JP5715352B2 - heatsink - Google Patents

Description

  The present invention relates to a heat sink used for heat dissipation of various electronic components such as a CPU, an integrated circuit, and a semiconductor element, an electronic device, and other various electric devices. In particular, the present invention relates to a heat sink that is excellent in cooling performance and suppresses a pressure loss generated when a cooling fluid flows.

  In electronic components such as CPUs, integrated circuits, semiconductor elements, electronic devices, and various electric devices, a heat sink is provided for heat dissipation. In recent years, since the heat generation amount and heat generation density of these elements or devices tend to increase, a high-performance heat sink with better cooling performance has been demanded.

  For example, many hybrid vehicles have been produced from the viewpoint of energy saving, etc., but an inverter that controls the drive motor of this hybrid vehicle is mounted with a heating element such as an IGBT element. Cooling is required during operation, and the inverter is provided with a heat sink.

  Further, in a lithium ion battery or the like mounted on a hybrid vehicle or the like, a heat sink may be provided in order to prevent a decrease in performance due to a temperature increase during operation.

  In recent years, heating elements such as inverters and batteries have been required to have higher efficiency and downsizing, and as a result, the energy density is higher and the heat generation of the heating elements tends to be higher. Therefore, further improvement in cooling performance has been demanded of the heat sink.

  When circulating the cooling fluid flowing through the heat sink using a fan, pump, etc., if the pressure loss of the cooling fluid increases, the required pump capacity increases and the noise during pump operation also increases. Therefore, it is required to keep pressure loss as small as possible.

JP 58-66793 A Japanese Patent Laid-Open No. 11-166696 JP 58-140597 A JP 2006-278735 A

  An object of this invention is to provide the heat sink which suppresses the pressure loss which arises when the fluid for cooling flows as much as possible with the further improvement in cooling performance.

  The present invention that solves the above-described problems relates to a heat sink that is excellent in cooling performance and that suppresses a pressure loss that occurs when a cooling fluid flows. The heat sink of the present invention has the following characteristics.

  The heat sink according to the first aspect is shown in FIG. 1 as a perspective view of one embodiment thereof, and as shown in FIG. 3 as a schematic plan view of the embodiment, on a base plate to which heat generating components are thermally connected. In addition, in the heat sink provided with a fin unit for conducting heat transfer to the cooling fluid, the fin unit has a large number of plate-like fins having a cross-sectional length L parallel to the base plate surface separated by a distance P. The first fin group erected on the base plate in parallel with each other, and is separated from the first fin group by a distance a of 0.8 P or more and 0.3 L or less from the upstream side to the downstream side of the cooling fluid. The second fin group is similar to the first fin group arranged in a predetermined D direction, and each cross section parallel to the base plate surface of each plate-like fin has a deviation angle γ with respect to the D direction. (However, ° ≦ γ ≦ 5 °.) Forms a.

  The heat sink of the second aspect is 0.8 P or more and 0 from the second fin group, as shown in FIG. 1 as a perspective view of the embodiment and as shown in FIG. 3 as a schematic plan view of the embodiment. It is repeated in the D direction that a fin group similar to the second fin group is further arranged in the D direction at a distance a of 3 L or less.

  As shown in the schematic sectional view of one embodiment of the heat sink of the third aspect, the plate surface of the plate-like fin is inclined with respect to the base plate surface at an inclination angle β (provided that 20 ° ≦ β ≦ 80 °). ).

  As shown in the schematic plan view of one embodiment of the heat sink of the fourth aspect, the plate surfaces of the plate-like fins of two adjacent fin groups are on the same common plane. Thus, plate-like fins are arranged.

  In the heat sink of the fifth aspect, the fin unit is formed by pressing a single metal plate.

  In the heat sink according to the sixth aspect, the fin unit is made of aluminum or an aluminum alloy.

  Here, the reason why the cooling performance of the heat sink of the present invention is excellent and the pressure loss of the cooling fluid can be kept small will be described.

