JP3140755U - Corrugated fin type radiator - Google Patents

Abstract

A corrugated fin type heat radiator capable of improving heat radiation efficiency is provided.
A corrugated fin type radiator 1 is formed of a corrugated fin 10 for radiating heat and a side wall portion 24 and a bottom portion 25 for fixing a part of the corrugated fin 10 (fin fixing portion). And a support substrate 20 having a plurality of fixing grooves 23 formed thereon. The bottom portion 25 has a flange portion 26 formed at least partially in parallel with the bottom portion 25 and having a height higher than that of the bottom portion 25, and the side wall portion 24 stands upright in a vertical direction from the support substrate 20. It is formed by a descending portion 24a, a tapered portion 24b whose diameter increases from the falling portion 24a toward the bottom portion 25, and a corner portion 24c having a round shape continuously formed from the tapered portion 24b to the bottom portion 25. The fixing portion is fixed in a shape along the side wall portion 24 and the bottom portion 25 of the fixing groove 23.
[Selection] Figure 1

Description

  The present invention relates to a corrugated fin-type heat radiator provided with a corrugated fin among heat radiators used for cooling semiconductor elements that generate heat when used, such as transistors, LSIs, and microprocessors.

  There are various types of heatsinks that cool semiconductor elements. Conventionally, corrugated fin type heatsinks that expand the heat radiation area by fixing the corrugated fins to the support substrate to which the semiconductor elements are attached are known. It has been.

  An example of a conventional corrugated fin-type radiator will be described with reference to FIG. FIG. 4A is a diagram showing a state in which the fin fixing portion of the corrugated fin is fixed to the fixing groove in the conventional corrugated fin-type radiator, and FIG. 4B is a view of the vicinity of the fixing groove to which the fin fixing portion is fixed. It is a partially expanded sectional view. As shown in FIG. 4A, the conventional corrugated fin type radiator 100 mainly includes a corrugated fin 110 and a support substrate 120 in which a plurality of fin fixing grooves 123 are formed. The fixing groove 123 is formed by a flat bottom portion 125, a tapered portion 124 that spreads from the opening side, and a corner portion 127 that is rounded between the tapered portion 124 and the bottom portion 125. The corrugated fin fixing portion 114 of the corrugated fin 110 has a protruding portion 111 with its lower end protruding to the fin fixing groove 123 side, and the width is equal to or smaller than the minimum opening width on the opening side of the fin fixing groove 123. It is formed to become.

When such a corrugated fin fixing portion 114 is pressed toward the fin fixing groove 123 with the press-fitting blade 132 having a flat lower end, the protruding portion 111 is crushed and deformed, and is pressed and fixed along the shape of the fin fixing groove 123. Is done. Thus, the corrugated fin fixing part 114 is fixed to the fin fixing groove 123.
Japanese Patent No. 3602806

However, there is still room for improvement in the corrugated fin-type radiator 100 as described above.
Here, in the technical field of a radiator, it is required to further improve the heat dissipation efficiency. For this purpose, it is an important issue to further increase the contact area and the contact force between the corrugated fins and the support substrate.

  Considering this point, in the conventional corrugated fin-type heat sink 100, as shown in FIG. 4B, the corrugated fin fixing portion 114 cannot be expanded well to the corner 127 of the fin fixing groove 123. In some cases, the gap S may be formed without being able to adhere well along the corner 127.

  Further, in the conventional corrugated fin-type radiator 100, when the protruding portion 111 of the corrugated fin fixing portion 114 is pressed by the press-fitting blade 132 having a flat lower end, the protruding portion 111 is crushed in the width direction of the fin fixing groove 123. When it spreads and reaches the corner 127, it is pushed up in the height direction of the fin fixing groove 123 and deformed. As a result of this deformation, the corrugated fin fixing portion 114 is pulled in the width direction, and its substantially central portion rises and deforms, thereby forming a gap S between the protruding portion 111 and the bottom portion 125 of the fin fixing groove 123. There was a case where it was done.

  The present invention has been made in view of the above problems, and can increase the adhesion area and adhesion force between the corrugated fins and the support substrate, thereby improving the heat radiation efficiency. It is an issue to provide.

