JP4875452B2 - Heat sink with centrifugal fan for heat dissipation - Google Patents

Description

  The present invention relates to a heat sink with a centrifugal fan provided with a heat radiating fin, and more particularly to a heat sink with excellent cooling efficiency that rectifies the wind flowing from the centrifugal fan through the heat radiating fin.

  A heat generation amount and a heat generation density of a heat generating portion such as a CPU and an element mounted on a substrate are increased, and a high performance heat sink that efficiently dissipates them is demanded. In personal computers as well, CPUs, graphic chips (GPU or VGA), chipsets and other elements that require active heat dissipation have increased. On the other hand, a reduction in thickness has been demanded.

As the amount of heat generation increases, it becomes difficult to cope with the combination of the radiation fin and the heat pipe, and a method of forcibly radiating the heat of the heating element moved to the radiation fin by the heat pipe by the fan has been adopted.
That is, a heat sink with a centrifugal fan is used in which the heat of the heat generating element is moved to the heat radiating fin portion by a heat pipe, cold air is sent to the heat radiating fin portion by a fan, and the heat of the heat generating element is released to the outside of the casing.

  A centrifugal fan is placed in a cavity formed by the top, bottom, and wall surfaces, and heat radiating fins are placed facing the centrifugal fan. The wind generated by the centrifugal fan passes through the individual heat radiating fins to enhance the heat radiation effect. be able to. Furthermore, a heat sink is thinned by arrange | positioning a centrifugal fan in the cavity part formed by an upper surface, a bottom face, and a wall surface, and arrange | positioning a radiation fin facing a centrifugal fan.

FIG. 7A is a schematic sectional view for explaining a conventional heat sink with a centrifugal fan. FIG.7 (b) is a graph which shows the air volume which passes the radiation fin by the conventional centrifugal fan. As shown in FIG. 1 (a), a centrifugal fan 101 is disposed in a cavity formed by an upper surface, a bottom surface, and a side wall surface. A heat radiating fin portion 102 is arranged facing the centrifugal fan. One end of the heat pipe is thermally connected to the heat generating element (not shown), and the other end of the heat pipe is thermally connected along the long axis direction of the radiation fin. The heat of the heat generating element is moved to the heat radiating fin portion by the heat pipe, and the heat moved to the heat radiating fin portion is released to the outside of the housing by the wind from the centrifugal fan and radiated.
JP-A-9-172113

  As shown in FIG. 7, when the centrifugal fan is rotated with the heat radiating fin portion facing the centrifugal fan, the amount of air passing through the heat radiating fin by the rotation of the centrifugal fan is radiated with respect to the rotation direction of the fan. The air volume at the nearest end of the fin portion increases, and the air volume decreases along the long axis direction of the radiating fin portion. That is, a large amount of wind passes at the near end of the radiating fin, but the amount of air passing through the far end of the radiating fin is small. In this way, the amount of air passing through the radiating fin portion is not flattened, and part of the air amount becomes excessive, sufficient air does not pass in other portions, and the heat radiating efficiency of the radiating fin portion is low. There is a point.

  Accordingly, an object of the present invention is to provide a thin heat sink with a centrifugal fan by rectifying the wind passing through the heat dissipating fin portion facing the centrifugal fan, increasing the heat dissipating efficiency of the heat dissipating fin portion, reducing noise, and thin. There is.

  The inventor conducted extensive research to solve the conventional problems. As a result, the flow of the wind generated by the centrifugal fan is restricted to the portion closest to the rotation direction of the radiating fin portion located facing the centrifugal fan disposed in the cavity formed by the top surface, the bottom surface, and the side wall surface. If the rectifying pieces are arranged so that the wind passing through the individual radiating fins is rectified, the flow of the wind passing through the radiating fins where the amount of wind has been the largest in the past is restricted, and the entire radiating fin portion It has been found that the heat dissipation efficiency of the heat dissipating fin portion is increased since the air flows flattened.

  Further, when the rectifying piece described above is attached, the rectifying piece is arranged so as to form a predetermined angle with the long axis direction of the radiating fin, and the rectifying piece is attached to the top surface portion or the bottom surface portion, and the corresponding top surface portion or bottom surface It has been found that the amount of wind passing between the individual radiating fins can be more effectively flattened when a predetermined gap through which the wind flows is provided between the radiating fins.

