JP7178246B2 - radiator, cooling device - Google Patents

Description

The present invention relates to radiators and cooling devices.

In recent years, a number of radiators have been developed for liquid cooling systems that cool power devices (semiconductor elements) such as IGBTs (Insulated Gate Bipolar Transistors) used in electric vehicles, hybrid vehicles, and electric trains. fin plates have been proposed.
For example, a radiator for a liquid-cooled type cooling device described in Patent Document 1 is composed of a plurality of fin plates and a connecting member that connects all the fin plates together. The fin plate is composed of a vertically rectangular flat plate-like plate body and narrow width portions integrally provided at both ends of the plate body. All fin plates are spaced apart in the thickness direction of the plate body. The connecting member has a corrugated shape including a flat plate portion integrally formed with the narrow portion of the plate body and arc-shaped portions connecting the adjacent flat plate portions alternately at both upper and lower ends. The thickness of the plate main body, the narrow width portion and the flat plate portion are equal, and both side surfaces of the plate main body, both side surfaces of the narrow width portion and both side surfaces of the flat plate portion are positioned on the same plane.

JP 2018-107365 A

In an apparatus that uses a plurality of fins to cool a heating element such as a power device, it is desirable that cooling water uniformly flows through gaps between adjacent fins so that the heating element can be evenly cooled. Therefore, it is desirable that the intervals between the fins are uniform.
SUMMARY OF THE INVENTION An object of the present invention is to provide a radiator or the like capable of making the intervals between a plurality of fins uniform with high accuracy.

The present invention completed for this purpose comprises a plurality of plate-shaped fins arranged in a direction orthogonal to the plate surface, and a plurality of protruding portions protruding outward from each of the plurality of fins. 2. In the heat radiator, the end portions of the plurality of fins of adjacent protrusions of the plurality of protrusions are in contact with each other.
Here, the fin may be rectangular, and the protruding portion may protrude outward from an end portion of the fin in the longitudinal direction.
Further, the protruding portion may have a plate shape in which the direction in which the plurality of fins are arranged is parallel to the plate surface.
Further, the one-side end of the protrusion in the alignment direction has a one-side parallel portion parallel to the plate surface of the fin and a convex portion protruding from the one-side parallel portion, and the other end of the protrusion has a parallel portion on the other side parallel to the plate surface of the fin and a recess recessed from the parallel portion on the other side, and the parallel portion on the one side and the parallel portion on the other side of the adjacent protrusions are in contact with each other The convex portion and the concave portion may be fitted to each other in this state.
Further, the fin may be rectangular, and the protruding portion may be provided at a central portion of the fin in the width direction.
Alternatively, the fin may be rectangular, and the projecting portion may be provided at one end of the fin in the width direction.
Adjacent protruding portions may be joined by welding or adhesion.
From another point of view, the present invention provides a plurality of plate-like rectangular fins arranged in a direction orthogonal to the plate surface, and a plurality of fins protruding outward from the ends in the longitudinal direction of each of the plurality of fins. a plurality of projecting portions, wherein adjacent projecting portions among the plurality of projecting portions are joined to each other by welding or adhesion.
Viewed from another point of view, the present invention is a cooling device comprising the radiator described above, and a case that houses the radiator and in which a cooling liquid flows between the plurality of fins of the radiator. .

ADVANTAGE OF THE INVENTION According to this invention, the radiator etc. which can make the space|interval of several fins uniform with high precision can be provided.

1 is a perspective view of a liquid-cooled cooling device according to a first embodiment; FIG. FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1; FIG. 3 is a cross-sectional view taken along line III-III of FIG. 2; It is a figure for demonstrating the manufacturing method of a radiator. It is a figure for demonstrating the manufacturing method of a radiator. It is a perspective view which shows a mode that protrusion parts are welded by laser welding. It is an enlarged view of a bending piece. It is a figure which shows the modification of a protrusion part. FIG. 5 is a schematic configuration diagram of a radiator according to a second embodiment; It is a figure which shows the state which joined the radiator and the cover. FIG. 11 is a schematic configuration diagram of a radiator according to a third embodiment; FIG. 11 is a schematic configuration diagram of a radiator according to a fourth embodiment; FIG. 11 is a schematic configuration diagram of a radiator according to a fifth embodiment; FIG. 11 is a schematic configuration diagram of a radiator according to a sixth embodiment;

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.
<First embodiment>
FIG. 1 is a perspective view of a liquid cooling system 1 according to the first embodiment.
FIG. 2 is a cross-sectional view taken along line II--II in FIG.
FIG. 3 is a sectional view taken along line III--III in FIG.
A liquid-cooled cooling device 1 according to an embodiment includes a radiator 10 having a plurality of rectangular fins 11 and a case 20 that houses the radiator 10 . The liquid-cooled type cooling device 1 also includes an inlet joint 30 that allows coolant to flow from the outside of the case 20 to the inside, and an outlet joint 40 that allows the coolant to flow from the inside of the case 20 to the outside. Hereinafter, the longitudinal direction of the rectangular fins 11 may be referred to as the lateral direction, the lateral direction of the fins 11 may be referred to as the vertical direction, and the alignment direction of the plurality of fins 11 may be referred to as the front-rear direction.

