DE202011100657U1 - Condenser and cooling module with this condensation device - Google Patents

Abstract

Condensation device, comprising a hollow main body (11) which has at least one first inlet opening (111), at least one first outlet opening (112) and a guide zone (113), the first inlet opening (111) and the first outlet opening (112) adjoining each other the two sides of the guide zone (113), a plurality of guide elements (1131) being provided in the guide zone (113), which are spaced apart, with at least one channel (1132) being formed between two adjacent guide elements (1131) wherein the guide elements (1131) are directed with one end to the first inlet opening (111) and with the other end on the first outlet opening (112).

Description

Technical area

The invention relates to a condensation device and a cooling module with this condensation device, in particular a condensation device that can accelerate the working fluid circuit.

State of the art

With the development of semiconductor technology and market demand, the electronic products are becoming increasingly compact, while the function and the computing speed are always higher. Notebook and computer have a plurality of electronic components, in particular central unit, which generate heat during operation. To dissipate this heat, a cooling module is used, which is formed by cooling fins and a fan, so that the central unit is kept at normal working temperature. Therefore, the central unit cooler is an important component.

Recently, water cooling has been applied to the computer. Although the cooling fins that occupy a large space can be dispensed with by the water cooling, a working fluid is required to absorb the heat and transport it away. The tube length can be chosen arbitrarily. The location can also be changed. Therefore, the space limitation is smaller. The water cooling, however, requires a pump to deliver the working fluid. In addition, a water tank is required. The reliability of the pump and the tightness of the pipe are problems of water cooling.

Heat pipe is also used for heat transport. The heat pipe absorbs the heat from the heat source and transports the heat to the cooling fins. In the heat pipe, a capillary structure may be provided to increase the cooling effect. Reducing the power consumption of the central unit is also a solution to the problem with the operating heat.

1 shows a conventional cooling module 8th that is a heat-absorbing element 81 , a condensation element 82 and a pipe element 83 includes. The condensation element 82 is through a variety of cooling fins 821 educated. The heat receiving element 81 has an outlet opening 811 and an entrance opening 812. up and working with a fluid 84 filled. The heat receiving element 81 is through the pipe element 83 with the condensation element 82 connected, whereby a heat transport circuit is formed.

The pipe element 83 contains a first part 831 , a second part 832 and a third part 833 , The first part 831 located between the heat receiving element 81 and the condensation element 82 , The second part 832 is zigzag through the condensation element 82 guided. The third part 833 is located between the condensation element 82 and the entrance opening 812. the heat receiving element 81 , As a result, the first, second and third parts 831 . 832 . 833 connected with each other.

When heat transport is the heat absorption element 81 with at least one heat source 9 in contact and absorbs the heat of the heat source 9 , whereby the working fluid 84 in the heat receiving element 81 is evaporated. The gaseous working fluid 84 flows through the first part 831 of the tubular element 83 in the second part 832 of the tubular element 83 in the condensation element 82 , The condensation element 82 absorbs the heat of the second part 832 and dissipates the heat by heat radiation. This will cause the gaseous working fluid 84 in the second part 832 of the tubular element 83 condensed. The condensed working fluid flows through the second part 832 and the third part 833 in the heat receiving element 81 back. Therefore, the working fluid circulates in the cooling module.

The working fluid 84 will be in the second part 832 converted back into the liquid form. The liquid working fluid 84 in the second part 832 slowly flows by gravity into the heat receiving element 81 back. As a result, the middle region, the rear region and the arc region of the second part form 832 Blind zones of the heat transport, so that the reflux velocity of the working fluid 84 is low.

• 1. schlechte Wärmetransportwirkung,
• 2. Blindzone des Wärmetransports,
• 3. höhere Kosten.

Therefore, the conventional solution has the following disadvantages:

• 1. poor heat transport effect,
• 2. Blind zone of the heat transport,
• 3. higher costs.

Object of the invention

The invention has for its object to provide a condensation device that can accelerate the working fluid circuit.

Another object of the invention is to provide a cooling module which can accelerate the working fluid cycle and avoid the blind zone of heat transfer.

These objects are achieved by the condensation device according to the invention, which comprises a hollow main body which has at least one first inlet opening, at least one first outlet opening and a guide zone, wherein the first inlet opening and the first outlet opening are located on the two sides of the guide zone, wherein in the guide zone, a plurality of guide elements are provided which are arranged spaced, wherein between two adjacent guide elements in each case at least one channel is formed, wherein the guide elements with a End are directed to the first inlet opening and with the other end to the first outlet opening.

