DE202014002730U1 - Heat pipe and cooling module - Google Patents

Abstract

A heat pipe comprising a pipe (10) having a first end (101), a second end (102) and a middle part (104), the first and second ends (101, 102) lying next to each other and a heat absorption part (111 ), the middle part (104) forming a heat dissipation part, extending from the first end (101) to the second end (102) and forming a circle.

Description

Technical area

The invention relates to a heat pipe and a cooling module, which can reduce costs and increase the Wärmeleiteffizienz.

State of the art

The electronic products use heat pipe and cooling module to cool the internal electronic components. The heat of the electronic components can be conducted to the cooling fins of the cooling module, which then release the heat into the ambient air.

The arrangement of the heat pipe and the cooling fins of the cooling module is limited. To solve this problem, the cooling fins are connected obliquely to one end of the heat pipe. As a result, although the cooling area is increased, the distance between the blades and the cooling fins is not uniform, whereby turbulence can be generated, so that the wind resistance and the housing are high.

Usually, the rear end (condensation zone) of the heat pipe of the cooling module with the cooling fins and the front end (evaporation zone) with a heat source (CPU and graphics chip) in contact. When the front end of the heat pipe absorbs the heat from the heat source, the heat is transferred to the rear end of the heat pipe, which conducts the heat to the cooling fins, which then releases the heat into the ambient air. However, the cooling effect of the heat pipe of the cooling module is not high because the heat conduction efficiency of the end of the heat pipe is low. The working fluid in the heat pipe can easily stand in the phase change at the end of the heat pipe, so that the end forms an ineffective end (the heat can not be transported to the end of the heat pipe or the working fluid does not flow back to the evaporation end (front end) the end (condensation zone) does not conduct the heat efficiently to the cooling fins, so that the heat conduction efficiency is low and the cooling effect is poor.

If the heat pipe is not horizontal and the rear end of the heat pipe is lower than the front end of the heat pipe, the working fluid may remain at the rear end of the heat pipe by gravity and not flow back to the front end of the heat pipe.

• 1. Hoher Windwiderstand und hohes Geräusch;
• 2. hohe Kosten;
• 3. das Ende des Wärmerohrs bildet ein wirkungsloses Ende, wodurch die Wärmeleiteffizienz und die Kühlwirkung niedrig ist.

Therefore, the conventional solution has the following advantages:

• 1. High wind resistance and high noise;
• 2. high costs;
• 3. The end of the heat pipe forms an ineffective end, whereby the Wärmeleiteffizienz and the cooling effect is low.

For this reason, the inventor has developed the present invention.

Object of the invention

The invention has for its object to provide a heat pipe that can avoid an ineffective end.

Another object of the invention is to provide a heat pipe that can reduce costs.

The invention is based on a still further object to provide a cooling module that can significantly increase the Wärmeleiteffizienz.

Yet another object of the invention is to provide a cooling module which can reduce costs and increase the cooling effect.

The invention is based on a still further object to provide a cooling module, wherein the angular range of the cooling fins can adapt to the air outlet side, whereby the wind resistance and noise are reduced.

These objects are achieved by a heat pipe comprising a pipe having a first end, a second end and a central part, wherein the first and second ends are adjacent to each other and form a heat receiving part, the middle part forms a heat release part, from the first End until the second end extends and forms a circle.

These objects are achieved by the cooling module according to the invention, comprising: a A heat pipe comprising a pipe having a first end, a second end, and a center portion, said first and second ends being adjacent to each other and forming a heat receiving portion, said center portion forming a heat release portion extending from said first end to said second end and forms a circle; a plurality of cooling fins disposed on the central portion of the tube and forming air passages; and a fan having at least at least one air inlet side and an air outlet side, the air outlet side being connected to the air channels.