The liquid-cooling type cooling device 1 has a heating element P mounted on the outer surface (upper surface in this embodiment) of the case 20 via a flat insulating member I, and a cooling liquid and a heat radiation for circulating the inside of the case 20. It is an apparatus for cooling using a vessel 10 . The heating element P can be exemplified by a power semiconductor device such as an insulated gate bipolar transistor (IGBT). Also, the heating element P is an IGBT module in which an IGBT and a control circuit for controlling the IGBT are packaged, or an intelligent power module in which the IGBT module and a self-protection function are packaged. can be done.

(Case 20)
The case 20 includes a case body 21 to which the heating element P is mounted via an insulating member I, and a cover 22 that covers the opening of the case body 21 .
The case body 21 includes a flat plate-shaped top portion 21a, side portions 21b protruding in a direction (downward) perpendicular to the top portion 21a from each end of the top portion 21a, and perpendicular to the side portions 21b from each end of the side portion 21b. and a flange portion 21c protruding outward in the direction. A heating element P is attached via an insulating member I to the central portion of the surface (upper surface) of the top portion 21a opposite to the side on which the side portion 21b is provided. Further, in the top portion 21a, an entrance through hole 21d penetrated so as to communicate between the inside and the outside of the case 20 is provided outside the portion where the insulating member I and the heat generating element P are arranged in the horizontal direction. An outlet through hole 21e is formed.

The cover 22 is flat and rectangular, and is larger than the flange portion 21 c of the case body 21 . Four corners of the cover 22 are formed with through holes 221 through which bolts or the like for attaching the liquid cooling system 1 to other members are passed.

The case 20 is configured in a box shape so that the radiator 10 can be accommodated therein by brazing the flange portion 21c of the case body 21 and the cover 22 together. Case body 21 and cover 22 can be exemplified by being formed using an aluminum brazing sheet. In this case, at least one surface facing each other is provided with a brazing filler metal layer.
By brazing the case main body 21 and the cover 22 together, an inflow-side space 23 is formed below the inlet through-hole 21d in the case 20, and is above the outlet through-hole 21e in the case 20. An outflow side space 24 is formed below.

(Inlet joint 30)
The inlet joint 30 has a cylindrical portion 31 and a rectangular parallelepiped portion 32, and has a hollow interior so that the cooling liquid can flow. One end (right end) of the cylindrical portion 31 is open, and the other end is connected to the rectangular parallelepiped portion 32 . A through hole 33 is formed on one surface (lower surface) of the rectangular parallelepiped portion 32 to communicate the inside and the outside of the inlet joint 30 . The inlet joint 30 is brazed to the case main body 21 in a state in which the surface on which the through hole 33 is formed is placed on the surface (upper surface) of the top portion 21a of the case main body 21 on which the heating element P is mounted. At this time, the inside of the inlet joint 30 and the inside of the case main body 21 communicate with each other through the through hole 33 of the inlet joint 30 and the inlet through hole 21 d of the case main body 21 .

(Exit joint 40)
The outlet joint 40 has a cylindrical portion 41 and a rectangular parallelepiped portion 42, and has a hollow interior so that the cooling liquid can flow. One end (left end) of the cylindrical portion 41 is open, and the other end is connected to the rectangular parallelepiped portion 42 . One surface (lower surface) of the rectangular parallelepiped portion 42 is formed with a through hole 43 that communicates the inside and the outside of the outlet joint 40 . The outlet joint 40 is brazed to the case main body 21 in a state in which the surface in which the through hole 43 is formed is placed on the surface (upper surface) of the top portion 21a of the case main body 21 on which the heating element P is mounted. At this time, the inside of the outlet joint 40 and the inside of the case main body 21 are communicated with each other through the through hole 43 of the outlet joint 40 and the through hole 21e for outlet of the case main body 21 .

(Radiator 10)
The radiator 10 has a plate shape and includes a plurality of fins 11 arranged in a direction orthogonal to the plate surface, a plurality of projecting portions 12 provided on the outside of each of the plurality of fins 11, and the fins 11 and the projecting portions 12. and a connecting portion 13 for connecting the

The fins 11 have a rectangular shape and are arranged so that the lateral direction of the fins 11 is the vertical direction shown in FIG. 1 and the longitudinal direction of the fins 11 is the lateral direction shown in FIG. Further, the plurality of fins 11 are arranged at predetermined intervals (hereinafter sometimes referred to as “predetermined intervals”) in a direction perpendicular to the surfaces of the fins 11 . The plurality of fins 11 are arranged so that the alignment direction is the front-rear direction shown in FIG.

The protruding portion 12 has a left protruding portion 12l and a right protruding portion 12r that protrude outward from both ends of the fin 11 in the longitudinal direction. The left protruding portion 12l and the right protruding portion 12r are symmetrical. Below, the left protruding portion 12l will be described as a representative. Also, the left protruding portion 12l and the right protruding portion 12r may be collectively referred to as the protruding portion 12 in some cases.