These objects are achieved by the cooling module according to the invention, comprising: a hollow main body having at least a first inlet opening, at least a first outlet opening and a guide zone, wherein the first inlet opening and the first outlet opening are located on both sides of the guide zone, wherein the guide zone, a plurality of guide elements are provided which are arranged spaced, wherein between two adjacent guide elements in each case at least one channel is formed, wherein the guide elements are directed with one end to the first inlet opening and with the other end to the first outlet opening; and at least one heat receiving unit including an evaporation zone, a second inlet opening and a second outlet opening, wherein the second inlet opening is connected to the first outlet opening by a first heat transport unit, and wherein the second outlet opening is connected to the first inlet opening by a second heat transfer unit.

By the guide zone of the working fluid circuit of the condensation device and the cooling module can be accelerated and the blind zone of the heat transfer can be avoided.

• 1. keine Blindzone des Wärmetransports,
• 2. Beschleunigung des Arbeitsfluidkreislaufs,
• 3. Erhöhung der Wärmetransportwirkung,
• 4. Reduzierung der Kosten.

Therefore, the invention has the following advantages:

• 1. no blind zone of the heat transport,
• 2. acceleration of the working fluid cycle,
• 3. increase the heat transport effect,
• 4. Reduction of costs.

Brief description of the drawings

1 a sectional view of the conventional solution,

2 a sectional view of the first embodiment of the condensation device according to the invention,

3 a sectional view of the second embodiment of the condensation device according to the invention,

4 a sectional view of the third embodiment of the condensation device according to the invention,

5 a sectional view of the fourth embodiment of the condensation device according to the invention,

6 a sectional view of the fifth embodiment of the condensation device according to the invention,

7 a sectional view of the first embodiment of the cooling module according to the invention,

8th a sectional view of the second embodiment of the cooling module according to the invention,

9 a representation of the operation of the cooling module according to 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.

2 shows the first embodiment of the condensation device according to the invention 1 holding a hollow main body 11 includes.

The hollow main body 11 has at least one first inlet opening 111 , at least one first outlet opening 112 and a leadership zone 113 on. The first entrance opening 111 and the first exit opening 112 are located on both sides of the leadership zone 113 , In the leadership zone 113 are a variety of guiding elements 1131 provided, which are arranged spaced. Between two adjacent guide elements 1131 is at least one channel each 1132 educated. The guide elements 1131 are at one end to the first entrance 111 and with the other end on the first outlet opening 112 directed.

The channel 1132 has a first end 1132 and a second end 1132b ,

3 shows the second embodiment of the condensation device according to the invention, which differs from the first embodiment only in that the first inlet opening 111 with an extended spreading section 114 connected, who is a first scatterer 1141 and a second scatterer 1142 wherein the width of the first spreader 1141 smaller than that of the second spreader 1142 ,

4 shows the third embodiment of the condensation device according to the invention, which differs from the first embodiment only in that on the inner wall of the hollow main body 11 a capillary structure 11a formed by sintered metal powder or network. In the present embodiment, the capillary structure is formed by sintered metal powder.

5 shows the fourth embodiment of the condensation device according to the invention, which differs from the first embodiment only in that on the inner wall of the hollow main body 11 a variety of grooves or depressions 11b or protrusions are formed. In the present embodiment are sinks 11b educated. However, the invention is not limited thereto.

6 shows the fifth embodiment of the condensation device according to the invention, which differs from the first embodiment only in that on the outside of the hollow main body 11 a variety of cooling fins 11c are formed.

In the hollow main body 11 is a working fluid 2 filled, which is pure water, methanol, ketone or R134A.

7 shows the first embodiment of the cooling module according to the invention 3 , which is a condensation device, at least one heat absorption unit 4 , a first heat transport unit 5 and a second heat transport unit 6 includes.

The condensation device is constructed as in the first embodiment and is therefore not described.

The heat absorption unit 4 contains an evaporation area 41 , a second entrance opening 42 and a second exit opening 43 , The second entrance opening 42 is through the first heat transport unit 5 with the first outlet 112 connected. The second outlet 43 is through the second heat transport unit 6 with the first entrance opening 111 connected.

The first heat transport unit 5 and the second heat transport unit 6 are each formed by a tube made of metal or plastic. In the present embodiment, the first heat transport unit 5 a heat pipe and has on the inside a capillary structure 51 or grooves on.

On two sides of the condensation device 1 are a variety of cooling fins 11c educated.