  The corrugated fin-type radiator of the present invention that has solved the above-mentioned problems has a plurality of fixing grooves formed by a side wall portion and a bottom portion in order to fix a part of the corrugated fin and a corrugated fin for radiating heat. A corrugated fin-type radiator comprising: a support substrate formed, wherein the bottom portion is formed at least partially in parallel with the bottom portion and has a height higher than the bottom portion. The side wall portion includes a falling portion that vertically falls from the support substrate, a tapered portion that increases in diameter from the falling portion toward the bottom portion, and a continuous portion from the tapered portion to the bottom portion. And a part of the corrugated fin is fixed in a shape along the side wall and the bottom of the fixing groove.

  According to the present invention, since at least a part of the bottom part has the collar part, a part of the corrugated fin is first pressed by the collar part and spreads along the shape of the collar part. Furthermore, it spreads along the shape of the bottom part and is pushed toward the side wall parts on both sides of the fixing groove. Thus, by having a collar part, the contact | adherence area of a corrugated fin and a support substrate can be increased. Furthermore, by having the collar portion, the amount of deformation of the corrugated fin can be increased correspondingly, and thereby, a force to push a part of the corrugated fin toward the corner portion and the side wall portion on both sides of the fixing groove is increased. Can be strong. For this reason, a part of corrugated fin can be made to closely adhere to a fixed groove. Further, since the side wall portion of the fixed groove has a falling portion and a tapered portion, a part of the corrugated fin is fitted and fixed to the fixed groove, so that a lateral force in which adjacent corrugated fins pull each other is pulled. In accordance with the work, a part of the corrugated fin can be satisfactorily adhered to the side wall portion. As described above, by fixing a part of the corrugated fin in a shape along the side wall and the bottom of the fixing groove, the contact area between the corrugated fin and the support substrate can be increased. Furthermore, since the side wall portion has a corner portion having a rounded shape, a part of the corrugated fin that is expanded toward the corner portion presses the corner portion, thereby fixing the corrugated fin to the support substrate. Can be improved.

  Preferably, the length of the falling part is set to be 1/6 or more and 1/2 or less of the length of the side wall part. Preferably, the height of the flange portion is set to 1/10 or more and 2/3 or less of the height of the fixed groove, and the width of the lower end portion of the flange portion is set to 10 minutes of the width of the fixed groove. The width of the upper end portion of the flange portion is set to 1/8 or more and 5/5 or less of the width of the lower end portion of the flange portion, and the width dimension of the upper end portion Is formed so as to have a relationship equal to or smaller than the width of the lower end portion.

  According to this, a part of the corrugated fin can be more preferably fixed in a shape along the side wall portion, the bottom portion, and the corner portion of the fixing groove without applying an excessive load to the corrugated fin.

  Preferably, the radius of the corner portion is set to 1/16 or more and 1/3 or less of the width of the fixed groove.

  According to this, a part of corrugated fin can be stuck to a corner part more favorably.

  According to the corrugated fin type radiator of the present invention, the contact area between the corrugated fin and the support substrate can be increased, and the heat conduction from the support substrate to the corrugated fin can be improved. For this reason, the thermal radiation efficiency of a corrugated fin type heat radiator can be improved. In addition, the fixing strength of the corrugated fin to the support substrate can be improved.

  Hereinafter, the best mode for carrying out the corrugated fin-type radiator 1 according to the present invention will be described. In the drawings to be referred to, FIG. 1A is an overall configuration diagram of a corrugated fin-type radiator according to the present embodiment, FIG. 1B is a partially enlarged perspective view of a fixed groove portion in FIG. FIG. 3A is a partially enlarged cross-sectional view of the vicinity of the fixing groove in FIG. 1, and FIGS. 3A to 3C are views for explaining how the corrugated fin is fixed to the fixing groove.

  As shown in FIG. 1A, the corrugated fin-type radiator 1 is formed of a corrugated fin 10 for radiating heat and a side wall portion 24 and a bottom portion 25 for fixing a part of the corrugated fin 10. And a support substrate 20 on which a plurality of fixing grooves 23 are formed. Here, the corrugated fin 10 and the support substrate 20 are formed of a material having excellent thermal conductivity, such as copper, a copper alloy, and an aluminum alloy.

  The corrugated fin 10 includes a fin bottom portion 11 that is substantially parallel to the support substrate 20 that constitutes the lower end of the corrugated fin, and a fin top portion 12 that is substantially parallel to the support substrate 20 and constitutes the upper end of the corrugated fin 10. A connecting portion 13 that connects the fin bottom portion 11 and the fin top portion 12 and is substantially perpendicular to the support substrate 20 is configured. A plurality of fin bottom portions 11 and fin top portions 12 are alternately formed.