The projecting portion 12 has a plate shape in which the direction in which the plurality of fins 11 are arranged (the front-rear direction) is parallel to the plate surface. An end portion 121 on one side in the alignment direction of the protruding portion 12 has a one-side parallel portion 121a parallel to the plate surface of the fin 11 and a convex portion 121b protruding from the one-side parallel portion 121a. Further, the end portion 122 on the other side in the alignment direction of the projecting portion 12 has a parallel portion 122a on the other side parallel to the plate surface of the fin 11 and a recessed portion 122b recessed from the parallel portion 122a on the other side. As shown in FIG. 3B, the convex portion 121b and the concave portion 122b are formed in a semicircular shape.

Among the plurality of projecting portions 12 provided on each of the plurality of fins 11, the ends of the adjacent projecting portions 12 in the direction in which the fins 11 are arranged are in contact with each other. That is, the one-side parallel portion 121a of one protrusion 12 and the other-side parallel portion 122a of the protrusion 12 arranged on the front side of the one protrusion 12 are in contact with each other. In addition, the other side parallel portion 122a of one protrusion 12 and the one side parallel portion 121a of the protrusion 12 arranged on the rear side of the one protrusion 12 are in contact with each other.

Therefore, the distance between one fin 11 and the fins 11 arranged in front and behind this one fin 11 is the direction in which the fins 11 are arranged ( front-back direction). When the sizes of the plurality of projecting portions 12 are uniform, the intervals between the plurality of fins 11 are uniform.
In the radiator 10 according to the present embodiment, the protruding portions 12 are formed by press-cutting as will be described later. They are designed to be evenly spaced.
Moreover, in the radiator 10, the convex portion 121b and the concave portion 122b are fitted in a state in which the one-side parallel portion 121a and the other-side parallel portion 122a of the adjacent projecting portions 12 are in contact with each other. Thereby, the plurality of fins 11 are less likely to be displaced from each other in the longitudinal direction (horizontal direction) of the fins 11 .
The protruding portion 12 is provided at substantially the central portion of the fin 11 in the lateral direction in the vertical direction.

The connecting portion 13 is L-shaped and has a first connecting portion 131 connected to the fin 11 and a second connecting portion 132 connected to the projecting portion 12 . The first connecting portion 131 is connected to a substantially central portion of the fin 11 in the lateral direction. The second connecting portion 132 is bent at 90 degrees. As a result, the surface of the fin 11 and the surface of the projecting portion 12 form an angle of 90 degrees.

In addition, the material of the radiator 10 can be exemplified by an aluminum material such as aluminum or an aluminum alloy. Moreover, the material of the radiator 10 may be copper, aluminum, or a composite material of an aluminum alloy and carbon. Alternatively, the fins 11 may be made of an aluminum-carbon composite material, and the projecting portions 12 and the connecting portions 13 may be made of an aluminum material.
Also, the plate thickness of the radiator 10 can be exemplified as 0.3 to 1.2 mm. It is appropriately changed according to the size of the entire liquid cooling system 1 , the type of cooling liquid flowing through the case 20 , or the thermal conductivity of the fins 11 .

The radiator 10 has the upper ends of the plurality of fins 11 brazed to the surface (lower surface) of the top portion 21a of the case body 21 opposite to the surface on which the heating element P is mounted, and the lower ends of the plurality of fins 11 are brazed to the upper surface of the cover 22 to be fixed in the case 20 . When performing brazing, all of the brazing between the upper ends of the plurality of fins 11 and the case body 21, the brazing between the lower ends of the plurality of fins 11 and the cover 22, and the brazing between the case body 21 and the cover 22 are performed. Simultaneous execution can be exemplified.

In the liquid-cooled cooling device 1 configured as described above, the cooling liquid flows into the inflow-side space 23 in the case 20 through the interior of the inlet joint 30 and the inlet through-hole 21d. Then, it flows leftward in the inter-fin flow path 14 formed in the gaps between the fins 11 adjacent to each other among the plurality of fins 11 in the radiator 10 and reaches the outflow side space 24 . In addition, the front flow path 15 formed between the frontmost fin 11 in the radiator 10 and the side portion 21b of the case body 21, and the rearmost fin 11 in the radiator 10 and the case body 21 side It flows leftward through the rear channel 16 formed in the gap between the part 21 b and reaches the outflow space 24 . The coolant that has reached the outflow-side space 24 flows out of the case 20 through the outlet through-hole 21 e and the outlet joint 40 .

Then, the heat generated from the heating element P passes through the insulating member I, the top portion 21a of the case body 21, and the fins 11 of the radiator 10, the inter-fin flow path 14, the front flow path 15, and the rear flow path. The heat is dissipated by the coolant flowing through the passage 16 . Thereby, the heating element P is cooled.

(Manufacturing method of radiator 10)
4 and 5 are diagrams for explaining the manufacturing method of the radiator 10. FIG.
In the manufacturing method according to the present embodiment, the one fin 11, the projecting portion 12 and the connecting portion 13 projecting outward from the one fin 11, the other fin 11 adjacent to the one fin 11, and other A bending piece 17 connecting the projecting portion 12 projecting outward from the fin 11 and the connecting portion 13 is once formed. The bending piece 17 has both ends connected to adjacent protruding portions 12 and has a bending portion 171 bent in the central portion.
After that, by cutting the bent pieces 17, the radiator 10 composed of the plurality of fins 11, the projecting portions 12, and the connecting portions 13 is taken out.