A first aspect of the present invention is a centrifugal fan that blows air taken in from an air intake port in a tangential direction of a rotation circle of the fan;
A plurality of radiating fins are arranged in parallel, one end of which is thermally connected to the other end of the heat pipe that is thermally connected to the heating element, and the wind from the centrifugal fan passes through At least one radiating fin portion;
A cavity portion for accommodating the centrifugal fan, each formed by a top surface portion and a bottom surface portion each having an air intake, and a side wall portion having an opening in which the radiation fin portion is disposed;
It is attached to the upper surface portion or the bottom surface portion in the vicinity of the blower opening of the centrifugal fan, and has a predetermined gap through which air flows between the upper surface portion or the bottom surface portion opposed to the attached upper surface portion or the bottom surface portion. A heating element comprising a rectifying piece and a rectifying piece that regulates the flow of wind passing through the radiating fin portion by restricting the flow of the wind passing through the radiating fin located at a proximal end portion of the ventilation start position of the centrifugal fan It is a heat sink with a centrifugal fan for heat dissipation .

According to a second aspect of the present invention , the rectifying piece is substantially formed of a triangular prism shape, and is arranged vertically so that one surface of the triangular prism shape object forms a predetermined angle with the major axis direction of the heat radiating fin. It is a heat sink with a centrifugal fan for radiating heat generating elements .

A third aspect of the present invention is a heat sink with a centrifugal fan for heat-dissipating a heat generating element , wherein the rectifying piece includes a slit, and the width of the slit is gradually increased from the near end.

A fourth aspect of the present invention is a heat sink with a centrifugal fan for radiating a heat generating element , wherein the rectifying piece has an opening, and the air volume is regulated by the opening.

According to a fifth aspect of the present invention , there is provided a heat sink with a centrifugal fan for radiating heat generating elements , wherein the rectifying piece is formed of a group of fine metal wires wound spirally, and the air volume is regulated by the fine metal wire group.

A sixth aspect of this invention, heating said heat dissipating fin portion thermally connected to the surface opposite another heat radiating fins on the surface of the other end of the heat pipe is thermally connected It is a heat sink with a centrifugal fan for element heat dissipation .

  According to the heat sink with a centrifugal fan of the present invention, the centrifugal fan is attached to the cavity formed by the top surface, the bottom surface, and the side wall surface, and the heat dissipating fin portion is disposed facing the centrifugal fan. Since a rectifying piece that regulates the flow of wind, for example, a triangular prism-shaped object, is provided at the near end of the fin portion, the air passing through the individual radiating fins of the radiating fin portion from the centrifugal fan is rectified. The heat radiation efficiency of the part can be increased and noise can be reduced.

A heat sink with a centrifugal fan of the present invention will be described with reference to the drawings.
One aspect of the heat sink with a centrifugal fan according to the present invention includes: a centrifugal fan that blows air in a predetermined direction; and at least one heat dissipating fin portion in which a plurality of heat dissipating fins are arranged in parallel, through which air from the centrifugal fan passes. It is a heat sink with a centrifugal fan provided with the rectification piece which regulates the flow of the wind produced by the centrifugal fan so that the wind which passes through each radiation fin of the radiation fin part may be rectified.
The height of the rectifying piece may be the same as the height of the radiating fin, or may be smaller than the radiating fin portion or the radiating fin.

FIG. 1 is a schematic view for explaining a centrifugal fan and a rectifying piece attached to the upper surface of a heat sink with a centrifugal fan of the present invention. That is, FIG. 1 is a view of the centrifugal fan and the rectifying piece attached to the upper surface 3 of the heat sink as viewed from the back side.
The heat sink 1 with a centrifugal fan includes a hollow portion formed by overlapping a cover formed of an upper surface 3, a main body portion integrally formed with a bottom surface 5 and a side wall surface 6. Centrifugal fan 2 is accommodated in the cavity. A part of the wall surface part 6 has an opening, and a heat radiating fin part 7 is attached to the opening so as to face the centrifugal fan 2. An air intake port 8 of a centrifugal fan is formed on each of the upper surface 3 and the bottom surface 6.

  The radiating fin portion 7 is formed, for example, by arranging a plurality of generally U-shaped radiating fins including an upper surface portion, a vertical surface portion, and a bottom surface portion in parallel. A passage 10 having a rectangular cross section is formed from the upper surface portion, the bottom surface portion, the vertical surface portion, and the adjacent vertical surface portion by the radiating fins formed in parallel. The wind generated by the centrifugal fan passes through the passage described above.