  Such a corrugated fin 10 can be formed by bending a long metal thin plate by press working or the like. In this embodiment, as shown in FIGS. 1A and 2, the connecting portion 13 is not formed on the outermost side of the corrugated fin 10, and the outermost fin bottom portion 15 (see FIG. 2) It is formed shorter than the other fin bottom part 11.

  Moreover, the height from the support substrate 20 of the connection part 13 of the corrugated fin 10 will not be specifically limited if it is sufficient height in order to acquire the heat dissipation effect. Further, the width W1 of the corrugated fin 10 may be equal to or smaller than the width of the support substrate 20, and is not particularly limited. Further, the thickness of the corrugated fin 10 can be appropriately set in consideration of strength and the like.

  In the present embodiment, in the corrugated fin 10 configured in this way, the fin bottom portion 11 and the vicinity of the lower ends of the connecting portions 13 and 13 formed continuously from both longitudinal end portions of the fin bottom portion 11 are the fixing grooves 23. It is fitted and fixed along the shape of the fixing groove 23. Hereinafter, for convenience of explanation, this portion is also referred to as a “fin fixing portion”. The width of the fin fixing portion 14 (see FIG. 2), that is, the dimension between the outer wall portions of the connecting portion 13 is substantially the same as or slightly the same as the width on the opening side of the fixing groove 23, that is, the dimension between the side wall portions 24 and 24. It is formed to have a small width. Thereby, the fin fixing portion 14 can be smoothly inserted into the fixing groove 23.

  As shown in FIGS. 1A and 1B, the support substrate 20 is a base of the corrugated fin-type radiator 1, and has a predetermined width for fixing the corrugated fin 10 to the upper surface portion 21. A plurality of fixing grooves 23 having a depth are provided. Further, the support substrate 20 is in contact with a heat source (not shown) such as a semiconductor element at the lower surface portion 22, and transfers heat from the heat source (not shown) to the corrugated fin 10.

  As shown in FIG. 1B, a plurality of fixing grooves 23 are formed in a recessed manner from the upper surface portion 21 toward the lower surface portion 22 side of the support substrate 20, and have a side wall portion 24 and a bottom portion 25. Is done.

  The side wall portion 24 is formed continuously from the falling portion 24a that falls substantially perpendicular to the upper surface portion 21 of the support substrate 20 and the falling portion 24a, that is, from the lower end portion of the falling portion 24a, and the bottom portion 25. The taper portion 24b has a diameter that increases toward the center, and the taper portion 24b, that is, a corner portion 24c having a round shape that is continuously formed from the lower end portion of the taper portion 24b.

  It is preferable that the length L1 of the falling part 24a is not less than 1/6 and not more than 1/2 of the length L2 of the side wall part 24. If the length L1 of the falling part 24a is equal to or less than one-sixth of the length L2 of the side wall part 24, the length L1 of the falling part 24a is too short. Since there is a possibility that it cannot be made, it is not preferable. On the other hand, when the length L1 of the falling part 24a is equal to or more than half of the length L2 of the side wall part 24, the angle formed by the falling part 24a and the tapered part 24b, and the taper part 24b and the corner part 24c Since the angle formed becomes too steep, there is a possibility that the fin fixing part 14 cannot be satisfactorily adhered, which is not preferable. It is more preferable that the length L1 of the falling portion 24a is not less than one quarter and not more than one third of the length L2 of the side wall portion 24.

  The radius of the corner portion 24c is preferably set to 1/16 or more and 1/3 or less of the width W2 of the fixed groove 23. If the radius of the corner portion 24c is equal to or less than 1/16 of the width W2 of the fixing groove 23, the angle of the corner portion 24c becomes too steep, and the fin fixing portion 14 is favorably aligned with the shape of the corner portion 24c. Since there is a possibility that it cannot be adhered, it is not preferable. On the other hand, if the radius of the corner portion 24c is equal to or more than one third of the width W2 of the fixing groove 23, the angle of the corner portion 24c becomes too gentle, and the fixing strength may be insufficient. . It is more preferable that the corner portion 24c has a radius of 1/8 to 1/4 of the width W2 of the fixed groove 23.

