JP2005051127A - Cooling module and laminated structure of heat radiator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide the cooling module and the laminated structure of a heat radiating fin which can exhibit a sufficient cooling performance in a limited outer shape size by effectively utilizing space. <P>SOLUTION: An outlet 3 having a heat radiating member 5 is provided on the blowing side of a fan motor 2. The heat radiating member 5 is made of a plurality of heat radiating fins 11 arranged to be laminated. The heat radiating fins 11 are arranged radially from the center of the fan motor 2 at least in part of the outlet 3. Since wind smoothly flows from the fan motor 2 smoothly, a sufficient cooling performance can be obtained in a limited outer shaped size and a noise caused by the wind from the fan motor can be reduced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a cooling module having a fan suitable for cooling, for example, a microprocessor unit mounted in a personal computer (personal computer), and a laminated structure of heat radiators provided in the cooling module.

  2. Description of the Related Art Conventionally, MPUs (microprocessor units) mounted on thin electronic devices such as notebook computers have large power consumption and thus generate a large amount of heat. Cooling modules equipped with heat radiation fins and fan motors are used for cooling them (for example, patent documents). 1) is essential. In recent years, higher heat generation performance has been demanded due to an increase in the amount of heat generated with higher performance of the MPU.

  12 and 13 to 15 show conventional examples of cooling modules, respectively. Describing in order from FIG. 12, reference numeral 1 denotes a frame. The frame 1 is formed in a substantially square shape so as to surround the outer periphery of the fan motor 2 that is a blowing means, and holds the fan motor 2. Two blowing portions 3 and 4 are formed in communication with each other. In addition, the blowing units 3 and 4 are provided with heat radiating units 5 and 6 including a plurality of heat radiating fins, respectively, in such a direction as to prevent the air flow from the fan motor 2 as much as possible. A heat receiving portion 7 is attached in close contact with a heating element (not shown) such as an MPU of a notebook personal computer, and a heat pipe 8 serving as a heat transfer member is provided between the heat receiving portion 7 and the heat radiating portions 5 and 6. Is disposed. The heat pipe 8 injects a minute amount of hydraulic fluid into a tube body such as copper having excellent thermal conductivity, and circulates the hydraulic fluid inside the tube body, so that extremely excellent thermal responsiveness can be obtained. . The heat dissipating parts 5 and 6 are for receiving heat from the heat pipe 8 and exchanging heat with the air flowing through the blowing parts 3 and 4 to exhaust heat outside the cooling module. In addition, an intake hole 9 for taking air into the cooling module is formed at a position on the upper surface of the frame 1 facing the upper portion of the fan motor 2. In addition, in the corner part 10 of the flame | frame 1 between the blowing part 3 and the blowing part 4, the direction of the radiation fin of the thermal radiation part 5 and the thermal radiation part 6 is substantially orthogonal.

  Then, in the cooling module in the configuration of FIG. 12, when the fan motor 2 is rotated, air around the upper portion of the cooling module is taken in from the intake hole 9 and passes through the blowout portions 3 and 4. On the other hand, the heat received by the heat receiving portion 7 from the heating element is quickly transferred to the heat radiating portions 5 and 6 constituted by a plurality of heat radiating fins by the heat pipe 8 having excellent heat responsiveness. The heat of the heat radiating units 5 and 6 is cooled by the air from the fan motor 2 passing through the blowing units 3 and 4 and is radiated to the outside of the cooling module from two substantially orthogonal directions of the frame 1. Thereby, the temperature rise of a heat generating body can be suppressed.

  Next, the cooling module shown in FIGS. 13 to 15 will be described. As in the cooling module of FIG. 12, a frame 1 for holding the fan motor 2 is formed. The blowout part 3 is formed to communicate with only one side of the frame 1, and the blowout part 3 is formed with a heat radiation part 5 made up of a plurality of flat plate-like heat radiation fins. In addition, intake holes 9 for taking in air into the cooling module are formed at positions facing the fan motor 2 on the upper surface and the lower surface of the frame 1.