More specifically, as shown in FIG. 4, first, a plate material M made of an aluminum material is press-worked to punch out a plurality of fins 11, projecting portions 12, and connecting portions 13 and their surroundings (first step). . At that time, the rectangular shape is punched so that the longitudinal direction of the fins 11 is the lateral direction of the plate material M, and the lateral direction of the fins 11 is the longitudinal direction of the plate material M. For example, when the thickness of the plate material M is 0.3 to 1.2 mm, the width of the fins 11 in the lateral direction is 3 to 12 mm. In addition, in FIG. 4 , in the first step, three fins 11 , protrusions 12 , and connecting portions 13 are punched out, but the number of punches is not particularly limited to three.

Further, by subjecting the plate material M to press working, the portion inside the bending piece 17, in other words, the portion between the bending piece 17 and the projecting portion 12 is punched out (second step). In addition, in FIG. 4, in the second step, the inner sides of at least two bent pieces 17 provided between the three projecting portions 12 produced in the first step are punched out. In this manner, in the second step, it is preferable to set the punching range according to the number of protrusions 12 formed in the first step.
The order of the first step and the second step and the timing of the first step and the second step are not particularly limited.

After that, the fins 11 are rotated so that the angles of the surfaces of the fins 11 formed in the first step intersect the plate surface of the plate material M (third step). In the third step, the end portion of the second connection portion 132 of the connection portion 13 on the side of the protrusion 12 is bent with respect to the protrusion 12 so that the fin 11 and the portion of the connection portion 13 on the side of the fin 11 ( The first connecting portion 131 ) is rotated so as to form an angle that intersects the plate surface of the plate material M, in other words, the projecting portion 12 . At this time, it is preferable to bend the end of the second connection portion 132 of the connection portion 13 on the side of the protrusion 12 while pressing the protrusion 12 . Since it is not necessary to apply force to the fin 11 according to this, deformation|transformation of the fin 11 is suppressed. In this embodiment, the fins 11 may be rotated by 90 degrees with respect to the plate material M, for example.
The order of the second step and the third step and the timing of the second step and the third step are not particularly limited.

After that, the portion outside the bending piece 17 is punched out by performing press working on the plate material M (fourth step). As a result, the plurality of fins 11, the plurality of projecting portions 12, the plurality of connecting portions 13, and the plurality of bending pieces 17 are punched out.

After that, the bent portions 171 of the bent pieces 17 are further bent to bring the adjacent projecting portions 12 into contact with each other (fifth step). In the fifth step, the one-side parallel portion 121a of one protrusion 12 and the other-side parallel portion 122a of the protrusion 12 arranged on the front side of the one protrusion 12 are brought into contact (FIG. 3B). reference). Also, the other side parallel portion 122a of one protrusion 12 and the one side parallel portion 121a of the protrusion 12 arranged on the rear side of the one protrusion 12 are brought into contact (see FIG. 3B). At this time, the bent portion 171 is bent so that the convex portion 121b and the concave portion 122b are fitted to each other while the one-side parallel portion 121a and the other-side parallel portion 122a are in contact with each other. By this fifth step, the gap between the adjacent fins 11 is reduced, and the gap is reduced to a predetermined size (the size between the parallel portion 121a on one side and the parallel portion 122a on the other side of the projecting portion 12). Become.
In the fifth step, by applying a force to the projection 12 in a direction parallel to the surface of the projection 12 (a direction perpendicular to the surface of the fin 11), the bending portion 171 of the bending piece 17 is bent. good. Accordingly, since it is not necessary to apply force to the fins 11, deformation of the fins 11 is suppressed.

After that, when the number of fins 11 spaced apart by a predetermined distance reaches a predetermined number (hereinafter sometimes referred to as "predetermined number"), the predetermined number of fins 11 and the predetermined number of fins The projecting portion 12, the connecting portion 13 and the bending piece 17 projecting from 11 are cut off (sixth step). When separating, the bending piece that connects the protruding portion 12 and the connecting portion 13 protruding from the predetermined number of fins 11 and the protruding portion 12 and the connecting portion 13 that protrude from the (predetermined number of +1) fins 11 Cut 17. The location where the bending piece 17 is cut is not particularly limited, but for example, the connecting location between the bending piece 17 and the projecting portion 12 and the bending portion 171 can be exemplified.

After that, the protruding portions 12 are welded or adhered to join each other while the adjacent protruding portions 12 are in contact with each other (seventh step). As a method for bonding the protruding portions 12 to each other, applying an adhesive to the protruding portions 12 can be exemplified. As a technique for welding the protruding portions 12 together, laser welding or ultrasonic welding can be exemplified for the protruding portions 12 .

After joining the protrusions 12 together in the seventh step, the bent piece 17 is cut (eighth step). In the eighth step, while pressing the projecting portion 12, the tip of the bending piece 17 is bent upward or downward with respect to the projecting portion 12 (by applying a force in the lateral direction of the fin 11). ) to break the connecting portion between the bending piece 17 and the projecting portion 12 .