  FIG. 2 is a view for explaining the main body portion in which the bottom surface and the side wall surface of the heat sink with centrifugal fan of the present invention are integrally formed. The centrifugal fan 2 and the rectifying piece 4 attached to the upper surface 3 described above with reference to FIG. 1 are accommodated in the cavity of the main body shown in FIG. That is, the upper surface 3 is attached to the main body of the heat sink so that the centrifugal fan 2 faces the air intake port 8.

Thus, in the heat sink with a centrifugal fan of the present invention, the centrifugal fan 2 is housed in the cavity formed by the upper surface portion 3 and the bottom surface portion 5 and the side wall portion 6 each having the air intake port 8. The radiating fin portion 7 is provided in the opening of the side wall portion 6, and the rectifying piece 4 is attached to the upper surface portion.
In addition, in the aspect shown in FIG. 1 and 2, although the rectifying piece 4 is attached to the upper surface part, it is not limited to this, A rectifying piece may be attached to a bottom face part.

  The rectifying piece 4 is generally composed of a triangular prism-shaped object, and is arranged perpendicularly so that one surface of the triangular prism-shaped object forms a predetermined angle with the major axis direction of the radiation fin. That is, the wind generated by the centrifugal fan changes its direction and flows along one surface arranged perpendicular to the triangular prism shape. As a result, the amount of air flowing through the portion of the radiating fin at the nearest end in the rotation direction of the centrifugal fan is restricted, and accordingly, the amount of air that is also sufficient for the portion of the radiating fin at the farthest end in the rotation direction of the centrifugal fan. Wind flows, and the flow of wind is rectified as the entire heat dissipating fin portion.

  The rectifying piece 4 is attached to the upper surface portion with a predetermined gap through which wind flows between the rectifying piece 4 and the bottom surface portion. By attaching the rectifying piece to the upper surface portion in this way, a part of the wind generated by the centrifugal fan flows directly to the portion of the heat dissipating fin portion at the nearest end in the rotational direction of the centrifugal fan, and the main force is a triangular prism as described above. The direction is regulated along the vertical surface of the shaped object. In addition, the angle between the long axis direction of the radiating fin formed by the vertical surface of the triangular prism-shaped object and the size of the gap formed between the bottom surface part rectifies the wind flowing through the entire radiating fin part. Is set to

  FIG. 3 is a schematic perspective view showing a centrifugal heat sink according to the present invention. That is, FIG. 3 is a perspective view of the heat sink formed by incorporating the upper surface portion including the centrifugal fan and the rectifying piece shown in FIG. 1 into the main body portion shown in FIG. As shown in FIG. 3, a centrifugal fan is housed and fixed in a cavity formed by an upper surface portion, a side wall portion, and a bottom surface portion. Similar to the bottom surface, an air intake 8 is also formed on the top surface. A centrifugal fan is visible through the air intake.

  The direction of rotation is indicated by an arrow in the figure. The radiating fin portion is provided facing the centrifugal fan. With respect to the rotation direction of the centrifugal fan, the triangular prism-shaped object 4 as the rectifying piece described above is disposed at the closest end (indicated by a dotted line). One vertical surface (here, the surface facing the centrifugal fan) of the triangular prism-shaped object is attached to the upper surface portion so as to form a predetermined angle. A predetermined gap through which the wind of the centrifugal fan passes is provided between the tip and bottom of the triangular prism-shaped object attached to the upper surface.

  Although not shown, the other end of the heat pipe 9 whose one end is thermally connected to the heat generating element is thermally connected to the radiating fin. It is preferable that the other end portion of the heat pipe is disposed along the long axis direction of the radiating fin portion. Thus, by disposing the heat dissipating fin portion relative to the centrifugal fan and arranging the triangular prism-shaped object that is the rectifying piece as described above, the amount of wind passing through the heat dissipating fin portion is in the long axis direction of the heat dissipating fin portion. The heat dissipation efficiency is significantly improved and noise is reduced.

  FIG. 4 is a schematic perspective view showing a centrifugal heat sink according to the present invention. That is, FIG. 3 is a perspective view of the heat sink formed by incorporating the upper surface portion including the centrifugal fan and the rectifying piece shown in FIG. 1 into the main body portion shown in FIG. As shown in FIG. 4, the centrifugal fan 2 is housed and fixed in a cavity formed by the upper surface portion, the side wall portion, and the bottom surface portion. As with the top surface, an air intake 8 is also formed in the bottom surface. The centrifugal fan 2 is visible through the air intake.