  In this case, when the fan motor 2 is rotated, the air around the upper and lower portions of the cooling module is taken in from the intake holes 9 formed in the upper and lower surfaces of the frame 1 and passes through the blowout portion 3. And the heat of the thermal radiation part 5 is cooled by the air from the fan motor 2 which passes the blowing part 3, and is thermally radiated outside the cooling module. Thereby, the temperature rise of a heat generating body can be suppressed.

16 and 17 show a conventional example of a laminated structure of radiating fins constituting the radiating portion of the cooling module (see Patent Document 2). Reference numeral 21 denotes a heat radiating fin, which is formed in a U-shaped cross section having bent side portions 23 and 23 'parallel to each other at both ends of the main body portion 22. The bent sides 23 and 23 ′ are formed with notches 24 and 24 ′ and engaging portions 25 and 25 ′ protruding from the bent sides 23 and 23 ′. Claw portions 26 and 26 'projecting inward are formed. Then, by engaging the notches 24, 24 ′ with the claw portions 26, 26 ′ of the engaging portions 25, 25 ′ of the other radiating fins 21, the other radiating fins 21 are sequentially formed at both ends of the radiating fins 21, respectively. A heat dissipating fin unit 27 is formed as a set of heat dissipating fins 21 having a fixed laminated structure. The lower surface of the laminated radiating fins 21 is in close contact with and connected to the radiating base 28 that transmits heat from the heating element. Heat conducted to the outside is released to the outside.
JP-A-8-181260 No. 3073184

  As described above, in the conventional cooling module shown in FIG. 12, the heat radiating units 5 and 6 are forcibly cooled by the air blown from the fan motor 2, thereby cooling the heating element made of the MPU. However, two blowout portions 3 and 4 are formed in communication with two substantially orthogonal directions of the frame 1, and the heat radiating portion 5 and the heat radiating portion are formed at the corner portion 10 of the frame 1 between the blowout portion 3 and the blowout portion 4. 6 because the direction of the radiating fins 6 is substantially orthogonal, the wind from the fan motor 2 strikes the radiating fins in the vicinity of the corner portion 10 of the frame 1 at a large angle. There was a problem that the exhaust air volume of the fan motor 2 decreased due to the pressure loss of the corner portion 10 and satisfactory cooling performance could not be obtained. Further, in the vicinity of the corner portion 10, no radiation fins can be provided in a substantially rectangular parallelepiped region in which the right-side radiation fins of the radiation unit 5 and the lower-side radiation fins of the radiation unit 6 in FIG. There was a problem that could not be used effectively.

  Further, in the conventional cooling module shown in FIGS. 13 to 15, it is not possible to obtain a sufficient heat radiation area of the heat radiation fins of the heat radiation portion 5 in a limited outer size, and in cooling a high heat generation MPU. There was a problem that satisfactory cooling performance could not be obtained.

  Further, in the conventional laminated structure of the radiating fins shown in FIGS. 16 and 17, the bottom surface of the radiating fin unit 27 is partially formed by the claw portions 26 and 26 ′ protruding inwardly formed in the engaging portions 25 and 25 ′. Since the bottom surface of the radiating fin unit 27 is not completely flat, the contact area between the radiating fin unit 27 and the radiating base 28 cannot be sufficiently secured. There was a problem that satisfactory heat transfer characteristics between 28 and 28 could not be obtained.

  Therefore, in view of the above problems, an object of the present invention is to provide a laminated structure of a cooling module and a radiating fin capable of obtaining sufficient cooling performance in a limited outer size by effectively using space.

  In the cooling module according to claim 1 of the present invention, the fins are arranged radially at least at a part of the blowout portion, so that the wind from the fan smoothly flows without stagnation and sufficient cooling performance in a limited outer size. And noise caused by wind from the fan can be reduced.

  In the cooling module according to claim 2 of the present invention, by forming at least a part of the fin in the curved portion, the heat radiation area of the fin can be increased in a limited outer size, and good cooling performance can be obtained. .