  Generally, when the cooling fluid flows along the heat dissipating fins in the heat sink, a temperature boundary layer is formed. That is, the cooling fluid removes heat from the fin by contacting the surface of the heat-dissipating fin that is thermally connected from the heat-generating component through the base plate, and thereby near the surface of the fin. The cooling fluid is gradually warmed and becomes hotter as it goes downstream. On the other hand, since the flow along the fins is generally laminar, the cooling fluid flowing away from the fins does not contact the high-temperature fins, so there is no particular high temperature even when going downstream. . In this way, as it goes downstream, there is a temperature difference in the cooling fluid between the portion near the fin surface and the portion away from the fin, and a temperature boundary layer is formed between them. .

  The cooling fluid that has already reached a high temperature near the fin surface is no longer capable of removing heat from the fin. Therefore, if the cooling fluid that is still cold at the part away from the fins comes to and comes into contact with the fin surface, the ability to remove heat from the fins will be further enhanced. That is, if the cooling fluid that was flowing near the fin surface and the cooling fluid that was flowing away from the fin can be replaced in the middle of the flow, it is most ideal, It is not easy to realize such “replacement”. Therefore, as a suboptimal measure, even if the cooling fluids cannot be completely replaced, the effect is great only by “mixing” both the cooling fluids. That is, by disturbing the flow in the middle of the flow and breaking the temperature boundary layer, a cooling fluid having a lower temperature comes into contact with the fin surface, and the ability to take away heat from the fin is further enhanced.

In view of the above circumstances, first, the reason why the heat sink of the first aspect has excellent cooling performance and the pressure loss of the cooling fluid can be kept small will be described.
Since the second fin group is disposed in the D direction as viewed from the first fin group, when the cooling fluid leaves the first fin group and enters the second fin group, the cooling fluid is directed in the D direction.
However, each cross section parallel to the base plate surface of each plate-like fin forms a deviation angle γ (where 1 ° ≦ γ ≦ 5 °) with respect to the D direction. When the cooling fluid that has flown along the fins leaves the first fin group and enters the second fin group, the cooling fluid flows in the D direction, which is different from the direction of the plate fin that has flown up to that point by an angle γ. As a result, it receives the force in the horizontal direction.

  Here, the D direction is a direction from the upstream side to the downstream side of the cooling fluid, and is a direction in which the same second fin group is arranged in series with respect to the first fin group. Say. However, in the heat sink of the present invention, once the “D direction” is determined once the first two fin groups are arranged in series, only the D direction is used throughout the heat sink. Another “D direction” is not newly added.

  As a result, the cooling fluid that has flowed as a laminar flow while forming a temperature boundary layer along the plate-like fins of the first fin group is disrupted in the flow and the temperature boundary layer is destroyed. The cooling fluid that has flowed away from the plate-like fin surface of the fin group and is still at a low temperature, and then the cooling fluid that has flowed near the plate-like fin surface of the first fin group, It enters the second fin group in a mixed state and comes into contact with the plate-like fin surface of the second fin group. In this way, the cooling performance is further increased.

  By the way, if the flow is disturbed, the pressure loss is generally larger than that in a laminar flow. However, in the present invention, since the deviation angle γ is suppressed to 5 ° or less, the degree of deviation of the flow direction of the cooling fluid is not so great, so the pressure loss does not increase so much.

  Now, like the heat sink of the second aspect, the cooling fluid exits one fin group and enters another fin group by repeating the arrangement of the fin group in the D direction separated by a distance a in the D direction. Since there are more opportunities to mix sometimes, the cooling performance is further enhanced.

  Further, like the heat sink of the third aspect, the plate surface of the plate-shaped fin is inclined at an inclination angle β (20 ° ≦ β ≦ 80 °) with respect to the base plate surface, so that it is perpendicular to the base plate surface. It becomes possible to stir the cooling fluid also in the direction, and the cooling performance can be further improved.

  Further, if the arrangement is such that the plate surfaces of the plate-like fins of the two adjacent fin groups are on the same common plane as in the heat sink of the fourth aspect, this arrangement is each plate-like. Since it is easy to grasp the position of the fin, manufacturing is facilitated. In addition, a long plate-like fin that is common to each fin group is erected on the base plate in advance, and then a slit with a spacing P for each length L is cut in a direction perpendicular to the D direction. It is.

  Further, the fin unit can be formed relatively easily by pressing and forming one metal plate as in the heat sink of the fifth aspect.

  In addition, like the heat sink of the sixth aspect, by configuring the fin unit using aluminum or aluminum alloy having high thermal conductivity, heat can be efficiently transferred from the base plate to the end of the fin unit.

