
(9): Inlet pipe
(11): Outlet pipe
(12): Coolant inlet
(13): Coolant outflow section
(14): Heat dissipation board
(15A) (15B): Pin fin

Claims (6)

A casing having a top wall and a bottom wall, in which a coolant flows, and a radiator fixed to the casing, and one of the top wall outer surface and the bottom wall outer surface of the casing Is a heating element mounting surface, and a radiator is a heat dissipation board that receives heat generated from the heating element attached to the heating element mounting surface, and a plurality of the radiators that are integrally provided on the heat dissipation board and scattered throughout the casing. It is a liquid cooling type cooling device that consists of pin fins, and the heat generated from the heating element attached to the heating element mounting surface is dissipated to the coolant flowing in the casing through the heat dissipation board of the radiator and the pin fins,
Cooling liquid that causes the cooling liquid to flow into the casing into the wall where the inner height of the casing where the pin fins are provided is constant and the outer surface of the top and bottom walls of the casing is not the heating element mounting surface An inflow part and a cooling liquid outflow part for allowing the cooling liquid to flow out of the casing are formed so as to face a portion where the pin fins of the radiator are provided. An inlet pipe that is fed in and an outlet pipe that leads to the cooling outflow portion and sends out the cooling liquid from the casing are connected, and the pin fins present within the range of the cooling liquid inflow portion and the cooling liquid outflow portion are provided with pin fins. A liquid-cooling type cooling device that is 2/3 or less of the internal height of the casing of the part. The coolant inlet and the coolant outlet are circular, centered on the center of the coolant inlet and the coolant outlet, and have a diameter 1.5 times the diameter of the coolant inlet and the coolant outlet. 2. The liquid cooling type cooling apparatus according to claim 1, wherein the height of the pin fin located in the circle is 2/3 or less of the internal height of the casing of the portion where the pin fin is provided. The liquid cooling type cooling apparatus according to claim 1 or 2, wherein the height of the pin fins that are lowered is ½ or less of the internal height of the casing of the portion where the pin fins are provided. The liquid-cooling type cooling device according to any one of claims 1 to 3, wherein the heat radiating substrate of the radiator serves also as a wall whose outer surface is a heating element mounting surface of the top wall and the bottom wall of the casing. Two circular through holes are formed in the wall of the top and bottom walls of the casing whose outer surface is not the heating element mounting surface, and the inlet pipe is inserted into one of the circular through holes and joined to the casing. The outlet pipe is inserted into the other circular through hole and joined to the casing, and the portion of the pipe inserted into the circular through hole of the inlet pipe serves as a coolant inflow portion and is inserted into the circular through hole of the outlet pipe. The liquid cooling type cooling device according to any one of claims 1 to 4, wherein the pipe portion of the portion formed is a coolant outflow portion. The liquid tip according to any one of claims 1 to 5, wherein the tip of the pin fin not lowered is joined to the inner surface of a wall of the top wall and the bottom wall of the casing whose outer surface is not a heating element mounting surface. Cold cooling device.

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