  In the laminated structure of the heat radiating body according to claim 3 of the present invention, the engagement means that can be engaged is provided in the main body portion, so that the side portion is formed flat and contacts with the heat radiating base that transfers heat from the heat generating body. A sufficient area can be taken, and good heat transfer characteristics can be obtained in a limited external size. Further, by providing the guide means on the side, adjacent fins can be easily maintained in a predetermined positional relationship.

  In the cooling module according to the first aspect of the present invention, the wind from the fan smoothly flows without stagnation, sufficient cooling performance can be obtained in a limited outer size, and noise from the wind from the fan can be reduced. .

  In the cooling module according to the second aspect of the present invention, the heat radiation area of the fin can be increased in a limited outer size, and good cooling performance can be obtained.

  In the laminated structure of the heat radiator according to claim 3 of the present invention, the sides can be formed flat so that a sufficient contact area with the heat radiation base for transferring heat from the heat generator can be obtained. Good heat transfer characteristics can be obtained. Moreover, adjacent fins can be easily kept in a predetermined positional relationship.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In each embodiment, the same parts as those in the conventional example are denoted by the same reference numerals.

  FIG. 1 shows a first embodiment of the present invention. A frame 1 rotatably holds a fan motor 2 as a fan which is a blowing means. The frame 1 is formed in a substantially quarter circle shape obtained by connecting two straight lines that are substantially orthogonal to each other when viewed from the upper surface and an arc connecting the two straight lines, and a portion corresponding to the arc of the substantially quarter circle shape is formed. The blowing part 3 which fully opened the side part is formed. And, along the curved surface shape of the arc of the blowout part 3, a heat dissipating part 5 comprising a plurality of heat dissipating fins 11 arranged on the arc without gaps at substantially constant intervals is provided. The directions are arranged radially about the fan motor 2 so as not to obstruct the air flow from the fan motor 2.

  A heat receiving part 7 is attached in close contact with a heating element (not shown) such as an MPU of a notebook personal computer, and a heat pipe 8 as a heat transfer member is arranged between the heat receiving part 7 and the heat radiating part 5. Established. The heat pipe 8 injects a minute amount of hydraulic fluid into a tube body such as copper having excellent thermal conductivity, and circulates the hydraulic fluid inside the tube body, so that extremely excellent thermal responsiveness can be obtained. . Further, the heat pipe 8 is formed in an arc shape according to the shape of the heat radiating portion 5, and is provided in contact with the upper portion of the heat radiating portion 5. The heat dissipating unit 5 receives heat from the heat pipe 8 and exchanges heat with the air flowing through the blowing unit 3 to exhaust heat outside the cooling module. In addition, an intake hole 9 for taking air into the cooling module is formed at a position on the upper surface of the frame 1 facing the upper portion of the fan motor 2.

  Next, the operation will be described. When the fan motor 2 is rotated, the air around the upper part of the cooling module is taken in from the intake hole 9 and passes through the blowout part 3. On the other hand, the heat received by the heat receiving portion 7 from the heating element is quickly transferred to the heat radiating portion 5 composed of a plurality of heat radiating fins by the heat pipe 8 having excellent heat responsiveness. And the heat of this thermal radiation part 5 is cooled by the air from the fan motor 2 which passes the blowing part 3, and is thermally radiated outside the cooling module. Thereby, the temperature rise of a heat generating body can be suppressed. The direction of the plurality of heat dissipating fins 11 arranged in an arc shape on the blowout portion 3 is arranged radially around the fan motor 2 so as not to hinder the air flow from the fan motor 2. The wind from the air flows smoothly without any stagnation and good cooling performance is obtained, and noise from the wind from the fan motor 2 is also reduced.

  As described above, in the present embodiment, the fan motor 2 is provided, and the blower portion 3 including the heat radiating portion 5 is provided on the air blowing side of the fan motor 2, and the heat radiating portion 5 includes a plurality of heat radiating fins 11 arranged in layers. The radiating fins 11 are arranged radially around the fan motor 2 in at least a part of the blowing portion 3.