These objects are further achieved by the cooling module according to the invention, comprising: a heat pipe comprising a pipe having a first end, a second end and a central part, wherein the first and second ends are adjacent to each other and form a heat receiving part, the middle part forming a heat release member, extending from the first end to the second end and forming a circle; a plurality of cooling fins forming air passages; and a fan having at least one air inlet side, an air outlet side, an upper lid and a lower lid, wherein the lower lid is located on the central part and forms with the lower lid a receiving space, which is connected to the air inlet side and the air outlet side, wherein in the receiving space a paddle wheel and the cooling fins are arranged, wherein the air inlet side is mounted in the center of the upper lid or in the middle of the lower lid, wherein the air outlet side is attached to one side of the fan and is connected to the air ducts.

Brief description of the drawings

1A a perspective view of the first preferred embodiment of the first preferred embodiment of the invention,

1B a perspective view of the first preferred embodiment of the first preferred embodiment of the invention partially in section,

1C a further perspective view of the first preferred embodiment of the first preferred embodiment of the invention,

1D a further perspective view of the first preferred embodiment of the invention,

2A a perspective view of the first preferred embodiment of the invention with the heat source,

2 B a further perspective view of the first preferred embodiment of the invention with the heat source,

3A an exploded view of the second preferred embodiment of the invention,

3B a perspective view of the second preferred embodiment of the invention,

3C a further exploded view of the second preferred embodiment of the invention,

3D another perspective view of the second preferred embodiment of the invention,

4A an exploded view of the third preferred embodiment of the invention,

4B a further exploded view of the third preferred embodiment of the invention,

5 a perspective view of the third preferred embodiment of the invention,

6A a sectional view of the third preferred embodiment of the invention,

6B a further sectional view of the third preferred embodiment of the invention,

7 a further perspective view of the third preferred embodiment of the invention,

8A a representation of an embodiment of the third preferred embodiment of the invention,

8B a representation of another embodiment of the third preferred embodiment of the invention,

9A an exploded view of the fourth preferred embodiment of the invention,

9B a further exploded view of the fourth preferred embodiment of the invention,

10A a perspective view of the fourth preferred embodiment of the invention,

10B another perspective view of the fourth preferred embodiment of the invention,

11 an embodiment of the fourth preferred embodiment of the invention,

12A an exploded view of the fifth preferred embodiment of the invention,

12B a further exploded view of the fifth preferred embodiment of the invention,

13A a perspective view of the fifth preferred embodiment of the invention,

13B a further perspective view of the fifth preferred embodiment of the invention,

14 a representation of the embodiment of the fifth preferred embodiment of the invention.

Ways to carry out the invention

Further details, features and advantages of the invention will become apparent from the following detailed description taken in conjunction with the accompanying drawings.

The 1A and 1B show the first preferred embodiment of the heat pipe according to the invention 1 that a pipe 10 includes, which is a flat tube (flat heat pipe) in the present embodiment. The invention is not limited thereto. In practice, the shape of the pipe 10 depending on the electronic product (such as mobile device). In 1C is the pipe 10 D-shaped (D-shaped heat pipe). In 1D is the pipe 10 round (round heat pipe).

The pipe 10 is filled with a working fluid (not shown). The pipe 10 has a first end 101 , a second end 102 , a middle part 104 and at least one capillary structure 115 , The capillary structure is formed in the present embodiment by a sintered powder (it may also be formed by grooves, metal mesh, coating, porous body) and is located on the inner wall of the tube 10 , The first end 101 (or the first heat receiving end) 101 defines the front end of the pipe. The second end 102 (or the second heat receiving end) is located near the first end and defines the rear end of the tube. Ie. the front end and the rear end of the tube 10 lie parallel next to each other. The first and second end 101 . 102 form a heat receiving part 111 (or heat absorption zone).