  For the heat sink of the present invention described above, techniques disclosed in patent publications such as Patent Documents 1 to 4 are known as techniques similar to the present invention. There remain points that cannot be fully satisfied in any aspect of performance, miniaturization, ease of formation, and the like.

  In Patent Document 1, a corrugated fin is provided in a flat tube through which a high-temperature fluid that is an object to be cooled flows, and an inclined louver is further provided in the corrugated fin, and an air flow is supplied to the corrugated fin and the inclined louver. The fluid in the flat tube is cooled by applying and cooling. At first glance, the pattern of the cross-sectional view showing the louver arrangement on the corrugated fins gives the feeling that the bag is similar to the present invention.

In the present invention, plate-like fins are directly erected on a base plate to which heat-generating components are thermally connected, and the structure is significantly different from Patent Document 1.
In particular, the fin group consisting of a large number of plate-like fins is separated from the fin group by a distance a, and the cooling fluid flowing along the plate-like fins receives a lateral force there. As a result, the cooling fluid that flows near the surface of the plate fin and the cooling fluid that flows away from the surface of the plate fin are mixed together, and the temperature boundary layer is destroyed to increase the cooling performance. On the other hand, the arrangement in Patent Document 1 does not cause such a lateral force.

  Further, in Patent Document 1, since the inclined louver is provided on the corrugated fin, the distance from the heating element is increased, and the area of the joint portion between the inclined louver and the corrugated fin is reduced, so that the heat transfer is worsened. However, in the present invention, since the plate-like fins are directly erected on the base plate to which the heat generating components are thermally connected, the distance from the heat generating element is short, and the heat transfer is good.

  In Patent Document 1, the fin is not inclined with respect to the base plate surface. Therefore, the cooling fluid cannot be stirred in a direction perpendicular to the base plate surface. However, in the present invention, since the cooling fluid can be stirred in a direction perpendicular to the base plate surface, the cooling performance is higher.

  Next, in Patent Document 2, a winglet obtained by bending a portion of a plurality of flat plate-like fins arranged substantially parallel to each other in a cantilever manner has an angle of attack with respect to the air current and an angle of inclination with respect to the surface of the fin base material. Is.

On the other hand, in the present invention, a large number of plate-like fins erected in parallel with each other on the base plate are provided with a bias angle and an inclination angle, and the structure is significantly different from that of Patent Document 2.
Further, since the main purpose of Patent Document 2 is to prevent local frost formation, in order to strengthen the corner vortex and promote heat transfer in front of the winglet, the angle of attack γ is in the range of 30 ° to 70 °, The fin inclination angle β is in the range of 90 ° to 160 °, and the deviation angle γ of the present invention is significantly different from 1 ° to 5 ° and the inclination angle β is 20 ° to 80 °.
When the plate-like fins of the present invention are erected at the angle of attack γ and the angle of inclination β as in Patent Document 2, the pressure loss of the cooling fluid is significantly increased.

  According to Patent Document 3, by providing a plate-like inner fin inclined with respect to the flow direction of the fluid in the pipe, the resistance of the refrigerant passage is reduced, and the heat transfer area is effectively worked to improve the heat transfer performance. Is.

  However, since the fin group is not separated from the fin group by a distance a as in the present invention, the cooling fluid flowing along the plate fins exerts a lateral force there. By receiving, the cooling fluid that flows near the plate fin surface and the cooling fluid that flows away from the plate fin surface are mixed, and the temperature boundary layer is collapsed to increase the cooling performance. There is no effect. In the arrangement of Patent Document 3, such a lateral force does not occur.

  In Patent Document 3, the fin is not inclined with respect to the base plate surface. Therefore, the cooling fluid cannot be stirred in a direction perpendicular to the base plate surface. However, in the present invention, since the cooling fluid can be stirred in a direction perpendicular to the base plate surface, the cooling performance is higher.

In Patent Document 4, a plurality of cooling fins that form a convex shape toward the upstream side of the flow of the cooling fluid are arranged in substantially the same straight line along the flow direction of the cooling fluid.
The object of the invention of Patent Document 4 is to bring the Karman vortex generated at the rear end of the upstream cooling fin into contact with the high resistance region of the downstream cooling fin.