  In this case, the wind from the fan motor has a large angle to the heat dissipating fins near the corners of the frame, as seen in a cooling module in which two blowing portions are formed in communication with two substantially orthogonal directions of the conventional frame. Therefore, the wind from the fan motor 2 is stagnated without causing a problem that noise is increased or the exhaust air volume of the fan motor is reduced due to pressure loss at the corners of the frame and satisfactory cooling performance cannot be obtained. It can flow smoothly and improve airflow performance and noise performance. Furthermore, heat radiation fins 11 can be provided near the corners of the frame, and satisfactory cooling performance can be obtained by allowing the wind from the fan motor 2 to flow radially in multiple directions by effectively using the space. .

  FIG. 2 shows a second embodiment of the present invention. In addition, the same code | symbol is attached | subjected to the same location as the said 1st Example, and since description of a common part overlaps, it abbreviate | omits as much as possible. In this embodiment, the frame 1 smoothly connects two straight lines that are substantially parallel to each other when viewed from the upper surface, and one end side of these two straight lines by a semicircular arc, and the other end side is substantially orthogonal to the two straight lines. The blowout portion 3 is formed in a shape connected by straight lines, and the side portions of the portions corresponding to the two straight lines and the semicircular arc are fully opened. And, along the shape of the blowout part 3, a heat dissipating part 5 composed of a plurality of heat dissipating fins 11 arranged on the arc without gaps at substantially constant intervals is provided, and in a portion corresponding to the semicircular arc, The direction of the radiating fins 11 is arranged radially with respect to the fan motor 2 so as not to hinder the flow of air from the fan motor 2.

  The heat pipe 8 is formed in a shape that smoothly connects two substantially parallel straight lines and a semicircular arc according to the shape of the heat radiating portion 5, and is provided in contact with the upper portion of the heat radiating portion 5. In addition, an intake hole 9 for taking air into the cooling module is formed at a position on the upper surface of the frame 1 facing the upper portion of the fan motor 2.

  Next, the operation will be described. When the fan motor 2 is rotated, the air around the upper part of the cooling module is taken in from the intake hole 9 and passes through the blowout part 3. On the other hand, the heat received by the heat receiving portion 7 from the heating element is quickly transferred to the heat radiating portion 5 composed of a plurality of heat radiating fins by the heat pipe 8 having excellent heat responsiveness. And the heat of this thermal radiation part 5 is cooled by the air from the fan motor 2 which passes the blowing part 3, and is thermally radiated outside the cooling module. Thereby, the temperature rise of a heat generating body can be suppressed. The direction of the plurality of heat dissipating fins 11 arranged in the arc shape in the blowout portion 3 is arranged radially around the fan motor 2 so as not to disturb the air flow from the fan motor 2 in a portion corresponding to the semicircular arc. As a result, the wind from the fan motor 2 flows smoothly without stagnation and good cooling performance is obtained, and noise due to the wind from the fan motor 2 is also reduced.

  As described above, in the present embodiment, the fan motor 2 is provided, and the blower portion 3 including the heat radiating portion 5 is provided on the air blowing side of the fan motor 2, and the heat radiating portion 5 includes a plurality of heat radiating fins 11 arranged in layers. The radiating fins 11 are arranged radially around the fan motor 2 in at least a part of the blowing portion 3.

  In this case, the wind from the fan motor has a large angle to the heat dissipating fins near the corners of the frame, as seen in a cooling module in which two blowing portions are formed in communication with two substantially orthogonal directions of the conventional frame. Therefore, the wind from the fan motor 2 is stagnated without causing a problem that noise is increased or the exhaust air volume of the fan motor is reduced due to pressure loss at the corners of the frame and satisfactory cooling performance cannot be obtained. It can flow smoothly and improve airflow performance and noise performance. Furthermore, satisfactory cooling performance can be obtained by causing the wind from the fan motor 2 to flow radially in multiple directions.