In the present embodiment, the heat receiving part is located on a heat source 4 (such as CPU, graphics chip, Southbridge and Northbridge) ( 2A ). The invention is not limited thereto. How out 2 B can be seen, the heat receiving part 111 also on one side of a heat conductor 3 lie with the other side on the heat source 4 lies. The heat conductor 3 absorbs the heat of the heat source 4 and conducts the heat to the heat receiving part 111 , The heat conductor 3 has a variety of mounting arms 31 on, extending from the two sides of the heat conductor 3 extend outwardly and are secured by a plurality of fasteners (not shown) on the support plate (not shown) of the heat source.

The first and second ends of the pipe 10 (the front and rear end of the tube 10 ) continuously absorb the heat. When one end loses the absorption function, the other end can continue to absorb the heat. By the invention, the Wärmeleiteffizienz and the cooling power can be increased in the opposite direction of gravity. If the pipe 10 not lying horizontally and the first and second ends 101 . 102 higher than the middle part 104 (Heat release part), the working fluid in the middle part 104 against gravity quickly through the capillary structure 115 on the inner wall of the pipe 10 to the first and second tubes 101 . 102 flow, since the two ends of the tube are designed as a heat receiving end.

Therefore, the invention can be achieved by a single tube 1 achieve the working efficiency of two or more than two pipes in the conventional solution, so that the cost can be reduced.

How out 2A is apparent forms the middle part 104 a heat release part (heat release zone). The middle part 104 extends from the first end 101 until the second end 102 and forms a circle. Ie. the first and second ends 101 . 102 and the middle part 104 form one-piece tube. The middle part 104 forms a central clearance 113 , If the first and second end 101 . 102 (Heat receiving part 111 ) the heat of the heat source 4 absorbed, it can heat the heat quickly to the heat release part (middle part 104 ) transport.

Because the first and second end 101 . 102 lie next to each other and a heat absorption zone (heat receiving part 111 ) and the middle part 104 from the first end 101 until the second end 102 extends and forms a circle, the Wärmeleiteffizienz can be increased, whereby an ineffective end of the heat pipe is avoided. In addition, the invention can reduce the cost and increase the cooling power in the opposite direction of gravity.

The 3A and 3B in conjunction with the 2A and 2 B show the second preferred embodiment of the invention, which differs from the first preferred embodiment only in that on the central part 104 of the pipe 10 a variety of cooling fins 23 are provided on one side of the middle part 104 of the pipe 10 stand. Ie. on at least one side of the middle section 104 are local or continuous cooling fins 23 arranged. The cooling fins 23 can also be continuously strung in the range of 90 ° to 360 ° become. In this embodiment, the cooling fins 23 in the range of 360 continuously ranked. The invention is not limited thereto. As required, the arrangement of the cooling fins 23 on the middle part 104 to be changed. In the 3C and 3D are the cooling fins 23 in the range of 180 ° on the middle part 104 ranked continuously.

Between the cooling fins 23 are cooling channels 231 educated. When the heat receiving part 111 (or heat receiving zone) passing through the first and second ends 101 . 102 (the front and rear end of the tube 10 )), the heat of the heat source 4 absorbed, it can heat the heat quickly to the heat release part (middle part 104 ) transport. The heat release part conducts the heat to the cooling fins 23 , which thus give off the heat in the ambient air. Through the cooling fins 23 can the cooling surface of the heat release part (the middle part 104 ).

The 4A and 5 show the third preferred embodiment of the invention, which differs from the first preferred embodiment only in that the heat pipe 1 on a cooling module 2 is applied. Ie. the cooling module 2 includes a heat pipe 1 , a variety of cooling fins 23 and a fan 21 , The heat pipe 1 is the same as the heat pipe 1 in the first preferred embodiment of the invention.

The cooling fins 23 stand on one side of the middle section 104 of the pipe 10 , Ie. the cooling fins 23 be in the range of 90 ° to 360 ° on the middle part 104 ranked continuously. In this embodiment, the cooling fins 23 in the range of 360 ° continuously ranked ( 5 ). The invention is not limited thereto. As required, the arrangement of the cooling fins 23 on the middle part 104 to be changed. In 7 are the cooling fins 23 in the range of 180 ° on the middle part 104 ranked continuously. Through the cooling fins 23 on the heat release part (middle part 104 ) the cooling surface is increased.