On the other hand, since the present invention does not intend a Karman vortex, the fin shape is simply a plate shape.
Further, as described above, in the present invention, a lateral force is applied to the cooling fluid in the space between the fin groups as described above. There is no suggestion.

  In Patent Document 4, the fin is not inclined with respect to the base plate surface. Therefore, the cooling fluid cannot be stirred in a direction perpendicular to the base plate surface. However, in the present invention, since the cooling fluid can be stirred in a direction perpendicular to the base plate surface, the cooling performance is higher.

According to the present invention, it is possible to obtain a heat sink that has high cooling performance and that suppresses pressure loss that occurs when a cooling fluid flows.
Further, when the heat sink of the present invention is formed by pressing from a single metal plate, it is possible to manufacture more easily.
Further, when the heat sink of the present invention is made of aluminum or aluminum alloy having high thermal conductivity, heat can be efficiently transferred from the base plate to the end of the fin unit.

It is a perspective view of the heat sink 100 of 1st Embodiment. (A) is the fragmentary sectional view which showed the state by which the plate-shaped fin 13 of the fin unit 10 was joined to the base plate 11 with the brazing material 15. FIG. (B) is a partial cross-sectional view showing a state in which the plate-like fins 13 of the fin unit 10 are crimped to the base plate 11 by the crimping portion 16. It is sectional drawing which showed the fin unit 10 of 1st Embodiment in the plane of the baseplate. It is the graph which showed the change of maximum temperature rise value (DELTA) T and pressure loss (DELTA) P accompanying the change of deviation angle (gamma). It is sectional drawing which showed the fin unit 20 of 2nd Embodiment in the plane of the baseplate. It is sectional drawing which showed manufacture of the fin unit 20 of 2nd Embodiment. It is a perspective view of the fin unit 30 of 3rd Embodiment. It is a perspective view of the heat sink 400 of 4th Embodiment. It is the perspective view which showed inlet part Ti and outlet part To of the cooling fluid.

(First embodiment)
FIG. 1 is a perspective view of a heat sink 100 according to the first embodiment. Here, the base plate 11 is the XY plane, the “D direction” of the cooling fluid indicated by the arrow AR from the upstream side to the downstream side is the X axis direction, and the direction perpendicular to the base plate 11 is the Z axis direction. As can be seen from the definition of “D direction”, the −X side of the heat sink 100 is the cooling fluid inflow side, and the + X side is the cooling fluid outflow side. Air, water, antifreeze, oil (oil), etc. are used as the cooling fluid. However, when the cooling fluid is a liquid such as water, antifreeze, or oil (oil), a structure including a cover plate (see the fourth embodiment) is preferably provided so that the cooling fluid does not leak.

  As shown in FIG. 1, the heat sink 100 is attached to a heat generating component 12 such as a semiconductor element, an integrated circuit, or a CPU. Although the heat generating component 12 is drawn to help understanding, it is not attached to the heat sink 100. Further, although the heat generating component 12 is drawn larger than the base plate 11 to help understanding, there are cases where the heat generating component 12 is actually smaller than the base plate 11. The heat sink 100 includes a base plate 11 placed in close contact with the XY plane of the heat generating component 12 and a fin unit 10 thermally connected to the base plate 11. The fin unit 10 includes a first fin group 10A, a second fin group 10B, and a third fin group 10C arranged in parallel along the D direction. These fin groups are composed of, for example, six plate-like fins 13 that are parallel to each other. Further, the first fin group 10A, the second fin group 10B, and the third fin group 10C are arranged so as to be shifted in the Y-axis direction so that the corresponding plate-like fins 13 are not arranged on the same plane. Furthermore, the heat sink 100 shown in FIG. 1 is drawn with only one fin unit 10 composed of 18 plate-like fins 13 arranged in six rows in the Y-axis direction and three rows in the X-axis direction. Dozens to hundreds of fin units 10 may be provided.

  In the fin unit 10, the plate-like fins 13 are formed of a metal having good thermal conductivity such as aluminum or an alloy thereof. Further, the fin unit 10 is thermally connected by caulking or the like with one of the long sides of the plate-like fins 13 brazed to the base plate 11. The plate-like fins 13 are inclined with respect to the base plate 11 at an inclination angle β. Here, the inclination angle β is 20 ° ≦ β ≦ 80 °. As described above, if the plate-like fins 13 are disposed on the base plate 11 at an inclination, the cooling fluid is stirred in a direction perpendicular to the base plate 11 (Z-axis direction). For this reason, the cooling performance of the heat sink 100 becomes higher.