  FIG. 3 shows a third embodiment of the present invention. In this embodiment, two fan motors 2 and 2 ′ are provided, and the frame 1 has a curved shape that smoothly connects the outer circumferences of the two fan motors 2 and 2 ′. And the blowing part 3 which fully opened the side part of the part corresponded in the curve shape which connects the outer periphery of two fan motors 2 and 2 'smoothly is formed. A heat dissipating part 5 comprising a plurality of heat dissipating fins 11 arranged at substantially constant intervals without gaps is provided along the shape of the blow-out part 3. The fan motor 2 or the fan motor 2 is arranged as radially as possible around the fan motor 2 so as not to disturb the air flow from the fan motor 2. Further, intake holes 9 and 9 'for taking in air into the cooling module are formed at positions on the upper surface of the frame 1 facing the upper portions of the fan motors 2 and 2'.

  In this case, when the fan motors 2 and 2 ′ are rotated, the air around the upper portion of the cooling module is taken in from the intake holes 9 and 9 ′ and passes through the blow-out unit 3. The heat of the heat radiating unit 5 is cooled by the air from the fan motors 2 and 2 ′ passing through the blowing unit 3 and is radiated to the outside of the cooling module. In addition, since the direction of the several radiation fin 11 arranged in the blowing part 3 is arranged radially as much as possible centering on the fan motor 2 or the fan motor 2, the wind from fan motor 2, 2 'does not stagnate It flows smoothly and good cooling performance is obtained, and noise caused by wind from the fan motors 2 and 2 'is also reduced.

  As described above, in this embodiment, the fan motors 2 and 2 ′ are provided, and the blower unit 3 including the heat radiating unit 5 is provided on the air blowing side of the fan motors 2 and 2 ′. The fins 11 are formed in a stacked manner, and at least a part of the blowout part 3 is arranged with the heat dissipating fins 11 radially with the fan motors 2 and 2 ′ as the center.

  In this case, the wind from the fan motor has a large angle to the heat dissipating fins near the corners of the frame, as seen in a cooling module in which two blowing portions are formed in communication with two substantially orthogonal directions of the conventional frame. Therefore, the wind from the fan motor 2 is stagnated without causing a problem that noise is increased or the exhaust air volume of the fan motor is reduced due to pressure loss at the corners of the frame and satisfactory cooling performance cannot be obtained. It can flow smoothly and improve airflow performance and noise performance. Furthermore, satisfactory cooling performance can be obtained by causing the wind from the fan motor 2 to flow radially in multiple directions.

  4 to 8 show a fourth embodiment of the present invention. A flat frame 1 that forms a heat sink is formed in a substantially square shape so as to surround the outer periphery of the fan motor 2 that is a blowing means, holds the fan motor 2, and communicates in two substantially orthogonal directions of the frame 1. Two blowout portions 3 and 4 are formed. In addition, the blowing portions 3 and 4 are provided with heat radiating portions 5 and 6 as heat radiating fin units each including a plurality of heat radiating fins 11 and 12 in such a direction as to prevent the air flow from the fan motor 2 as much as possible. . Further, a heat receiving part (not shown) attached in close contact with a heating element (not shown) such as an MPU of a notebook personal computer is connected to the heat radiating part 5, and between the heat radiating part 5 and the heat radiating part 6. In order to quickly transfer the heat of the heating element to the heat radiating portion 6, three heat pipes 8 as heat transfer members bent in an L shape are arranged. As described above, the heat pipe 8 has an extremely excellent thermal responsiveness. However, in order to efficiently receive the heat from the heating element, the heat pipe 8 is orthogonal to the air flow from the fan motor 2, It is attached so as to straddle the full width of 4. Thus, the frame 1, the heat radiating portions 5, 6, and the heat pipe 8 are thermally connected to each other.

  In addition, an intake hole 9 for taking air into the cooling module is formed at a position on the upper surface of the frame 1 facing the upper portion of the fan motor 2. Although not shown, an intake hole for taking air into the cooling module is also formed at a position facing the lower part of the fan motor 2 on the lower surface of the frame 1. Further, the upper surface of the cooling module is formed by a thin plate-like cover 13 that constitutes the upper surface of the frame 1 and the heat radiating portions 5 and 6. The cover 13 may be formed separately corresponding to the frame 1, the heat radiating part 5, and the heat radiating part 6.