Between the cooling fins 23 are cooling channels 231 educated. The ventilator 21 is a centrifugal fan and in the middle part 104 of the pipe 10 arranged. Ie. the ventilator 21 is above the central clearance of the midsection 104 arranged. The ventilator 21 has at least one air inlet side 211 , an air outlet side 213 , an upper lid 214 and one of the top lids 214 opposite lower lid 215 , The upper lid 214 and the lower lid 215 form a recording room 216 that with the air inlet side 211 and the air outlet side 213 connected is. In the recording room 216 is a paddle wheel 217 arranged. In this embodiment, the upper lid 214 by welding with the cooling fins 23 connected. In practice, the upper lid 214 also by screw or locking connection with the lower cover 215 get connected. In this embodiment, the centrifugal fan has two embodiments:

First, as from the 4A . 5 and 6A is apparent, are an air inlet side 211 and an air outlet side 213 intended. The air inlet side 211 is located in the middle of the upper lid 214 , The air outlet side 213 is located on one side of the fan and communicates with the air ducts 231 connected. The air outlet side 213 can adapt to the angular range of cooling fins 23 to adjust. When the cooling fins 23 in the range of 180 ° are continuously ranked, the angular range of the air outlet side 213 also 180 °.

Second, as from the 4B . 5 and 6B it can be seen are two air inlet sides 211 and an air outlet side 213 intended. An air inlet side 211 is located in the middle of the upper lid 214 , The other air inlet side 211 is located in the middle of the lower lid 215 , The two air inlet sides 211 are with the central clearance 113 connected. The other air inlet side 211 is also with the recording room 216 and the air outlet side 213 connected. The air outlet side 213 is located on one side of the fan and communicates with the air ducts 231 connected. The air outlet side 213 can adapt to the angular range of cooling fins 23 to adjust. When the cooling fins 23 in the range of 270 ° are continuously ranked, the angle range of the air outlet side 213 also 270 °. When the cooling fins 23 in the range of 360 ° are continuously ranked, the angle range of the air outlet side 213 also 360 °. As a result, the lowest wind resistance and the largest amount of air can be achieved, so that the cooling effect is significantly increased and the noise is reduced.

How out 8A it can be seen when the heat receiving part 111 (or heat receiving zone) passing through the first and second ends 101 . 102 is formed, the heat of the heat source 4 absorbed, it can heat the heat quickly to the heat release part (middle part 104 ) transport. The heat release part conducts the heat to the cooling fins 23 , which thus give off the heat in the ambient air. At the same time the paddle wheel sucks 217 of the fan 21 the outside air through the air inlet side 211 one through the air outlet side 213 to the cooling fins 23 flows, reducing the heat of the cooling fins 23 is necessarily dissipated.

Or how out 8B it can be seen when the heat receiving part 111 (or heat receiving zone) passing through the first and second ends 101 . 102 is formed by the heat conductor 3 the heat of the heat source 4 absorbed, it can heat the heat quickly to the heat release part (middle part 104 ) transport. The heat release part conducts the heat to the cooling fins 23 , which thus give off the heat in the ambient air. At the same time the paddle wheel sucks 217 of the fan 21 the outside air through the air inlet side 211 one through the air outlet side 213 to the cooling fins 23 flows, reducing the heat of the cooling fins 23 is necessarily dissipated.

The 9A and 10A show the fourth preferred embodiment of the invention, which differs from the first preferred embodiment only in that the heat pipe 1 on a cooling module 5 is applied. Ie. the cooling module 5 includes a heat pipe 1 , a variety of cooling fins 53 and a fan 51 , The heat pipe 1 is the same as the heat pipe 1 in the first preferred embodiment of the invention.