FIG. 6 is a perspective view showing how the projections 12 are welded together by laser welding.
As shown in FIG. 6, a laser beam L from a laser head 151 of a laser device 150 is directed toward a portion where a convex portion 121b and a concave portion 122b are fitted to each other among the portions where the adjacent protrusions 12 are in contact with each other. to irradiate. Then, by moving the laser head 151 in the direction in which the plurality of fins 11 are arranged (the direction in which the plurality of protrusions 12 are arranged), in other words, in a direction perpendicular to the surface of the fins 11, the laser beam L is continuously emitted. do.
Note that the laser source of the laser device 150 is not particularly limited. YAG lasers, _CO2 lasers, fiber lasers, disk lasers, semiconductor lasers can be exemplified. Moreover, the irradiation direction of the laser light L may be a direction perpendicular to the surface of the projecting portion 12 or a direction inclined with respect to the perpendicular direction.

According to the radiator 10 manufactured using the manufacturing method described above, the intervals between the plurality of fins 11 can be made uniform. That is, the size between the one side parallel portion 121a and the other side parallel portion 122a of the projecting portion 12 projecting outward from one fin 11 determines the gap between the adjacent fins 11, and this projecting portion The shape of 12 is formed by punching by press working. In addition, the dimensions in the case of forming by punching by press work are more likely to be the desired size (dimensions in the design drawing) than the dimensions in the case of forming by plastic deformation by bending, for example. Therefore, according to the radiator 10 manufactured using the manufacturing method described above, the intervals between the plurality of fins 11 can be made uniform.

Further, according to the manufacturing method described above, the interval between the fins 11 is determined by bending the bent portions 171 of the bent pieces 17 to bring the adjacent projecting portions 12 into contact with each other. In other words, the distance between the fins 11 is determined by applying a force parallel to the surfaces of the protrusions 12 to the protrusions 12 and striking the adjacent protrusions 12 . Therefore, it is possible to easily determine the spacing between the fins 11 .

Further, when performing the seventh step of welding or bonding the protruding portions 12 to each other, a force in a direction parallel to the surfaces of the protruding portions 12 is applied to the protruding portions 12 so that the plurality of fins 11 are separated by a predetermined distance. Since it is possible to maintain (restrict) them in a state in which they are arranged side by side, it is possible to join them at a predetermined interval with high accuracy.

In addition, since the protrusions 121b and the recesses 122b of the adjacent protrusions 12 are formed so as to fit together, force is applied to the protrusions 12 so as to bring the protrusions 12 into contact with each other, and the surfaces of the protrusions 12 are pressed. Even if the fins 11 are pushed in a parallel direction, the fins 11 are prevented from slipping in the longitudinal direction. Therefore, it becomes easier for the plurality of fins 11 to line up straight.

FIG. 7 is an enlarged view of the bending piece 17. FIG.
A notch 172 recessed from the inner surface is preferably formed in the bent portion 171 of the bent piece 17 . This makes it easier to bend the bent portion 171 and bring the adjacent projecting portions 12 into contact with each other. In addition, it is preferable to form a notch 173 recessed from the inner surface at each of both ends of the bending piece 17 at a connecting portion with the protruding portion 12 . This makes it possible to easily separate the bending piece 17 from the projecting portion 12 .

(Action and effect of radiator 10)
According to the radiator 10 manufactured using the manufacturing method described above, it is highly possible that the intervals between the plurality of fins 11 are uniform. That is, according to the shape of the heat sink 10, the distance between the fins 11 is determined by bringing the protruding portions 12 formed by punching out by pressing into contact with each other, so that the distance between the plurality of fins 11 becomes uniform. easy. As a result, according to the heat radiator 10, the heat generated from the heating element P is uniformly radiated, and the heating element P is uniformly cooled.

Moreover, in the radiator 10, the projecting portion 12 prevents the flow of the cooling liquid from the inflow side space 23 to the outflow side space 24 through the inter-fin flow path 14, the front side flow path 15, and the rear side flow path 16. However, the size of the protrusion 12 in the width direction of the fins 11 is the same as the thickness of the plate material M (for example, 0.3 to 1.2 mm), and the width direction of the fins 11 Since it is considerably smaller than the size (approximately 10% as an example), it is less likely to get in the way.

(Modified example of manufacturing method of radiator 10)
In the manufacturing method described with reference to FIGS. 4 and 5, the projecting portion 12 and the connecting portion 13 projecting outward from one fin 11 and the connecting portion 13 projecting outward from the other fin 11 next to this one fin 11 A bending piece 17 that connects the protruding portion 12 and the connecting portion 13 is once formed, and the adjacent protruding portions 12 are joined together and then cut. However, the method for manufacturing the radiator 10 is not limited to such an aspect. For example, by press-working the plate material M, the periphery of the fins 11, the protrusions 12, and the connection portions 13 is punched out, and the angle of the surface of the fins 11 intersects the surface of the protrusions 12 (for example, 90 degrees). ) to form a single fin member (not shown) composed of one fin 11 , the protrusion 12 and the connecting portion 13 . After that, a plurality of single fin members may be combined so that the adjacent protrusions 12 are in contact with each other, and then the protrusions 12 may be joined by welding or bonding.
Even in the radiator 10 manufactured in this manner, the distance between the fins 11 is determined by bringing the protruding portions 12 formed by punching out by press work into contact with each other, so the distance between the plurality of fins 11 is determined. tends to be uniform. As a result, according to the heat radiator 10, the heat generated from the heating element P is uniformly radiated, and the heating element P is uniformly cooled.