  The radiating fins 11 and 12 are made of a material having high thermal conductivity, and as shown in FIGS. 5 and 7, a part of each of the radiating fins 11 and 12 is formed in a curved surface. And the heat radiating parts 5 and 6 are formed by laminating a plurality of heat radiating fins 11 and 12 of the same shape partially formed in a curved surface in this manner at substantially equal intervals. The shape of the radiation fins 11 and 12 is as straight as possible in the exhaust direction of the fan motor 2, that is, in the longitudinal direction of the radiation fins 11 and 12, so as not to cause pressure loss. And the direction orthogonal to the exhaust direction, that is, the vicinity of the central portion in the short direction of the radiating fins 11 and 12, is formed into an arcuate curved surface. By forming a part of the radiating fins 11 and 12 in a curved surface in this way, the surface area, that is, the radiating area is increased compared to the radiating fin of the same size that does not form a curved surface. Is about 10% larger.

  Next, the operation will be described. When the fan motor 2 is rotated, air around the upper part and the lower part of the cooling module is taken in from the intake holes 9 and the intake holes on the lower surface of the frame 1 (not shown), and passes through the blowing parts 3 and 4. On the other hand, the heat from the heating element is transmitted to the heat radiating section 5 and then quickly transmitted to the heat radiating section 6 by the heat pipe 8 having excellent thermal response. And the heat of this heat radiating part 5 and 6 is cooled by the air from the fan motor 2 which passes the blowing parts 3 and 4, and is radiated outside the cooling module. Thereby, the temperature rise of a heat generating body can be suppressed. Also, part of the radiating fins 11 and 12 are curved, and the radiating area is larger compared to radiating fins of the same size that do not form a curved surface. Cooling performance can be obtained. In addition, by forming the longitudinal sections of the radiation fins 11 and 12 in a straight line, the air from the fan motor 2 can be smoothly exhausted without causing pressure loss.

  As described above, in the present embodiment, the fan motor 2 is provided, and the blowing portions 3 and 4 including the heat radiating portions 5 and 6 are provided on the air blowing side of the fan motor 2, and the heat radiating portions 5 and 6 include a plurality of heat radiating portions. The fins 11 and 12 are formed in a stacked arrangement, and at least a part of the radiating fins 11 and 12 is formed into a curved surface.

  In this case, since the heat radiation area of the heat radiation fins 11 and 12 can be increased compared with the heat radiation fin of the same size that does not form a curved surface, good cooling performance can be achieved in the limited outer size of the heat radiation parts 5 and 6. Can be obtained.

  9 to 11 show a fifth embodiment of the present invention. In the figure, reference numeral 21 denotes a heat radiating fin as a heat radiating body, which is formed in a U-shaped cross section having bent side portions 23 and 23 'which are side portions parallel to each other at both ends of the main body portion 22. At substantially the center of the bent side portions 23, 23 ′, triangular cutout portions 29, 29 ′ having one end of the main body portion 22 as one side are provided, and the cutout portions 29 of the bent side portions 23, 23 ′ are provided. , 29 ′ are provided so as to protrude from the portion where the flat ridges 30, 29 ′ are formed. Then, when the guide portions 30, 30 'of the radiating fins 21 adjacent to the notches 29, 29' are fitted and the plurality of radiating fins 21 are stacked, the plurality of bent side portions 23, 23 'are formed. The surfaces 31 and 31 'to be processed are configured to be flat surfaces without irregularities. The guide members 30 and 30 ′ and the notches 29 and 29 ′ constitute a guide means, and the guide members 30 and 30 ′ are fitted into another adjacent heat radiation fin 21 to be separated from another heat radiation. The alignment with the fins 21 is performed, and there is no effect of engaging with another adjacent radiation fin 21.

