JPH1131770A - Heat generating unit cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to obtain a uniform and excellent cooling effect of a cooling device, by a method wherein an air blower having an air-blasting fan is provided in opposition to an air-blasting vet provided in a heat sink of a structure, wherein the air-blasting vent which is encircled with the end parts on the insides of radiation fins is formed in the surface of a heat transfer medium. SOLUTION: The cooling air is sent to an air-blasting vent 3 provided in opposition to a fan 20, but the other diameter d1 of the fan 20 is made shorter than the outer diameter d2 of the vent 3 to increase the amount of the air blast. The main flow of the cooling air flows in the directions shown by arrows B, collide on the radiating surface 1b of a heat transfer medium 1, is diffused outward and flows from inflow vents formed in the fans 2 into between the fins 2. At this time, as prescribed intervals h2 are provided between the fins 2 and an air-blower 18, the cooling air flows also in the directions shown by arrows C and is sent also on the sides of the fins 2 which are near the motor- driven air blower 18. Accordingly, the cooling air comes into contact uniformly with the whole of the fins 2 and the cooling effect of the cooling device can be raised.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat generating component cooling device for efficiently cooling a heat generating element such as an electronic component.

[0002]

2. Description of the Related Art FIG. 6 is a perspective view of a conventional heating element cooling device disclosed in Japanese Patent Application Laid-Open No. 8-321571, for example, and FIG. In FIG. 6, the heat sink 31
Is made of a high heat conductive material such as aluminum, copper or aluminum nitride. The heat sink 31 is a heating element 45 such as a semiconductor.
Is attached to dissipate the heat of the heating element 45 and cool it. A cover 41 is attached to the upper surface of the heat sink 31 by a method such as brazing or screwing. The cover 41 may be made of a high thermal conductive material such as aluminum, copper, or aluminum nitride. The fan 3 is provided inside the heat sink 31.
2 and a motor 33 for driving the fan 32 are provided. The cover 41 has an opening 42 at a position corresponding to the upper part of the fan 32 and the motor 33. The side surface of the heat sink 31 is provided with an opening 43 only in one direction.
When the fan 32 is driven by the motor 33, the air is sucked from the opening 42, passes through the inside of the heat sink 31, and is discharged from the opening 43 on the side surface.

In FIG. 7, a plurality of heat dissipating fins are provided so as to surround the fan 32, and outer wall portions 44 are provided in three directions other than the opening 43 on the outer periphery.
The fan 32 rotates in the direction of the arrow and draws in air from above the figure. The air sucked from above in the figure by the fan 32 passes through the fins 34, 35, 36 and 37 and is discharged in the direction of the opening 43. Although the air sucked by the fan 32 is in the same direction, the air blown by the rotation of the fan 32 is blown in the tangential direction of the rotation of the fan 32. In order to guide this air in the direction of the opening 43, the fins 3
4, 35, 36 and 37 have different shapes depending on positions. In FIG. 7, when the center lines AC and BD are drawn, the heat sink device is divided into four parts.

[0004] In a portion sandwiched by AB, air is supplied to the fan 3.
The fins 34 deviate in the direction of rotation of the tangent of the rotation circle 2
To the blowing direction 38. The shape of the plurality of fins 34 is such that the fan 32 side 34a is curved to deflect air coming tangentially toward the opening 43,
The blowout side 34 b of the fin 34 is parallel to the blowout direction of the opening 43. Since the angle difference between the blowing direction 38 and the air coming in the tangential direction of the fan 32 becomes smaller toward the side A, the curved portion on the fan 32 side becomes smaller.

At the portion sandwiched between the BCs, the air blown in the tangential direction of the fan 32 is directed in the opposite direction to the blowout direction 38, so that the air blows through the C side and the D side and blows out in the blowout direction 38.
The shape of the fin 35 is set in order to guide the fin 35. The shape of the plurality of fins 35 is such that the fan 32 side 35a is parallel to the tangential direction of the rotating circle of the fan 32 to guide the air coming in the tangential direction of the rotating circle of the fan 32, and the blowing side 35b of the fin 35 is Is deflected to the C side to be curved to the C side. Since the direction of air blowing in the tangential direction of the rotation circle of the fan 32 is directed toward the D side as it goes to the C side, the curvature of the fin 35 is reduced.