  FIG. 2A is a partial cross-sectional view showing a state in which the plate-like fins 13 of the fin unit 10 are joined to the base plate 11 with the brazing material 15. As shown in FIG. 2A, the plate-like fins 13 are obliquely contacted with the base plate 11 by the brazing material 15 at an inclination angle β. For thermal joining, the brazing material 15 may be placed and heated. However, if the brazing sheet is used as a material for any member, the brazing material 15 is already clad on the brazing sheet. Assembling work becomes easier.

  FIG. 2B is a partial cross-sectional view showing a state where the plate-like fins 13 of the fin unit 10 are crimped to the base plate 11 by the crimping portion 16. In FIG. 2B, the caulking portion 16 is provided on the base plate 11, and the plate-like fins 13 are joined by the caulking portion 16. Therefore, the groove portion 17 is provided in the base plate 11, and the plate-like fin 13 is inserted into the groove portion 17. Here, the plate-like fins 13 are inserted into the base plate 11 so that the angle between the plate-like fins 13 and the base plate 11 is also β. Thereafter, the plate-like fins 13 are caulked in the −Y axis direction by the caulking portion 16 provided on the base plate 11. With such a configuration, the plate-like fins 13 and the caulking portion 16 of the base plate 11 are connected with a larger area, and heat exchange is promoted. Therefore, the fin unit 10 improves heat transfer with the heat-generating component and improves heat dissipation characteristics.

  FIG. 3 is a cross-sectional view showing the fin unit 10 (for example, arranged by a crimping portion) in the plane of the base plate 11. In the example shown in FIG. 3, the length L in the X-axis direction of the plate-like fins 13 is about 15 to 20 mm, and the interval P between the plate-like fins 13 parallel to each other is about 0.8 to 3 mm. Further, the distance a in the X-axis direction between adjacent fin groups is 0.8 P or more and 0.3 L or less. However, the above-described dimensions are merely examples of the present invention to help understanding, and of course the present invention is not limited to these dimensions.

  If the distance a becomes smaller than 0.8P, the distance until the cooling fluid exits the first fin group 10A and enters the second fin group 10B is too short, for example. For this reason, the cooling fluid that has flowed near the surface of the plate-like fin 13 of the first fin group 10A and the cooling fluid that has flowed away from the surface of the plate-like fin 13 are not sufficiently mixed. . Moreover, the pressure loss of the part will become large. Therefore, the distance a is preferably 0.8 P or more.

  Here, the reason why the value of the distance a is proportional to the interval P between the plate-like fins 13 is as follows. If the interval P between the plate-like fins 13 is large, the degree of separation between the cooling fluid that flows near the surface of the plate-like fin 13 and the cooling fluid that flows away from the surface is also large. . For this reason, in order to mix them, it is necessary to lengthen the section (namely, space between the 1st fin group 10A and the 2nd fin group 10B) which flows while receiving the force of a horizontal direction. On the contrary, when the interval P between the plate-like fins 13 is small, a shorter distance may be used.

  On the other hand, the distance a is preferably 0.3 L or less. The distance a is a space between adjacent fin groups, and since this space is between the fin groups, the plate-like fins 13 do not exist. For this reason, when a / L is large, that is, when the distance a is large compared to the length L of the plate-like fins 13, the proportion of the space where the plate-like fins 13 do not exist is large. For example, when the dimension of the fin unit 10 as a whole is determined to be a predetermined value, if the space between adjacent fin groups is too large, the number of fin groups that can be included in the dimension (number of plate-like fins 13). Will decrease.

  If the distance a is larger than 0.3 L, the cooling performance is not reduced because the total surface area of the plate fins becomes smaller than the cooling performance improvement effect based on the mixing of the cooling fluids. The influence wins. For this reason, cooling performance will fall. Therefore, the distance a is preferably 0.3 L or less.