  On the other hand, a notch 32 is provided in the approximate center of the main body 22, and an engaging part 33 is formed protruding in a substantially horizontal direction from the lower side of the notch 32. The engaging portion 33 is initially formed flush with the main body portion 22 as shown by a dotted line in FIG. 11, and is simply as shown by a solid line in FIG. It can be tilted in a substantially horizontal direction. Further, the tip of the engagement portion 33 is formed in a T shape, and when the engagement portion 33 is tilted, the engagement portion 33 is formed in the small recess 34 formed in the notch portion 32 of the adjacent radiating fin 21. The adjacent heat dissipating fins 21 are engaged with each other. In this way, the engaging portion 33 and the notch 32 constitute an engaging means, and a plurality of radiating fins 21 are sequentially fixed to form a laminated structure, and the radiating fin unit 27 as an aggregate of the radiating fins 21. Is configured. The flat lower surface 31 ′ of the laminated radiating fins 21 is in close contact with and connected to the radiating base 28 that conducts heat from the heating element, and the heat from the radiating base 28 is conducted to the radiating fins 21, and the fan motor (not shown) The heat conducted to the heat radiating fins 21 by the wind is released to the outside.

  As described above, in this embodiment, a plurality of radiating fins 21 are formed in a stacked manner, and the radiating fins 21 are formed by connecting a main body portion 22 and an end portion of the main body portion 22 at a substantially right angle. Side portions 23 and 23 ', and an engaging portion 33 and a notch portion 32, which are engaging means that can be engaged with the adjacent radiating fins 21, are provided in the main body portion 22, and between the adjacent radiating fins 21 Guide portions 30 and 30 ′, which are guide means for positioning, and notches 29 and 29 ′ are provided on the bent side portions 23 and 23 ′.

  In this case, by providing the main body portion 22 with the engaging portion 33 and the notch portion 32 that can be engaged with another radiating fin 21, surfaces 31 and 31 ′ formed by the plurality of bent side portions 23 and 23 ′. Can be formed on a flat surface with no irregularities to provide a sufficient contact area with the heat dissipation base 28 that conducts heat from the heating element, and good heat transfer characteristics can be obtained within a limited external size it can. In addition, by providing guide portions 30, 30 ′ and notches 29, 29 ′ for positioning with other adjacent radiating fins 21 in the bent side portions 23, 23 ′, adjacent radiating fins 21 can be connected to each other. The predetermined positional relationship can be easily maintained.

  In addition, this invention is not limited to said each Example, A various deformation | transformation implementation is possible.

It is a perspective view of the cooling module in 1st Example. It is a top view of the cooling module in 2nd Example. It is a top view of the cooling module in 3rd Example. It is a top view of the cooling module in 4th Example. It is the side view seen from the upper part of FIG. 4 same as the above. It is an expanded sectional view of a heat dissipation part same as the above. It is the side view seen from the left of FIG. 4 same as the above. It is the side view seen from the right side of FIG. 4 same as the above. It is a perspective view of the laminated structure of the radiation fin in 5th Example. It is an expanded sectional view same as the above. It is a front view of a radiation fin same as the above. It is a top view of the conventional cooling module. It is a top view of another conventional cooling module. It is the side view seen from the upper part of FIG. 13 same as the above. It is the side view seen from the left of FIG. 13 same as the above. It is a perspective view of the laminated structure of the conventional radiation fin. It is an expanded sectional view same as the above.

Explanation of symbols

2 Fan motor (fan)
3, 4 Outlet part 5, 6 Heat dissipation part
11, 12 Radiation fin (fin)
21 Heat dissipation fin (heat sink)
22 Main unit
23, 23 'bent side (side)
29, 29 'Notch (guide means)
30, 30 'guide part (guide means)
32 Notch (engagement means)
33 Engagement part (engagement means)

Claims (3)

A cooling module comprising a fan, provided with a blowout portion, wherein the heat dissipating portion is formed by arranging fins, and the fins are arranged radially at least at a part of the blowout portion. A cooling module comprising a fan, a blowout portion, a heat dissipating portion formed by arranging fins, and at least a part of the fin being formed as a curved portion. A heat dissipating body is formed by laminating and disposing the heat dissipating body having a main body portion and a side portion formed by connecting to the main body portion. Is provided on the side portion.

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