In the portion sandwiched between the CDs, the shape of the fins 36 is set to guide the air blown in the tangential direction of the fan 32 to the blowout direction 38 through the D side. The shape of the plurality of fins 36 is such that the fan 32 side 36a is parallel to the tangential direction of the rotating circle of the fan 32 to guide air coming in the tangential direction of the rotating circle of the fan 32, and the blowing side 36b of the fin 36 is Is deflected in the direction D and in the blowing direction 38 so as to be deflected in the direction D and in the blowing direction 38. The direction of flow of air coming in the tangential direction of the rotation circle of the fan 32 toward the side D is the blowing direction 38.
Since the fin 36 is directed to the side, the curvature of the fin 36 is reduced.

In the portion sandwiched by the DAs, the shape of the fins 37 is set to guide the air blown in the tangential direction of the fan 32 in the blowout direction 38. The shape of the plurality of fins 37 is such that the fan 32
Although it is parallel to the tangential direction to guide air coming in the tangential direction of the rotating circle, the side close to the A side has a shape parallel to the blowing direction 38 side. The outlet side 3 of the fin 37
7b has a shape parallel to the blowing direction 38 for deflecting the flow of air toward the blowing direction 38.

[0008]

Since the conventional cooling device for a heating element such as an electronic component is constructed as described above, the arrangement of the radiating fins is irregular, so that the air resistance is increased and the cooling performance is reduced. There is a problem that a uniform heat radiation effect cannot be obtained because the discharge direction is limited to one direction.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a heating element cooling device which has a small air resistance and can obtain a uniform and excellent cooling effect.

[0010]

According to a first aspect of the present invention, a plurality of curved radiating fins are radially arranged on a surface of a heat transfer body, and an inner end of each of the heat radiation fins is provided on a surface of the heat transfer body. And a fan having a blower fan provided opposite to the blower port of the heat sink.

According to a second aspect, in the first aspect, the outer diameter of the blower fan is smaller than the outer diameter of the blower port.

According to a third aspect, in the first aspect, the difference between the outer diameter of the blower fan and the outer diameter of the blower port is set to 5% or less of the outer diameter of the blower fan.

According to a fourth aspect, in the first aspect, a predetermined gap is provided between the radiation fin and the blower.

In a fifth aspect based on the first aspect, the distance between the lower end of the blower fan and the upper surface of the heat transfer member is H, the outer diameter of the blower fan is d ₁ , and the aperture ratio inside the radiation fin is n. , H = 100d ₁ / 4n.

According to a sixth aspect, in the first aspect, a plurality of projections are formed on a surface of the radiation fin.

According to a seventh aspect of the present invention, in the first aspect, a mounting portion for the heating element is provided on a surface of the heat transfer element opposite to the side on which the radiating fins are provided. Thicker than the thickness.

According to an eighth aspect, in the first aspect, a pedestal for mounting the blower is provided integrally with the radiating fins.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. FIG. 1 is a top view showing one embodiment of a heating element cooling device according to the present invention, FIG. 2 is a longitudinal sectional view thereof, and FIG. 3 is a bottom view thereof. In the figure, reference numeral 1 denotes a heat transfer body of an aluminum alloy material (containing 90% or more of aluminum), which is formed in a substantially rectangular plate shape. Reference numeral 1a denotes a mounting surface of a heat-generating component such as a semiconductor constituting the bottom surface of the heat transfer body 1, and 1b denotes a heat radiation surface of the heat transfer body 1 facing the mounting surface 1a. Numeral 2 denotes a plurality of plate-shaped curved heat radiation fins standing on the heat radiation surface 1b, which are arranged in a spiral shape from the substantially central portion of the heat transfer body 1 toward the outer periphery. 2a is an inner surface of the curved heat radiation fin 2, 2b is an outer surface of the heat radiation fin 2, 2c is a plurality of triangular inner protrusions protruding from the inner surface 2a, 2d is a plurality of triangular protrusions protruding from the outer surface 2b. Outer protrusions. Reference numeral 3 denotes a space portion of the heat transfer body 1 where the heat radiation fins 2 are not formed, and is an air outlet having a diameter d ₂ and a height h ₁ surrounded by an inner end of the heat radiation fin 2,
This is a portion that receives air from a blower described later. that's all,
The heat transfer body 1 and the radiating fins 2 constitute a radiating plate having an air outlet 3.

Reference numeral 6 denotes a mounting seat for a semiconductor or the like, which has a flat shape slightly protruding from the mounting surface 1a of the heat transfer body 1 and is formed thicker than the thickness of the heat transfer body 1. FIG. 5 shows a bottom view of the heat sink with the semiconductor removed. As shown in FIG.
A groove 6a formed in a concave portion on the mounting surface 1a is provided on an outer periphery of the device, and a female screw 6b for mounting a semiconductor or the like is provided substantially at the center. Reference numeral 7 denotes a semiconductor mounting seat provided at a distance from the mounting seat 6. Like the mounting seat 6, the semiconductor mounting seat 7 has a flat shape slightly projecting from the mounting surface 1a. 7b.