8th shows the second embodiment of the cooling module according to the invention 3 which differs from the first embodiment only in that the first inlet opening 111 the condensation device 1 with an extended spreading section 114 connected, who is a first scatterer 1141 and a second scatterer 1142 wherein the width of the first spreader 1141 smaller than that of the second spreader 1142 ,

9 shows the operation of the cooling module according to the invention 3 , When used is the heat absorption unit 4 with at least one heat source 7 in contact. The working fluid 2 in the heat receiving unit 4 is vaporized by the heat in the evaporation zone. The steam passes through the second outlet 43 out, flows through the second heat transport unit 6 to the first entrance opening 111 the condensation device 1 and thus enters the condensation device 1 one. Through the leadership zone 113 the condensation device 1 a high pressure required for the working fluid circuit is generated. In the leadership zone 113 is formed by a suitable embodiment, a low pressure side, whereby a required for the working fluid circuit pressure gradient is generated, so that the working fluid 22 through the first heat transport unit 5 in the heat receiving unit 4 is transported back. This will reduce the cooling effect of the cooling module 3 elevated. In addition, a blind zone of the heat transport in the condensation device as in the conventional solution can be avoided.

Claims (13)

Condensing device comprising a hollow main body ( 11 ), which has at least one first entrance opening ( 111 ), at least one first outlet opening ( 112 ) and a leadership zone ( 113 ), wherein the first inlet opening ( 111 ) and the first exit opening ( 112 ) on both sides of the guiding zone ( 113 ), whereas in the guiding zone ( 113 ) a plurality of guide elements ( 1131 ) are provided, which are arranged at a distance, wherein between two adjacent guide elements ( 1131 ) at least one channel ( 1132 ) is formed, wherein the guide elements ( 1131 ) with one end to the first inlet opening ( 111 ) and with the other end to the first outlet opening ( 112 ) are directed. Condensation device according to claim 1, characterized in that the channel ( 1132 ) a first end ( 1132 ) and a second end ( 1132b ) having. Condensation device according to claim 1, characterized in that the first inlet opening ( 111 ) with an extended spreading section ( 114 ) who is a first spreader ( 1141 ) and a second spreader ( 1142 ), wherein the width of the first scattering end ( 1141 ) is smaller than that of the second spreader ( 1142 ). Condensation device according to claim 1, characterized in that on the inner wall of the hollow main body ( 11 ) a capillary structure ( 11a ) is formed. Condensation device according to claim 4, characterized in that the capillary structure ( 11a ) is formed by sintered metal powder or mesh. Condensation device according to claim 1, characterized in that on the inner wall of the hollow main body ( 11 ) a plurality of grooves or depressions ( 11b ) or projections are formed. Condensation device according to claim 1, characterized in that in the hollow main body ( 11 ) a working fluid ( 2 ), which is pure water, methanol, ketone or (R134A). Cooling module comprising a condensation device comprising a hollow main body ( 11 ), the at least one first inlet opening ( 111 ), at least one first outlet opening ( 112 ) and a leadership zone ( 113 ), wherein the first inlet opening ( 111 ) and the first exit opening ( 112 ) on both sides of the guiding zone ( 113 ), whereas in the guiding zone ( 113 ) a plurality of guide elements ( 1131 ) are provided, which are arranged at a distance, wherein between two adjacent guide elements ( 1131 ) at least one channel ( 1132 ) is formed, wherein the guide elements ( 1131 ) with one end to the first inlet opening ( 111 ) and with the other end to the first outlet opening ( 112 ), and at least one heat receiving unit ( 4 ), which has an evaporation area ( 41 ), a second entrance opening 42 and a second exit opening ( 43 ), wherein the second inlet opening ( 42 ) by a first heat transport unit ( 5 ) with the first outlet opening ( 112 ), and wherein the second outlet opening ( 43 ) by a second heat transport unit ( 6 ) with the first entrance opening ( 111 ) connected is. Cooling module according to claim 8, characterized in that the channel ( 1132 ) a first end ( 1132 ) and a second end ( 1132b ) having. Cooling module according to claim 8, characterized in that the first inlet opening ( 111 ) with an extended spreading section ( 114 ), who is a first spreader ( 1141 ) and a second spreader ( 1142 ), wherein the width of the first scattering end ( 1141 ) is smaller than that of the second spreader ( 1142 ). Cooling module according to claim 8, characterized in that in the hollow main body ( 11 ) a working fluid ( 2 ), which is pure water, methanol, ketone or (R134A). Cooling module according to claim 8, characterized in that in the heat absorption unit ( 4 ) a working fluid ( 2 ), which is pure water, methanol, ketone or (R134A). Cooling module according to claim 8, characterized in that the first heat transport unit ( 5 ) is a heat pipe and on the inside a capillary structure ( 51 ) or grooves.

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