  The bottom portion 25 is formed in a flat plate shape substantially parallel to the upper surface portion 21 of the support substrate 20, and has a flange portion 26 formed at least partially in parallel with the bottom portion 25 and having a height higher than that of the bottom portion 25. Configured.

  In the present embodiment, the flange portion 26 is formed at a substantially central portion of the bottom portion 25. The flange portion 26 has a height H2 from the fixing groove 23 that is not less than 1/10 and not more than two-thirds of the height H1 of the fixing groove 23, and the width W3 of the lower end portion is 10 times the width W2 of the fixing groove 23. 1/8 to 5/6, the width W4 of the upper end is 1/8 to 4/5 of the width W3 of the lower end of the flange 26, and the width of the upper end of the flange 26 It is formed so that the dimension of W4 is less than or equal to the dimension of the width W3 of the lower end portion of the flange portion 26. Thereby, the contact | adherence area to the fixing groove 13 of the fin fixing | fixed part 14 can be increased. The height H2 of the flange portion 26 from the fixing groove 23 is set to ¼ to ½ of the height H1 of the fixing groove 23, and the width W3 of the lower end portion of the flange portion 26 is set to the width of the fixing groove 23. More preferably, the width W4 of the upper end portion of the flange portion 26 is set to be not less than one third and not more than one half of the width W3 of the lower end portion of the flange portion 26. .

  Such a support substrate 20 is formed by, for example, extruding or cutting a plurality of fixing grooves 23 in one plate surface portion (upper surface portion 21 in the present embodiment) of a metal plate.

  Further, at both ends of the support substrate 20, engaging portions for engaging the connecting portions 13 formed continuously with the outermost fin bottom portion 15 with the outermost fin bottom portion 15 positioned on the outermost side of the corrugated fin 10. 28 is formed. The engaging portion 28 has an engaging side wall portion 28a that falls vertically from the upper surface portion 21, and an engaging bottom portion 28b that is parallel to the support substrate 20 formed continuously from the engaging side wall portion 28a. Configured. The width of the engaging portion 28 is formed to be substantially the same width as the dimension from the outer end portion of the outermost fin bottom portion 15 to the outer wall portion of the connecting portion 13.

  Further, a caulking portion 29 is further formed outside the engaging portion 28. The caulking portion 29 is used to fix the outermost fin bottom portion 15 to the engaging portion 28 by being crushed. In the present embodiment, the caulking portion 29 is attached to the outer end portion of the engaging bottom portion 28b of the engaging portion 28. It is formed in the shape of a protrusion that rises along. The height H3 of the caulking portion 29 is set so that when the caulking portion 29 is crushed, the height of the engaging side wall portion 28a, that is, the height of the fixing groove 23 is set so that the vicinity of the tip portion is not caught by the engaging side wall portion 28a. It is preferably formed so as to be lower than the height H1.

  Next, how the fin fixing portion 14 is fixed to the fixing groove 23 will be described with reference to FIGS. 3A to 3C and FIGS. As shown in FIG. 3A, the fin fixing portion 14 of the corrugated fin 10 is inserted into the fixing groove 23 from the opening side and fitted to the upper portion of the flange portion 26. Then, as shown in FIG. 3 (b), the fin bottom portion 11 is pressed toward the flange portion 26 of the fixing groove 23 at the front end portion of the press tool 31 having the concave portion 31 a at the front end between the connecting portions 13 and 13. Is done. As a result, the fin bottom portion 11 adheres along the shape of the flange portion 26, and is spread from the flange portion 26 in the width direction of the bottom portion 25 of the fixing groove 23, and adheres along the shape of the corner portion 24 c. Further, it is pushed upward from the corner portion 24c and closely adheres along the shapes of the tapered portion 24b and the falling portion 24a.

  Since the side wall portion 24 of the fixing groove 23 has a falling portion 24a and a tapered portion 24b, the lateral direction in which the adjacent corrugated fins 20 are pulled together by the fin fixing portion 14 being fitted and fixed to the fixing groove 23. As the force acts, in particular, the connecting portions 13 and 13 of the fin fixing portion 14 can be satisfactorily adhered to the side wall portion 24. Moreover, since the side wall part 24 has the corner part 24c which has a rounded shape, the fin fixing part 14 can be adhered closely to the corner part 24c. In this way, as shown in FIG. 3C, the fin fixing portion 14 is fixed in close contact along the shape of the fixing groove 23.