Reference numerals 8 and 9 denote semiconductors mounted on the mounting seats 6 and 7, respectively. The semiconductor elements 8 and 9 are brought into close contact with the mounting seat 6 and the mounting seat 7 on which a silicone conductive putty having heat conductivity is applied, and the screw holes 6 b and 7 are
b. Reference numeral 10 denotes a partition plate which is provided upright adjacent to the mounting seat 6, and has a height higher than the height of the semiconductor. Reference numeral 11 denotes a partition plate that is provided upright adjacent to the mounting seat 7 and has the same height as the partition plate 10. The partition plates 10 and 11 are used for positioning the semiconductors 8 and 9, and when the screws are tightened, the semiconductors 8 and 9 are used.
9 is prevented from turning. Further, since the grooves 6a and 7a are provided between the partition plates 10 and 11 and the mounting seats 6 and 7, respectively, the semiconductors 8 and 9 are surely mounted on the mounting seats 6 and 7 and the partition plates 10 and 11. The heat can be transmitted to the heat transfer body 1 upon contact.

Reference numeral 12 denotes a boss provided at a corner of the heat transfer body 1 and protruding from the mounting surface 1a and the heat radiation surface 1b, and has a screw hole 12a. A boss 13 is provided at a corner of the heat transfer body 1 on a diagonal line with the boss 12 and protrudes from the mounting surface 1a and has a screw hole 13a. In addition, this boss 1
The heights of 2 and 13 are the same as those of the partition plates 10 and 11.

Reference numerals 14 and 15 denote a pair of mounting bosses serving as pedestals for fixing an electric blower described later.
And a predetermined height h from the upper surface of the radiation fin 2
It is erected on ₂ . 16 and 17 are bosses 12 and 13
A predetermined height h from the upper surface of the radiation fin 2 on the line connecting
_This is the positioning boss of the electric blower set up in step ₂ . The heat transfer body 1, the heat radiation fins 2, and the bosses 12 to 17 are integrally formed by die casting.

Reference numeral 18 denotes an electric blower, and a motor 19,
And an axial flow blower 20 as a fan.
The guide portion of the electric blower 18 is a circle drawn by the inner end of the radiation fin 2, that is, a circle concentric with the blower port 3 and having the same diameter (ie, d ₂ ). Further, the diameter d ₁ of the fan 20 and the diameter d ₂ of the air blowing port 3 constitutes the relationship d _2> d _1. The electric blower 18 has its corner fixed to the mounting bosses 14 and 15 with screws 21 and is combined with a heat sink. Also, holes are provided at positions corresponding to the positioning bosses 16 and 17.

The shape of the radiation fin 2 will be described in more detail with reference to FIG. FIG. 4 is a top view of the heat sink with the electric blower 18 removed. The heat radiating fins 2 are arranged on the heat radiating surface 1b of the heat transfer body 1 radially from the inside to the outside at substantially uniform intervals over the entire circumference. Specifically, each of the radiating fins 2 is arranged in a ring shape such that an inner end thereof draws a circle having a diameter d ₂ and an outer end thereof draws a concentric circle having a larger diameter D. The inner end of 2 faces the air outlet 3. The gap between the inner ends of the adjacent radiating fins 2 becomes the inlet 4 for the cool air blown from the electric blower 18, and the gap between the outer ends becomes the outlet 5 for the cool air, and the outlet 5 Larger than entrance 4,
The spread angle is set to about 14 degrees in order to obtain a diffusion effect. The opening ratio of the inflow port 4 is determined by the outer peripheral area (π
× d ₂ × h ₁ ).

The radiating surface of the heat transfer body 1 has a predetermined angle with respect to the radial direction of the circle drawn by each inner end of the radiating fin 2 so that the inflow port 4 side of the radiating fin 2 coincides with the inflow angle of the cool air. 1b, the angle of which is equal to the outflow angle of the wind of the fan 20. Further, since the wind of the fan 20 flows out while turning, the radiating fins 2 having a predetermined curvature are arranged in a spiral so as not to hinder the swirling flow. Therefore, the fluid resistance at the inflow port 4 can be minimized, and the flow resistance in the flow path formed by the radiation fins 2 can be minimized.

The height of the inner projection 2c and the outer projection 2d is gradually increased from the inflow port 4 side to the discharge port 5 side. The inner protrusion 2c is formed higher than the outer protrusion 2d. Further, an outer protrusion 2d protruding on the outer surface 2b of one heat radiation fin 2 of the adjacent heat fin 2 and an inner protrusion 2c protruding on the inner surface 2a of the other heat radiation fin 2 facing the heat radiation fin 2 are arranged to be shifted from each other. .