As described above, in order for the distance a to be not less than 0.8P and not more than 0.3L, it is necessary that P and L have at least the following relationship.
0.8P ≦ a ≦ 0.3L
Dividing both sides of this equation by 0.8
P ≦ a / 0.8 ≦ (0.3 / 0.8) * L
That is, P ≦ (3/8) L
That is, at least the interval P between the plate-like fins 13 needs to be about 0.4 or less of the length L of the plate-like fins 13.

Next, how the maximum temperature rise value ΔT of the base plate and the pressure loss ΔP of the cooling fluid change when the size of the distance a between the fin group of the fin unit is changed. The results of specific investigation by simulation calculation will be described. Table 1 shows parameters and calculation results of the three fin units I to III.
In addition, since the case where the dimension as the whole fin unit is decided to the predetermined value is assumed, the length L of the cross section parallel to the baseplate surface of a plate-shaped fin is also changing by changing a.
As simulation conditions, the material of the fin and the base plate is aluminum, and the base plate is thermally connected to the heat generating component. Further, water is used as the cooling fluid, and the front flow velocity at the inlet is 0.1 m / s.

  In the fin units I to III shown in Table 1, the distance a satisfies the condition of 0.8 P or more and 0.3 L or less. In this case, the maximum temperature rise value ΔT is 110 ° C. or less and the cooling performance is excellent, and the pressure loss ΔP is 600 Pa or less and the pressure loss is small.

  Further, when several tens to several hundreds of fin units 10 are provided on the base plate 11, it is desirable to arrange them while satisfying the above-described distance P and distance a.

  Now, the long side direction of the plate-like fin 13 of the fin unit 10 forms a deviation angle γ with respect to the D direction. Here, the deflection angle γ is preferably 1 ° to 5 °. FIG. 4 is a graph showing simulation results relating to the maximum temperature rise value ΔT of the base plate and the pressure loss ΔP of the cooling fluid when the bias angle γ is changed.

The graph shown in FIG. 4 is a simulation performed under the following calculation conditions.
In the simulation, aluminum was used as the material for the fin unit 10 and the base plate 11. As the fin unit 10, the length L in the X-axis direction of the plate fins 13 is 17.5 mm, the interval P between the plate fins 13 is 0.9 mm, and the distance a between the fin groups is 2 mm. “Fin Unit I” was used. Furthermore, water was used as the cooling fluid, and the flow velocity on the inflow side (−X axis direction) was set to 0.1 m / s.

  As shown in FIG. 4, when the deflection angle γ is less than 1 °, the maximum temperature rise ΔT of the base plate is 110 ° C. or more, and the cooling performance is low. When the deflection angle γ is larger than 5 °, the pressure loss ΔP is 600 Pa or more, and the pressure loss is too large. Therefore, it is desirable that the deflection angle γ is 1 ° to 5 °. In particular, when the deflection angle γ is 3 ° to 5 °, the maximum temperature rise value ΔT is 100 ° C. or less, and the pressure loss ΔP is 600 Pa or less.

  Returning to FIG. 1, the flow of the cooling fluid will be described. The cooling fluid exits the first fin group 10A and faces the second fin group 10B in the D direction, and exits the second fin group 10B and faces the third fin group 10C in the D direction. The plate-like fins 13 of the fin unit 10 have a bias angle γ with respect to the D direction in the long side direction. For this reason, when the cooling fluid flowing along the plate-like fins 13 flows out of the first fin group 10A or the second fin group 10B, it receives a force in the D direction that differs from the flow direction by an angle γ.

  For this reason, for example, the cooling fluid that has flowed as a laminar flow while forming a temperature boundary layer along the plate-like fins 13 of the first fin group 10 </ b> A is disturbed and the temperature boundary layer is destroyed. It becomes. In addition, the cooling fluid that has flowed away from the surface of the plate-like fins 13 of the first fin group 10A and is still at a low temperature is next to the vicinity of the surface of the plate-like fins 13 of the first fin group 10A. The second fin group 10 </ b> B enters the second fin group 10 </ b> B while being mixed with the flowing cooling fluid. Thereby, the cooling performance of the heat sink 100 is enhanced.

(Second Embodiment)
FIG. 5 is a cross-sectional view showing the fin unit 20 of the second embodiment in the plane of the base plate 11. As shown in FIG. 5, the heat sink 200 of the second embodiment includes a first fin group 20A, a second fin group 20B, and a third fin group 20C having the same shape as the fin group described in the first embodiment. ing.