Between the cooling fins 53 are cooling channels 531 educated. The ventilator 51 is a centrifugal fan and in the middle part 104 of the pipe 10 arranged. Ie. the ventilator 51 is above the central clearance 113 of the middle section 104 arranged. The ventilator 51 has at least one air inlet side 511 , an air outlet side 513 , an upper lid 514 and one of the top lids 514 opposite lower lid 515 , The lower lid 515 is made of material with high thermal conductivity (such as copper) and lies with one side on the middle part 104 and with the other side on the cooling fins 53 , The cooling fins 53 lie with the other side on the upper lid 514 , The upper lid 514 and the lower lid 515 form a recording room 516 that with the air inlet side 511 and the air outlet side 513 connected is. In the recording room 516 are a paddle wheel 517 and the cooling fins 53 arranged. In this embodiment, the centrifugal fan has two embodiments:

First, as from the 9A and 10A is apparent, are an air inlet side 511 and an air outlet side 513 intended. The air inlet side 511 is located in the middle of the lower lid 515 , The air outlet side 513 is located on one side of the fan 51 and is with the air channels 531 connected. The air outlet side 513 can adapt to the angular range of cooling fins 23 to adjust. When the cooling fins 23 in the range of 2700 ° are continuously ranked, the angle range of the air outlet side 513 also 270 °. In practice, the air inlet side 511 from in the middle of the upper lid 514 of the fan 51 to be appropriate.

Second, as from the 9B and 10A it can be seen are two air inlet sides 511 and an air outlet side 513 intended. An air inlet side 511 is located in the middle of the upper lid 514 , The other air inlet side 511 is located in the middle of the lower lid 515 , The two air inlet sides 511 are with the central clearance 113 connected. The other air inlet side 211 is also with the recording room 516 and the air outlet side 513 connected. The air outlet side 513 is located on one side of the fan 51 and is with the air channels 531 connected. The air outlet side 513 can adapt to the angular range of cooling fins 53 to adjust. When the cooling fins 53 in the recording room 516 be continuously strung in the range of 180 ° ( 10B ), the angular range of the air outlet side 513 also 180 °. When the cooling fins 53 in the range of 360 ° continuously ranked ( 10B ), the angular range of the air outlet side 513 also 360 °. As a result, the lowest wind resistance and the largest amount of air can be achieved, so that the cooling effect is significantly increased and the noise is reduced.

How out 11 it can be seen when the heat receiving part 111 (or heat receiving zone) passing through the first and second ends 101 . 102 is formed, the heat of the heat source 4 (it can quickly transfer the heat to the heat release part (middle part 104 ) transport. The heat release part conducts the heat through the lower lid 515 on the cooling fins 53 , which thus give off the heat in the ambient air. At the same time the paddle wheel sucks 517 of the fan 51 the outside air through the air inlet side 511 one through the air outlet side 513 to the cooling fins 53 flows, reducing the heat of the cooling fins 53 is necessarily dissipated.

The 12A . 12B and 13A show the fifth preferred embodiment of the invention, which differs from the fourth preferred embodiment only in that the size of the lower lid 515 to the pipe 10 is adjusted. Here, the lower lid extends 515 from the middle part 104 until the first and second ends 101 . 102 (the first and second heat receiving end). The first and second end 101 . 102 be with the lower lid 515 glued together. Ie. the lower lid extends to the heat receiving part 111 (or heat absorption zone). The first and second end 101 . 102 (the first and second heat receiving end) stick on the lower lid 515 , In the present embodiment, the lower lid 515 rectangular and the upper lid 514 square shaped. In practice, the shape of the lower lid 515 and the top lid 514 not limited to this.