Next, the operation of the cooling device will be described. Heat is generated when the semiconductors 8 and 9 are energized, but this heat is diffused from the mounting seats 6 and 7 to the entire heat transfer body 1 and is transferred from the heat radiating surface 1b to the heat radiating fins 2 to heat the entire heat radiating plate. Here, cooling is performed as follows by rotating the fan 20 and blowing air.

[0028] When the driven motor 19 is a fan 20 rotates in the direction of arrow A, the cool air is blown to the air blowing port 3 provided opposite to the fan 20, the outside diameter d ₁ of the fan 20 of the air blowing port 3 By making it smaller than the outer diameter d ₂ , a large amount of air can be obtained. Here, if the difference between the outer diameter d ₁ of the fan 20 and the outer diameter d ₂ of the air blowing port 3 and less than 5% of the outer diameter d ₁ of the blower fan, it is possible to obtain more of the blast volume.

The main flow of the cool air proceeds in the direction of arrow B,
And diffuses outward and flows into the space between the radiation fins 2 through the inflow port 4 of the radiation fin 2. At this time, if the electric blower 18 is too close to the radiating fins 2, there is a possibility that the cool air does not hit the surface of the radiating fins 2 on the side closer to the blower 18, but a predetermined gap h between the radiating fins 2 and the blower 18. ₂ , the cool air also travels in the direction of arrow C, and is also blown to the side of the radiating fin 2 close to the electric blower 18 (that is, a position distant from the radiating surface 1b of the heat transfer plate 1). 2 is uniformly contacted, and the cooling effect is improved.

The cool air flowing into the space between the radiating fins 2 from the inlet 4 exchanges heat with the radiating fins 2 and is discharged from the outlet 5 to the entire circumference. The function of cooling between the radiation fins 2 will be described. As described above, the resistance when the cold air flows into the inflow port 4 is small, and the resistance of the flow in the flow path formed by the radiation fins 2 is also small. can get. The flow velocity on the surface of the radiation fin 2 becomes slower than the main flow of the wind flowing through the central portion between the radiation fins 2 due to the viscous resistance of the surface. 2d, a vortex is generated immediately after the vortex, and a turbulent flow is generated behind the vortex to re-attach to the surface of the radiation fin 2. By the action of the turbulence, the mainstream cold wind is sent to the reattachment point of the radiation fins 2 and the warm wind on the surface of the radiation fins 2 is sent to the cold mainstream side, so that the heat transfer coefficient near the reattachment point is improved. . Further, by providing a plurality of projections 2c and 2d on the surface of the facing radiating fin 2 so as to be shifted from each other, a peeling region having a low heat transfer coefficient (a region from the protrusion to the reattachment point) is made as narrow as possible, and peeling and reattachment are prevented. By repeatedly raising the temperature, the heat transfer coefficient is improved, and the cooling effect is dramatically improved.

Further, since the protrusions 2c and 2d are gradually increased toward the outside of the heat radiating plate, the flow velocity of the wind flowing between the heat radiating fins 2 decreases as the wind advances toward the outer peripheral side due to the surface viscosity of the heat radiating fins 2. The heat recovery decreases, but the protrusions 2c, 2c
The heat transfer coefficient is increased by d. The wind passing between the heat radiation fins 2 is strong on the inner surface 2a side and weak on the outer surface 2b side of the heat radiation fin 2, but hits the inner surface 2a because the inner protrusion 2c is formed higher than the outer protrusion 2d. The strong wind is diffused toward the outer surface 2b to improve the cooling effect.

Mounting boss 1 for mounting blower 18
Since the fins 4 and 15 are formed integrally with the radiating fins 2, they do not obstruct the flow of air. The mounting bosses 14, 1
The cross-sectional shape of 5 is circular in FIG. 4, but it is also possible to make it a shape with even less resistance to flow.

The relationship of the opening ratio n of the inlet 4, the distance H between the lower end of the fan 20 and the heat radiating surface 1 b of the heat transfer body 1, and the outer diameter d ₁ of the fan 20 is H ≧ 100 d ₁ / 4n. Thereby, the air volume loss at the outlet of the fan 20 is made close to 0,
The blowing efficiency is improved.

As described above, the heating element cooling device according to the present embodiment has a very high cooling effect.
8 and the heat sink can be made smaller.