(Modified example of protrusion 12)
FIG. 8 is a diagram showing a modified example of the projecting portion 12. As shown in FIG.
The protrusion 12 described above has a protrusion 121b on one end 121 and a recess 122b on the other end 122. As shown in FIG. It does not have to be. Even with such a configuration, the spacing between the fins 11 is determined by bringing the protrusions 12 formed by punching out by press working into contact with each other, so the spacing between the plurality of fins 11 tends to be uniform.

<Second embodiment>
FIG. 9 is a schematic configuration diagram of a radiator 200 according to the second embodiment.
A radiator 200 according to the second embodiment differs from the radiator 10 according to the first embodiment in a projecting portion 212 corresponding to the projecting portion 12 . Differences from the radiator 10 will be described below. Components having the same functions in the second embodiment and the first embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.

A radiator 200 according to the second embodiment includes a plurality of fins 211, a plurality of projecting portions 212 provided outside the plurality of fins 211, and connecting portions 213 connecting the fins 211 and the projecting portions 212. and
The projecting portion 212 differs in position with respect to the fins 211 from the projecting portion 12 of the radiator 10 according to the first embodiment. The projecting portion 212 is provided at the lowest end portion of the fin 211 in the width direction. Also, the lower surface of the projecting portion 212 and the lower end surface of the fin 211 are provided so as to be flush with each other.

The connecting portion 213 is L-shaped and has a first connecting portion 231 connected to the fin 211 and a second connecting portion 232 connected to the projecting portion 212 . The first connecting portion 231 is connected to the longitudinal end of the fin 211 and is bent 90 degrees. The second connecting portion 232 is provided so as to be on the same plane as the projecting portion 12 .

In addition, because the connecting portion 213 is connected to the longitudinal end portion of the fin 211 and bent at 90 degrees, a notch 211a is formed around the portion of the fin 211 to which the connecting portion 213 is connected. formed. As a result, the side of the connecting portion 213 connected to the fins 211 can be easily bent with respect to the protruding portion 212, and the surface of the fins 211 and the surface of the protruding portion 212 can be easily molded so as to form an angle of 90 degrees.

In the radiator 200 configured in this manner, the distance between the fins 211 is determined by bringing the protruding portions 212 formed by punching out by pressing into contact with each other, so that the distance between the plurality of fins 211 is uniform. easy. As a result, according to the radiator 200, the heat generated from the heating element P is uniformly radiated, and the heating element P is uniformly cooled.
Moreover, in the radiator 200, the projecting portion 212 is provided at the lowermost end portion of the fins 211 in the lateral direction, so that the flow of the cooling liquid from the inflow side space 23 to the outflow side space 24 is not easily obstructed. .

As with the radiator 10 according to the first embodiment, the radiator 200 has the upper ends of the plurality of fins 211 brazed to the top portion 21a of the case body 21, and the lower ends of the plurality of fins 211 are brazed to the upper surface of the cover 22. It is fixed in the case 20 by brazing. Also, as described above, the timing of brazing the plurality of fins 211 and the case body 21, brazing the plurality of fins 211 and the cover 22, and brazing the case body 21 and the cover 22 is not particularly limited. .

FIG. 10 is a diagram showing a state in which the radiator 200 and the cover 22 are joined together.
In radiator 200, projecting portion 212 is provided at the lowermost end portion of fin 211 in the lateral direction, and the lower surface of projecting portion 212 and the lower end surface of fin 211 are at the same height. Therefore, when brazing the plurality of fins 211 and the cover 22 together, the lower surface of the projecting portion 212 and the cover 22 are welded. Therefore, according to the radiator 200, by welding or bonding the radiator 200 and the cover 22 together, the positions of the radiator 200 and the cover 22 are determined with high accuracy.
Note that the method of joining the radiator 200 and the cover 22 is not limited to brazing. For example, crimping, adhesion, and welding other than brazing may be used.

<Third Embodiment>
FIG. 11 is a schematic configuration diagram of a radiator 300 according to the third embodiment.
A radiator 300 according to the third embodiment differs from the radiator 200 according to the second embodiment in a connecting portion 313 corresponding to the connecting portion 213 . Differences from the radiator 200 will be described below. Elements having the same functions in the third embodiment and the second embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.