How out 14 it can be seen, lies the other side of the lower lid 515 on a heat source 4 , absorbs the heat of the heat source 4 and directs this heat to the heat release part 111 , At the same time, part of the heat is transferred to the cooling fins 53 directed. The heat receiving part 111 (the first and second end 101 . 102 ) transports the heat quickly to the heat release part (middle part 104 ), which transfers the heat to the cooling fins 53 conducts, which release the heat quickly into the ambient air. At the same time the paddle wheel sucks 517 of the fan 51 the outside air through the air inlet side 511 one through the air outlet side 513 to the cooling fins 53 flows, reducing the heat of the cooling fins 53 is necessarily dissipated.

In 13B are the cooling fins 53 in the recording room 516 in the range of 180 ° continuously ranked. The angular range of the air outlet side 513 on one side of the fan 51 is also 180 °.

Through the heat pipe 1 can the heat conduction efficiency of the cooling module 52 increase. In addition, the invention can reduce the cost and increase the cooling power in the opposite direction of gravity. Furthermore, the wind resistance and the noise can be reduced.

The cooling module 2 Can be applied to a mobile device (such as a smartphone, notebook, iPad, PDA, iPad2) or a monitor (such as LED or LCD monitor).

• 1. Erhöhung der Wärmeleiteffizienz und Vermeidung ein wirkungsloses Ende;
• 2. Reduzierung der Kosten und Erhöhung der Kühlleistung in der Gegenrichtung der Schwerkraft;
• 3. Reduzierung des Windwiderstands und des Geräusches;
• 4. Erhöhung der Kühlwirkung.

Therefore, the invention has the following advantages:

• 1. increase the Wärmeleiteffizienz and avoiding an ineffective end;
• 2. Reduction of costs and increase of cooling capacity in the opposite direction of gravity;
• 3. Reduction of wind resistance and noise;
• 4. Increase the cooling effect.

The foregoing description represents only the preferred embodiments of the invention and is not intended to serve as a definition of the limits and scope of the invention.

All equivalent changes and modifications are within the scope of this invention.

Claims (20)