  The direction of rotation is indicated by an arrow in the figure. The radiating fin portion 7 is provided facing the centrifugal fan 2. With respect to the rotation direction of the centrifugal fan, the triangular prism-shaped object 4 as the rectifying piece described above is disposed at the closest end (indicated by a dotted line). One vertical surface (here, the surface facing the centrifugal fan) of the triangular prism-shaped object is attached to the upper surface portion so as to form a predetermined angle. A predetermined gap through which the wind of the centrifugal fan passes is provided between the tip and bottom of the triangular prism-shaped object attached to the upper surface.

  As shown in the drawing, the other end of the heat pipe 9 whose one end is thermally connected to the heat generating element (not shown) is thermally connected to the radiating fin. As shown in FIG. 4, the other end of the heat pipe is preferably arranged along the long axis direction of the heat radiating fin. Thus, by disposing the heat dissipating fin portion relative to the centrifugal fan and arranging the triangular prism-shaped object that is the rectifying piece as described above, the amount of wind passing through the heat dissipating fin portion is in the long axis direction of the heat dissipating fin portion. The heat dissipation efficiency is significantly improved and noise is reduced.

In the heat sink with centrifugal fan of the present invention described with reference to FIGS. 1 to 4, the triangular prism-shaped object has been described as the rectifying piece for regulating the air flow of the centrifugal fan. However, as the rectifying piece, a rectifying piece having a slit is used. There may be.
FIG. 5 is a diagram illustrating a state where a rectifying piece having a centrifugal fan and a slit is attached to the upper surface. In the rectifying piece provided with the slit, for example, the width of the slit may gradually increase from the near end.

  The upper surface portion provided with the centrifugal fan and the rectifying piece in the embodiment shown in FIG. 5 is attached to the hollow portion of the main body portion shown in FIG. 2 so that the centrifugal fan 2 and the rectifying piece 4 are accommodated. That is, the upper surface 3 is attached to the main body of the heat sink so that the centrifugal fan 2 faces the air intake port 8. Also in the heat sink with a centrifugal fan of this aspect, the centrifugal fan 2 is accommodated in the cavity formed by the top surface portion 3 and the bottom surface portion 5 provided with the air intake port 8 and the side wall portion 6, respectively. The opening is provided with the heat radiating fin portion 7, and the rectifying piece 4 is attached to the upper surface portion.

  As described with reference to FIG. 4, the direction of rotation is indicated by an arrow in the figure. The radiating fin portion 7 is provided facing the centrifugal fan 2. With respect to the rotation direction of the centrifugal fan, the rectifying piece 4 having the slit as the rectifying piece described above is disposed at the nearest end. After the wind from the centrifugal fan passes through the slit of the rectifying piece and the air volume is regulated, it flows to the heat radiating fin portion. The air volume can be changed by changing the width of the slit.

  FIG. 6 is a view showing a state in which a rectifying piece composed of a centrifugal fan and a group of fine metal wires wound spirally is attached to the upper surface. For example, the rectifying piece formed of the spirally wound thin metal wire group may be gradually reduced in density from the near end.

  6 is attached so that the centrifugal fan 2 and the rectifying piece 4 are accommodated in the cavity of the main body shown in FIG. That is, the upper surface 3 is attached to the main body of the heat sink so that the centrifugal fan 2 faces the air intake port 8. Also in the heat sink with a centrifugal fan of this aspect, the centrifugal fan 2 is accommodated in the cavity formed by the top surface portion 3 and the bottom surface portion 5 provided with the air intake port 8 and the side wall portion 6, respectively. The opening is provided with the heat radiating fin portion 7, and the rectifying piece 4 is attached to the upper surface portion.

Also in this aspect, as described with reference to FIG. 4, the rotation direction is indicated by an arrow in the drawing. The radiating fin portion 7 is provided facing the centrifugal fan 2. With respect to the rotation direction of the centrifugal fan, the straightening piece 4 composed of the above-described spirally wound metal thin wire group is disposed at the nearest end portion. The wind from the centrifugal fan passes through the metal thin wire group wound in a spiral shape of the rectifying piece, and after the air volume is regulated, it flows to the radiating fin portion. The air volume can be changed by changing the winding density of the spirally wound metal wires.
In another aspect, the rectifying piece may include an opening, and the air volume may be regulated by the opening.