A radiator 300 according to the third embodiment includes a plurality of fins 311, a plurality of projecting portions 312 provided outside the plurality of fins 311, and connecting portions 313 connecting the fins 311 and the projecting portions 312. and
As with the projecting portion 212 of the heat sink 200 according to the second embodiment, the connecting portion 313 is arranged in the lateral direction of the fin 211 so that the lower surface of the projecting portion 312 and the lower end surface of the fin 311 are at the same height. Located at the bottom end. In addition, the connection portion 313 includes a first connection portion 331 connected to a portion of the fin 311 in the lateral direction and a second connection portion 331 connected to the projecting portion 312 in the same manner as the connection portion 13 of the radiator 10 according to the first embodiment. It is L-shaped with two connections 332 . The second connecting portion 332 is bent at 90 degrees. As a result, the surface of the fin 311 and the surface of the projecting portion 312 form an angle of 90 degrees.

In the heat sink 300 configured in this way, the distance between the fins 311 is determined by bringing the projections 312 formed by punching out by pressing into contact with each other, so that the distance between the fins 311 becomes uniform. easy. As a result, according to the radiator 300, the heat generated from the heating element P is uniformly radiated, and the heating element P is uniformly cooled.
Moreover, in the radiator 300, the protruding portion 312 is provided at the lowermost end portion of the fin 311 in the lateral direction, so that the flow of the cooling liquid from the inflow side space 23 to the outflow side space 24 is not easily obstructed. .
Further, by welding or bonding the radiator 300 and the cover 22 together, the positions of the radiator 300 and the cover 22 can be determined with high accuracy.

<Fourth Embodiment>
In the radiator 10 according to the first embodiment, the radiator 200 according to the second embodiment, and the radiator 300 according to the third embodiment, the semicircular convex portion A semicircular recess 122b is formed at the end 122 on the other side of 121b. By fitting the convex portion 121b and the concave portion 122b together, displacement of the fins 11, 211, and 311 in the longitudinal direction is suppressed. However, the shape of the convex portion 121b and the concave portion 122b is not limited to the semicircular shape.

FIG. 12 is a schematic configuration diagram of a radiator 400 according to the fourth embodiment.
A radiator 400 according to the fourth embodiment differs from the radiator 200 according to the second embodiment in a projecting portion 412 corresponding to the projecting portion 212 . Differences from the radiator 200 will be described below.

A radiator 400 according to the fourth embodiment includes a plurality of fins 411, a plurality of projecting portions 412 provided on the outside of each of the plurality of fins 411, and connecting portions 413 connecting the fins 411 and the projecting portions 412. and The fins 411 and the connection portion 413 are the same as the fins 211 and the connection portion 213 according to the second embodiment, respectively, so detailed description thereof will be omitted.

An end portion 421 on one side in the alignment direction of the protruding portion 412 has a one-side parallel portion 421a parallel to the plate surface of the fin 411 and a convex portion 421b protruding from the one-side parallel portion 421a. Further, the end portion 422 on the other side in the alignment direction of the projecting portion 412 has a parallel portion 422a on the other side parallel to the plate surface of the fin 411 and a recessed portion 422b recessed from the parallel portion 422a on the other side. The convex portion 421b protrudes in a quarter arc shape, and the concave portion 422b is recessed in a quarter arc shape.

In the projecting portion 412 configured as described above, the one-side parallel portion 421a of one projecting portion 412 and the other-side parallel portion 422a of the projecting portion 412 arranged on the front side of the one projecting portion 412 come into contact with each other. is doing. Also, the other side parallel portion 422a of one protrusion 412 and the one side parallel portion 421a of the protrusion 412 arranged on the rear side of the one protrusion 412 are in contact with each other. When the sizes of the plurality of projecting portions 412 are uniform, the intervals between the plurality of fins 211 are uniform.

Moreover, in the radiator 400, the convex portion 421b and the concave portion 422b are fitted in a state in which the one-side parallel portion 421a and the other-side parallel portion 422a of the adjacent protrusions 412 are in contact with each other. This structure is bilaterally symmetrical with the left protruding portion 12l and the right protruding portion 12r protruding outward from both ends of the fin 211 in the longitudinal direction. Therefore, the recesses 422b of the projecting portion 412 protruding from both the left and right ends of the one fin 411 correspond to the protrusions of the projecting portion 412 projecting from the left and right ends of the fin 411 arranged behind the one fin 11, respectively. It is pushed inward from the portion 421b. As a result, the plurality of fins 411 are less likely to be displaced from each other in the longitudinal direction (horizontal direction) of the fins 411 .

The radiator 400 configured in this manner can be manufactured by the manufacturing method described with reference to FIGS. Further, after forming a single fin member (not shown) composed of one fin 411, a protrusion 412 and a connection portion 413, a plurality of single fin members are brought into contact with adjacent protrusions 412, After combining the protrusions 421b and the recesses 422b so that they fit together, the protrusions 412 may be joined by welding or bonding.

The connecting portion 413 of the radiator 400 may be configured similarly to the connecting portion 13 according to the first embodiment and the connecting portion 313 according to the third embodiment. Further, similarly to the projecting portion 12 according to the first embodiment, the projecting portion 412 may be provided substantially in the central portion of the fin 411 in the width direction.