  As can be seen from the reference lines BL1 to BL6, the corresponding plate-like fins 23 of the fin groups 20A to 20C are arranged on the same common XY plane. When viewed from the reference line BL1, the three plate-like fins 23 in the first row on the most −Y side of each of the fin groups 20A to 20C are arranged on the same plane. When viewed from the reference line BL2, the three plate-like fins 23 in the second row of the fin groups 20A to 20C are arranged on the same plane. The same applies to the reference line BL6. That is, the 18 plate-like fins 23 shown in FIG. 5 are arranged in six planes (planes each including the reference lines BL1 to BL6), and the six planes are parallel to each other.

According to such a configuration, since the position of each plate-like fin 23 is easily grasped, the manufacture becomes easier. Also, a long plate-like fin common to each of the fin groups 20A to 20C is provided on the base plate 11 in advance, and then a slit with a distance a for each length L is cut in a direction perpendicular to the D direction. It is.
This manufacturing method will be described in detail with reference to FIG. FIG. 6 is a cross-sectional view illustrating the manufacture of the fin unit 20 of the second embodiment.

  First, as shown in FIG. 6A, six plate-like fin semi-finished products 23R having a length in the X-axis direction of (3L + 2a) are erected on the base plate 11 in parallel. Here, the plate-shaped fin semi-finished products 23R are spaced from each other, and each plate-shaped fin semi-finished product 23R has a deviation angle γ (1 ° to 5 °) with respect to the D direction in the long side direction. Further, the inclination angle β between each plate-like fin semi-finished product 23R and the base plate 11 is 20 ° ≦ β ≦ 80 °.

Thereafter, each plate-like fin semi-finished product 23R is cut along two pairs of cut lines CL extending in the Y-axis direction shown in FIG. Here, the distance between the pair of cut lines CL is a, and the distance a is 0.8P or more and 0.3L or less.
The reason for the dimension range of the second embodiment is as described in the first embodiment.

(Third embodiment)
FIG. 7 is a perspective view of the fin unit 30 of the third embodiment. As shown in FIG. 7, the fin unit 30 is formed by pressing a single metal plate such as aluminum. The fin unit 30 includes a plurality of plate-like fins 33 formed by cutting and raising in the −Z-axis direction, and a frame portion 34 that remains connected to the plurality of plate-like fins 33 without being cut and raised. Further, the fin unit 30 is connected to the base plate 11 by brazing or the like at the long side at the −Z side end of the plate fin 33. The frame portion 34 is connected to the + Z side end of the plate fin 33. The fin unit 30 includes a first fin group 30A, a second fin group 30B, and a third fin group 30C, each of which includes, for example, four plate-like fins 33 parallel to the X-axis direction arranged in the Y-axis direction. Have. Although one fin unit 30 is illustrated in FIG. 7, several tens to several hundreds of fin units 30 may be provided.

  In the fin groups 30 </ b> A to 30 </ b> C, the plate-like fins 33 having a length L in the X-axis direction are formed in parallel so as to be spaced apart in the Y-axis direction. Here, since each plate-like fin 33 is formed by pressing a single metal plate, the width of the short side is substantially the same as the interval P. Each plate-like fin 33 has a deflection angle γ (1 ° to 5 °) with respect to the D direction in the long side direction. Further, the inclination angle β between each plate-like fin 33 and the base plate 11 (XY plane, not shown in FIG. 7) is 20 ° ≦ β ≦ 80 °. If the plate-like fins 33 are thus inclined with respect to the base plate 11, the cooling fluid is stirred in a direction perpendicular to the base plate 11. Further, when the inclination angle β is set to 30 ° ≦ β ≦ 60 °, there is an effect that press molding is easy.

The distance between the fin groups 30A to 30C is a, and the distance a is 0.8P or more and 0.3L or less. The reason for setting the above-described dimension range is as described in the first embodiment.
In the third embodiment, the arrangement method of the plate-like fins 23 described in the second embodiment can also be applied. That is, the plate-like fins 33 corresponding in the X-axis direction may be arranged on the same plane.

(Fourth embodiment)
FIG. 8 is a perspective view of the heat sink 400 of the fourth embodiment. In the fourth embodiment, liquid such as water, antifreeze or oil is used as the cooling fluid. When the cooling fluid is a liquid, the cover plate 18 is provided so that the cooling fluid flows in the sealed space.