  As described above, according to the present invention, the centrifugal fan is attached to the cavity formed by the top surface, the bottom surface, and the side wall surface, and the heat dissipating fin portion is disposed facing the centrifugal fan. Since a rectifying piece that regulates the flow of wind, for example, a triangular prism-shaped object, is provided at the near end of the fin part, the wind passing through the individual radiating fins of the radiating fin part from the centrifugal fan is rectified. A heat sink with a centrifugal fan that can increase the heat dissipation efficiency of the fin portion and reduce noise can be provided.

FIG. 1 is a schematic view for explaining a centrifugal fan and a rectifying piece attached to the upper surface of a heat sink with a centrifugal fan of the present invention. FIG. 2 is a view for explaining the main body portion in which the bottom surface and the side wall surface of the heat sink with centrifugal fan of the present invention are integrally formed. FIG. 3 is a perspective view of a heat sink formed by incorporating the upper surface portion including the centrifugal fan and the rectifying piece shown in FIG. 1 into the main body shown in FIG. 2, as viewed from the front side. 4 is a perspective view of a heat sink formed by incorporating the upper surface portion including the centrifugal fan and the rectifying piece shown in FIG. 1 into the main body portion shown in FIG. 2, as viewed from the back side. FIG. 4 is a diagram illustrating another embodiment of the heat receiving plate. FIG. 5 is a diagram illustrating a state where a rectifying piece having a centrifugal fan and a slit is attached to the upper surface. FIG. 6 is a view showing a state in which a rectifying piece composed of a centrifugal fan and a group of fine metal wires wound spirally is attached to the upper surface. FIG. 7A is a schematic sectional view for explaining a conventional heat sink with a centrifugal fan. FIG.7 (b) is a graph which shows the air volume which passes the radiation fin by the conventional centrifugal fan.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Heat sink with centrifugal fan 2 Centrifugal fan 3 Upper surface part 4 Rectification piece 5 Bottom face part 6 Side wall surface 7 Radiation fin part 8 Air intake 9 Heat pipe 10 Heat radiation fin 100 Conventional heat sink 101 with centrifugal fan Centrifugal fan 102 Radiation fin part

Claims (6)

A centrifugal fan that blows air taken in from the air intake in the direction tangential to the rotation circle of the fan;
A plurality of radiating fins are arranged in parallel, one end of which is thermally connected to the other end of the heat pipe that is thermally connected to the heating element, and the wind from the centrifugal fan passes through At least one radiating fin portion;
A cavity portion for accommodating the centrifugal fan, each formed by a top surface portion and a bottom surface portion each having an air intake, and a side wall portion having an opening in which the radiation fin portion is disposed;
It is attached to the upper surface portion or the bottom surface portion in the vicinity of the blower opening of the centrifugal fan, and has a predetermined gap through which air flows between the upper surface portion or the bottom surface portion opposed to the attached upper surface portion or the bottom surface portion. A rectifying piece that regulates the flow of wind passing through the radiating fin part by restricting the flow of the wind passing through the radiating fin located at the near end of the ventilation start position of the centrifugal fan; and
A heat sink with a centrifugal fan for radiating heat generating elements . The rectifying piece is substantially formed of a triangular prism-shaped object, and one surface of the triangular prism-shaped object is arranged perpendicularly so as to form a predetermined angle with a major axis direction of the radiating fin. Heat sink with centrifugal fan for heat dissipation of heat generating elements . The heat sink with a centrifugal fan according to claim 1, wherein the rectifying piece includes a slit, and the width of the slit gradually increases from the near end. The heat sink with a centrifugal fan for radiating heat generating elements according to claim 1, wherein the rectifying piece has an opening, and the air volume is regulated by the opening. The heat sink with a centrifugal fan for radiating heat generating elements according to claim 1, wherein the rectifying piece is composed of a group of fine metal wires wound in a spiral shape, and the air volume is regulated by the group of fine metal wires. Wherein the heat dissipating fin portion and thermally separate heat dissipating fins on the surface opposite to the attached surface of the other end of the heat pipe is thermally connected, one of claims 1 to 5 1 The heat sink with a centrifugal fan for heat-emitting element heat radiation as described in the paragraph .

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