[0035]

According to the first aspect of the present invention, the air is uniformly blown from the blower, and the cooling effect is improved because there is no resistance to the flow of the cool air between the radiation fins.

According to the second aspect of the present invention, since the outer diameter of the blower fan is made smaller than the outer diameter of the blower port, the amount of blown air is large and the cooling effect is improved.

According to the third aspect, the amount of air can be further increased, so that the cooling effect is improved.

According to the fourth aspect, since the predetermined gap is provided between the radiation fin and the blower, the blown air comes into contact with the whole of the radiation fin, and the cooling effect is improved.

According to the fifth aspect, the distance between the lower end of the blower fan and the upper surface of the heat transfer member is H, the outer diameter of the blower fan is d ₁ ,
When the opening ratio inside the radiation fin is n, H = 100
Since it is configured to be d ₁ / 4n, the air blowing efficiency is good and the cooling effect is improved.

According to the sixth aspect of the present invention, since a plurality of projections are formed on the surface of the radiation fin, heat exchange is improved by the turbulent action of the vortex generated behind the projections, and the cooling effect is further improved.

According to the seventh aspect of the present invention, the mounting portion for the heating element is provided on the surface of the heat transfer element opposite to the side on which the radiation fins are provided, and the thickness of the mounting section is made larger than the thickness of the heat transfer element. Heat from the heating element is easily absorbed, heat conduction to the entire heat transfer element is improved, and the cooling effect is improved.

According to the eighth aspect, the pedestal for mounting the blower is provided integrally with the radiating fins, so that the flow of air between the radiating fins is not obstructed.

[Brief description of the drawings]

FIG. 1 is a top view of a heating element cooling device according to Embodiment 1 of the present invention.

FIG. 2 is a longitudinal sectional view of the heating element cooling device according to Embodiment 1 of the present invention.

FIG. 3 is a bottom view of the heating element cooling device according to Embodiment 1 of the present invention.

FIG. 4 is a top view of the heat sink with the electric blower removed.

FIG. 5 is a bottom view of the heat sink with a semiconductor removed.

FIG. 6 is a perspective view of a conventional heating element cooling device for electronic components and the like.

FIG. 7 is an internal structural view of a conventional heating element cooling device with a cover removed.

[Explanation of symbols]

1 heat transfer body, 2 radiation fins, 2c inner projection, 2d
Outer protrusion, 3 blow port, 6 mounting seat, 7 mounting seat, 14
Mounting boss, 15 Mounting boss, 18 Electric blower, 20
fan.

Continued on the front page (72) Inventor Hiroaki Tsukahara 1728-1, Koeda, Hanazono-cho, Osato-gun, Saitama Prefecture Inside Mitsubishi Electric Home Equipment Co., Ltd. Inside Equipment Co., Ltd. (72) Inventor Takao Oshima 1728-1 Komaeda, Hanazono-cho, Osato-gun, Saitama Prefecture Inside Mitsubishi Electric Home Equipment Co., Ltd. (72) Kunihiko Kaga 2-3-2 Marunouchi, Chiyoda-ku, Tokyo Mitsubishi Electric Inside the corporation

Claims (8)

[Claims] 1. A heat radiator having a plurality of curved radiating fins radially arranged on a surface of a heat transfer body, and a ventilation port surrounded by an inner end of each radiator fin on the surface of the heat transfer body. A heating element cooling device comprising: a plate; and a blower having a blower fan provided to face a blower opening of the heat sink. 2. The heating element cooling device according to claim 1, wherein the outer diameter of the blower fan is smaller than the outer diameter of the blower port. 3. The heating element cooling device according to claim 1, wherein the difference between the outer diameter of the blower fan and the outer diameter of the blower opening is set to 5% or less of the outer diameter of the blower fan. 4. The heating element cooling device according to claim 1, wherein a predetermined gap is provided between the radiation fin and the blower. 5. When the distance between the lower end of the blower fan and the upper surface of the heat transfer body is H, the outer diameter of the blower fan is d ₁ , and the opening ratio inside the radiation fin is n, H = 100d ₁ / 4n. The heating element cooling device according to claim 1, wherein the heating element cooling device is configured to be configured as follows. 6. The heating element cooling device according to claim 1, wherein a plurality of projections are formed on a surface of the radiation fin. 7. A heat-generating body, wherein a heat-generating body mounting portion is provided on a surface of the heat-transfer body opposite to the side on which the heat-radiating fins are provided, and the thickness of the mounting portion is greater than the thickness of the heat-transfer body. Item 1
The heating element cooling device as described in the above. 8. The heating element cooling device according to claim 1, wherein a pedestal for mounting the blower is provided integrally with the radiating fin.