  Compared to the heat sink 100 of the first embodiment, the heat sink 400 of the fourth embodiment has an outer periphery excluding the inflow side and the outflow side (not shown) so that liquid cooling fluid does not leak to the + Z side of the fin unit 10. A cover plate 18 for closing is provided. Here, the cover plate 18 is drawn with a dotted line so that the fin unit 10 can be seen through. Although not shown here, in order to prevent the cooling fluid from leaking, both the left and right sides of the fin unit 10, that is, the side surfaces on the + Y side and the −Y side must be closed. Of course, the cover plate 18 is provided. Since other configurations are the same as those of the heat sink 100 of the first embodiment, description thereof is omitted.

  Moreover, although it demonstrated using the fin unit 10 demonstrated in 1st Embodiment in 4th Embodiment, it is applied also to the fin units 20 and 30 demonstrated in 2nd and 3rd embodiment.

(Application examples)
An application example of the heat sinks 100 to 400 described in the first to fourth embodiments will be described with reference to FIG. FIG. 9 is a perspective view showing the inlet portion Ti and the outlet portion To of the cooling fluid.

  As shown in FIG. 9, an inlet portion Ti is provided on the inflow side (−X side) of the fin unit 50 in the D direction (X-axis direction), and an outlet portion To is provided on the outflow side (+ X side). Is provided. Here, the fin units 10 to 40 described in the first to fourth embodiments are applied to the fin unit 50.

  When the width W in the Y-axis direction of the inlet portion Ti and the outlet portion To is increased, it is preferable to increase the length S in the D direction at the inlet portion Ti and the outlet portion To according to the width W. This is because the pressure of the cooling fluid is uniformly applied to the fin unit 50.

The optimum embodiment of the present invention has been described in detail above. However, as will be apparent to those skilled in the art, the present invention can be implemented with various modifications and variations within the technical scope thereof.
In the present invention, the material of the fin unit is aluminum or aluminum alloy from the viewpoint of thermal conductivity and cost. However, the effect of the present invention is not limited even if other materials having good thermal conductivity such as copper and copper alloy are used. It is equally effective.

10, 20, 30, 50 ... Fin units 10A to 10C, 20A to 20C, 30A to 30C ... Fin group 11 ... Base plate 12 ... Heat-generating component 13, 23, 33 ... Plate-like fin 23R ... Plate-like fin semi-finished product 15 ... Low Material 16 ... Caulking part 17 ... Groove part 18 ... Cover plate 34 ... Frame part 100, 200, 400 ... Heat sink a ... Distance between fin groups L ... Plate fin length P ... Spacing between plate fins S ... Inlet part And the length in the X-axis direction of the outlet part Ti ... the inlet part To ... the outlet part W ... the width in the Y-axis direction of the inlet part and the outlet part β ... the inclination angle γ ... the deflection angle

Claims (6)

  In a heat sink in which a fin unit for conducting heat transfer to a cooling fluid is provided on a base plate to which heat-generating components are thermally connected, the fin unit has a cross-sectional length L parallel to the base plate surface. Are separated from each other by a distance a of 0.8P or more and 0.3L or less from the first fin group. And a second fin group similar to the first fin group disposed in a predetermined D direction from the upstream side to the downstream side of the cooling fluid, and the base plate of each plate-like fin A heat sink, wherein each cross section parallel to the surface forms an angle of deviation γ (where 1 ° ≦ γ ≦ 5 °) with respect to the D direction.   It is repeated in the D direction that a fin group similar to the second fin group is further arranged in the D direction at a distance a of 0.8 P or more and 0.3 L or less from the second fin group. The heat sink according to claim 1.   3. The heat sink according to claim 1, wherein the plate surface of the plate-like fin has an inclination angle β (20 ° ≦ β ≦ 80 °) with respect to the base plate surface.   4. The plate fins according to claim 1, wherein the plate fins are arranged so that plate surfaces of the plate fins of two adjacent fin groups are on the same common plane. 2. A heat sink according to claim 1.   The heat sink according to any one of claims 1 to 4, wherein the fin unit is formed by pressing a single metal plate.   The heat sink according to any one of claims 1 to 5, wherein the fin unit is made of aluminum or an aluminum alloy.