  At the same time, the outermost connecting portion 13 and the outermost fin bottom portion 15 are fitted to the engaging portion 28 (see FIG. 1B), and the crimping portion 29 is engaged with the press tool 32 having a flat tip. When pressed in the direction approaching the bottom portion 28b (see FIG. 1B), the caulking portion 29 is crushed along the shape of the tip of the press tool 32, spreads on the outermost fin bottom portion 15, The outer fin bottom portion 15 is pressed toward the engagement bottom portion 28b (see FIG. 1B). Thereby, as shown in FIG.3 (c), the outermost fin bottom part 15 and the connection part 13 are fixed to the engaging part 28 (refer FIG.1 (b)).

  In this way, the corrugated fin 20 is fixed to the support substrate 10. The concave portion 31 a at the tip of the press tool 31 can closely contact the fin bottom 11 along the shape of the flange 26 in consideration of the width and height of the lower end of the flange 26 and the thickness of the fin bottom 11. Width and depth are preferred.

  According to the corrugated fin-type radiator 1 according to the present embodiment, the corrugated fin 10 and the support substrate 20 are brought into close contact with the fin fixing portion 14 of the corrugated fin 10 along the shape of the fixing groove 23 of the support substrate 20. The contact area can be increased, and heat conduction from the support substrate 20 to the corrugated fins 10 can be improved. For this reason, the heat dissipation efficiency of the corrugated fin-type radiator 1 can be improved. Further, the strength of fixing the corrugated fin 10 to the support substrate 20 can be improved.

  The corrugated fin-type radiator according to the present embodiment has been described above. However, the corrugated fin-type radiator of the present invention is not limited to the present embodiment, and various modifications can be made without departing from the spirit of the present invention. Of course it is possible.

(A) is a whole block diagram of the corrugated fin-type radiator according to the present embodiment, and (b) is a partially enlarged perspective view of a fixed groove portion in (a). FIG. 2 is a partially enlarged sectional view in the vicinity of a fixing groove in FIG. 1. (A) thru | or (c) is a figure for demonstrating a mode that a corrugated fin is fixed to a fixing groove. (A) is a figure which shows a mode that the fin fixing | fixed part of a corrugated fin is fixed to a fixing groove in the conventional corrugated fin type heat sink, (b) is a part of the fixing groove vicinity to which the fin fixing | fixed part was fixed. It is an expanded sectional view.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Corrugated fin type heat sink 10 Corrugated fin 11 Fin bottom part 12 Fin top part 13 Connection part 14 Fin fixing | fixed part 15 Outermost fin bottom part 20 Support substrate 21 Upper surface part 22 Lower surface part 23 Fixing groove 24 Side wall part 24a Falling part 24b Taper part 24c Corner part 25 Bottom part 26 Gutter part 28 Engagement part 28a Engagement side wall part 28b Engagement bottom part 29 Caulking part 31, 32 Press tool 31a Recessed part

Claims (4)

Corrugated fins to dissipate heat,
In order to fix a part of the corrugated fin, a support substrate in which a plurality of fixing grooves formed by the side wall and the bottom are formed,
A corrugated fin-type heatsink comprising:
The bottom is
At least in part, having a collar portion formed parallel to the bottom portion and having a height higher than the bottom portion,
The side wall portion is
A falling portion that vertically falls from the support substrate, a tapered portion that increases in diameter from the falling portion toward the bottom portion, and a corner portion that has a round shape that is continuously formed from the tapered portion to the bottom portion. Formed by,
A part of the corrugated fin is fixed to the fixed groove in a shape along the side wall and the bottom of the fixed groove.   The corrugated fin-type radiator according to claim 1, wherein a length of the falling portion is set to be 1/6 or more and 1/2 or less of a length of the side wall portion.   The height of the flange is set to 1/10 or more and 2/3 or less of the height of the fixed groove, and the width of the lower end of the flange is set to 1/10 or more and 6 minutes of the width of the fixed groove. 5 or less, and the width of the upper end portion of the flange portion is not less than 1/8 and not more than 4/5 of the width of the lower end portion of the flange portion, and the width dimension of the upper end portion is the width of the lower end portion. 3. The corrugated fin-type heat radiator according to claim 1, wherein the corrugated fin-type heat radiator is formed so as to have a relationship of a width dimension or less.   4. The corrugated fin-type radiator according to claim 1, wherein a radius of the corner portion is 1/16 or more and 1/3 or less of a width of the fixed groove. 5. .

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