<Fifth Embodiment>
FIG. 13 is a schematic configuration diagram of a radiator 500 according to the fifth embodiment.
A radiator 500 according to the fifth embodiment differs from the radiator 200 according to the second embodiment in fins 511 corresponding to the fins 211 . Differences from the radiator 200 will be described below. In the fifth embodiment and the second embodiment, items having the same functions are denoted by the same reference numerals, and detailed description thereof will be omitted.

The fins 211 according to the second embodiment are linear in the longitudinal direction, but the fins 511 according to the fifth embodiment have peaks and valleys that are continuous in the longitudinal direction when viewed in the vertical direction. (It is similar to the fin 211 that it is rectangular when viewed in the front-rear direction). In this way, the corrugated fins 511 have a larger surface area than straight fins, so that the heating element P can be cooled more.
In the manufacturing method described with reference to FIGS. 4 and 5, by providing the step of forming the fins 511 in a wave shape after the first step or after the second step, the wave shape can be formed with high accuracy. It becomes possible.
Further, the fins 11 according to the first embodiment, the fins 311 according to the third embodiment, and the fins 411 according to the fourth embodiment may also be wave-shaped like the fins 511 .

<Sixth embodiment>
FIG. 14 is a schematic configuration diagram of a radiator 600 according to the sixth embodiment.
A radiator 600 according to the sixth embodiment differs from the radiator 200 according to the second embodiment in fins 611 corresponding to the fins 211 . Differences from the radiator 200 will be described below. In the sixth embodiment and the second embodiment, items having the same functions are denoted by the same reference numerals, and detailed description thereof will be omitted.

A fin 611 according to the sixth embodiment has a bar-shaped base portion 611a extending in the left-right direction and a plurality of columnar portions 611b projecting upward from the base portion 611a. The plurality of columnar portions 611b are arranged at predetermined intervals in the left-right direction. The columnar portion 611b has a rhombic shape when viewed in the vertical direction, and the short diagonal length of the rhombus is greater than the thickness of the base portion 611a and, in turn, the thickness of the plate material M. Further, the short diagonals of the columnar portions 611b provided on the fins 611 adjacent to each other among the plurality of fins 611 are shifted in the horizontal direction. For example, the columnar portion 611b of the other fin 611 adjacent to the one fin 611 is arranged between the adjacent columnar portions 611b of the one fin 611 . The length of the short diagonal line of the rhombus of the columnar portion 611b may be the same as the plate thickness of the plate material M.
Since the fins 611 have a plurality of rhombic columnar portions 611b, the coolant flowing between the fins 611 evenly contacts the columnar portions 611b, so that the heating element P can be further cooled.

In the manufacturing method described with reference to FIGS. 4 and 5, by providing the step of forming the plurality of columnar portions 611b on the fin 611 after the first step or after the second step, the columnar portions 611b can be manufactured with high accuracy. can be molded.
The fins 11 according to the first embodiment, the fins 311 according to the third embodiment, and the fins 411 according to the fourth embodiment may also have a plurality of columnar portions 611b like the fins 611. FIG.

REFERENCE SIGNS LIST 1 Liquid-cooled cooling device 10, 200, 300, 400, 500, 600 Radiator 11, 211, 311, 411, 511, 611 Fin 12, 212, 312, 412 Protrusion 13, Reference numerals 213, 313, 413: connecting part 20: case 30: inlet joint 40: outlet joint P: heating element I: insulating member

Claims (7)

a plurality of plate-shaped fins arranged in a direction orthogonal to the plate surface;
a plurality of projections projecting outward from each of the plurality of fins;
with
Among the plurality of protrusions, the ends of the plurality of fins in adjacent protrusions are in contact with each other,
The fins are rectangular,
The protruding portion protrudes outward in the longitudinal direction from an end portion in the longitudinal direction of the fin,
The projecting portion has a plate shape in which the direction in which the plurality of fins are arranged is parallel to the plate surface,
radiator. One end of the protruding portion in the alignment direction has a one-side parallel portion parallel to the plate surface of the fin and a convex portion protruding from the one-side parallel portion, and the other end has: having a parallel portion on the other side parallel to the plate surface of the fin and a concave portion recessed from the parallel portion on the other side;
2. The radiator according to claim 1 , wherein said convex portion and said concave portion are fitted to each other with said one side parallel portion and said other side parallel portion of said adjacent projecting portions being in contact with each other. 3. The heat radiator according to claim 1 , wherein the protruding portion is provided in a central portion of the fin in the width direction. 3. The radiator according to claim 1 , wherein the projecting portion is provided at one end of the fin in the lateral direction. 5. The radiator according to any one of claims 1 to 4 , wherein adjacent protrusions are joined by welding or adhesion. a plurality of plate-like rectangular fins arranged in a direction orthogonal to the plate surface;
a plurality of protrusions protruding outward in the longitudinal direction from the longitudinal end of each of the plurality of fins;
with
the protruding portion has a plate shape in which the direction in which the plurality of fins are arranged is parallel to the plate surface;
Adjacent protrusions among the plurality of protrusions are welded or bonded to each other. A radiator according to any one of claims 1 to 6 ;
a case that accommodates the radiator and allows coolant to flow between the plurality of fins of the radiator;
cooling device.

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