Heat pipe that is a pipe ( 10 ), which has a first end ( 101 ), a second end ( 102 ) and a middle part ( 104 ), wherein the first and second ends ( 101 . 102 ) lie next to each other and a heat receiving part ( 111 ), the middle part ( 104 ) forms a heat release member, extending from the first end ( 101 ) until the second end ( 102 ) and forms a circle. Heat pipe according to claim 1, characterized in that on the middle part ( 104 ) of the pipe ( 10 ) a plurality of cooling fins ( 23 ) provided on one side of the central part ( 104 ) of the pipe ( 10 ), wherein between the cooling fins ( 23 ) Air channels ( 231 ) are formed. Heat pipe according to claim 2, characterized in that the cooling fins ( 23 ) in the range of 90 ° to 360 ° on one side of the middle part ( 104 ) are strung continuously. Heat pipe according to claim 2, characterized in that the heat receiving part ( 111 ) directly on a heat source ( 4 ) lies. Cooling module, comprising a heat pipe ( 1 ), which is a pipe ( 10 ), which has a first end ( 101 ), a second end ( 102 ) and a middle part ( 104 ), wherein the first and second ends ( 101 . 102 ) lie next to each other and a heat receiving part ( 111 ), the middle part ( 104 ) forms a heat release member, extending from the first end ( 101 ) until the second end ( 102 ) and forms a circle, a plurality of cooling fins ( 23 ) located on the middle part ( 104 ) of the pipe ( 10 ) and air ducts ( 313 ), and a fan ( 21 ), which has at least at least one air inlet side ( 211 ) and an air outlet side ( 213 ), wherein the air outlet side ( 213 ) with the air channels ( 231 ) connected is. Cooling module according to claim 5, characterized in that the fan ( 21 ) a centrifugal fan and in the middle part 104 of the pipe ( 10 ) is located above the central space of the middle part ( 104 ), wherein the air inlet side ( 211 ) in the middle of an upper lid ( 214 ) of the fan ( 21 ), the air outlet side ( 213 ) on one side of the fan ( 23 ) and with the air ducts ( 231 ) connected is. Cooling module according to claim 5, characterized in that the fan ( 21 ) a centrifugal fan and in the middle part ( 104 ) of the pipe ( 10 ) is located above the central space of the middle part ( 104 ), wherein an air inlet side ( 211 ) in the middle of an upper lid ( 214 ) of the fan ( 21 ), the other air inlet side ( 211 ) in the middle of the lower lid ( 215 ), the other air inlet side ( 211 ) also with the receiving space ( 216 ) and the air outlet side ( 213 ), the air outlet side ( 213 ) is located on one side of the fan and with the air channels ( 231 ) are connected. Cooling module according to claim 6, characterized in that the cooling ribs ( 23 ) in the range of 90 ° to 360 ° on one side of the middle part ( 104 ) are strung continuously. Cooling module according to claim 7, characterized in that the cooling ribs ( 23 ) in the range of 90 ° to 360 ° on one side of the middle part ( 104 ) are strung continuously. Cooling module according to claim 6, characterized in that the heat receiving part ( 111 ) on one side of a heat conductor ( 3 ) located on the other side of the heat source ( 4 ) lies. Cooling module according to claim 6, characterized in that the heat receiving part ( 111 ) on one side of a heat conductor ( 3 ) located on the other side of the heat source ( 4 ) lies. Cooling module according to claim 6, characterized in that the heat receiving part ( 111 ) directly on a heat source ( 4 ) lies. Cooling module according to claim 7, characterized in that the heat receiving part ( 111 ) directly on a heat source ( 4 ) lies. Cooling module, comprising a heat pipe ( 1 ), which is a pipe ( 10 ), which has a first end ( 101 ), a second end ( 102 ) and a middle part ( 104 ), wherein the first and second ends ( 101 . 102 ) lie next to each other and a heat receiving part ( 111 ), the middle part ( 104 ) forms a heat release member, extending from the first end ( 101 ) until the second end ( 102 ) and forms a circle, a plurality of cooling fins ( 23 ), the air ducts ( 313 ), and a fan ( 21 ), the at least one air inlet side ( 511 ), an air outlet side ( 513 ), an upper lid ( 514 ) and a lower lid ( 515 ), wherein the lower lid ( 515 ) on the middle part ( 104 ) and with the lower lid ( 514 ) a recording room ( 516 ) formed with the air inlet side ( 514 ) and the air outlet side ( 515 ), wherein in the recording room ( 516 ) a paddle wheel ( 517 ) and the cooling fins ( 53 ) are arranged, wherein the air inlet side ( 514 ) in the middle of the upper lid ( 514 ) or in the middle of the lower lid ( 515 ), the air outlet side ( 515 ) on one side of the fan ( 51 ) and with the air ducts ( 231 ) connected is. Cooling module according to claim 14, characterized in that the lower cover ( 515 ) from the middle part ( 104 ) until the first and second ends ( 101 . 102 ), wherein the first and second ends ( 101 . 102 ) with the lower lid ( 515 ) are glued together. Cooling module according to claim 15, characterized in that the fan ( 51 ) a centrifugal fan and in the middle part ( 104 ) of the pipe ( 10 ) is located above the central space of the middle part ( 104 ), wherein the air inlet side ( 511 ) in the middle of an upper lid ( 514 ) of the fan ( 51 ), wherein the two air inlet sides ( 511 ) with the receiving space ( 516 ) are connected. Cooling module according to claim 14, characterized in that the cooling ribs ( 23 ) in the range of 90 ° to 360 ° in the receiving space ( 516 ) are strung continuously. Cooling module according to claim 16, characterized in that the cooling ribs ( 23 ) in the range of 90 ° to 360 ° in the receiving space ( 516 ) are strung continuously. Cooling module according to claim 14, characterized in that the heat receiving part ( 111 ) directly on a heat source ( 4 ) lies. Cooling module according to claim 16, characterized in that the lower cover ( 515 ) with one side on the heat receiving side and with the other side on a heat source ( 4 ) lies.

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