GB2416243A

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Publication number: GB2416243A
Application number: GB0415434A
Authority: GB
Inventors: Hsiang-Chieh Tseng; Yi-Song Liu; Chia-Min Chou; Chia-Feng Yeh
Original assignee: Giga Byte Technology Co Ltd
Current assignee: Giga Byte Technology Co Ltd
Priority date: 2004-07-09
Filing date: 2004-07-09
Publication date: 2006-01-18
Anticipated expiration: 2024-07-09
Also published as: GB0415434D0; GB2416243B

Abstract

Heat is transferred from an electronic device 100, eg a CPU, to a heat absorbing block 1, the heat absorbing block is cooled by a thermoelectric cooler 4 having a heat sink 53. Heat is also transferred from the block by heat pipe 2 to heat sink 3. The heat sinks are air-cooled by fan 200. A temperature sensor in direct contact with the electronic device may be used as part of a temperature control system for the device. More than one thermoelectric unit may be used to cool the device (figure 5) and forced fluid cooling may also be used (figures 9 and 10).

Description

24 1 6243

TWO STAGE RADIATION THERMOELECTRIC

COOLING APPARATUS

This invention relates generally to a thermoelectric cooling apparatus, in particular, a two stage radiation thermoelectric cooling apparatus for cooling an electronic device.

Central Processing Units (CPUs) of computers generate large quantities l0 of heat during operation, especially as the speed of operation increases.

However, this heat, if confined in the computer housing, can affect the operation and reliability of many heat sensitive elements forming parts of the computer, including the CPU itself, motherboard components, memory, CD ROM, CDRW, DVD, hard drive, Disk on Chip, Magnetic media, floppy drives, electronic cards, etc especially in personal computers, industrial computers, servers, workstations, mainframes, other computers and telecommunication devices.

A conventional cooler for cooling an electronic device such as CPU mainly contains a heat sink and a fan. The heat sink is made of copper or aluminum. The heat sink collects heat from the electronic device and the fan blow away the heat collected therefrom. The trend at present is to increase the power of the CPUs, which causes an increase in the temperature inside the computer housing. The conventional cooler sometimes cannot sufficiently remove the heat produced. Accordingly, it is becoming more necessary to find an efficient cooling apparatus.

At present, there is a known device known as thermoelectric cooler (TEC). A thermoelectric cooler includes a cold side and a hot side which, under a voltage difference, pump heat using the Peltier effect. The thermoelectric i' cooler utilizes electrical current to absorb heat from the cold side of the cooler and dissipate that heat on the hot side (opposite side).

A conventional TEC apparatus comprises a TEC and a heat sink. The cold side of the conventional TEC apparatus contacts a CPU. The TEC transmits the heat collected from the CPU to the heat sink and the heat sink dissipates the heat.

Another conventional TEC apparatus comprises a TEC and a heat sink.

The heat sink contacts a CPU and collects heat therefrom. A cold side of the TEC contacts the heat sink and transmitted the heat to a hot side of the TEC and then dissipates the heat to the air.

These devices are very reliable and cost effective in low wattage applications. However, in high wattage applications, a conventional TEC apparatus is less efficient than a conventional non-TEC cooler as illustrated in Fig.4 (test results.) In Fig.4, the horizontal axis represents CPU wattage, the vertical axis represents heat resistance, curve C1 represents a non-TEC cooler and curve C2 represents a conventional TEC apparatus. The test results are based on same testing circumstances such as using the same CPU, and the same fan under the same rotating speed (4200 rpm). The lower heat resistance, the more efficient the cooler.

In addition, the conventional TEC apparatuses don't provide detecting temperature sensors directly contacting the CPUs. Therefore, the control circuits thereof cannot receive precise temperature indications, so cannot precisely control the amount of electricity provided to the TECs in accordance with the indication. Accordingly, it would be very desirable to have an efficient thermoelectric cooling apparatus for an electronic device such as a CPU, or a computer chip which does not suffer from the drawbacks of the conventional coolers or the conventional TEC apparatuses.

The invention will be more clearly understood after referring to the following detailed description read in conjunction with the drawings wherein: Fig. 1 is a side view of the first embodiment of present invention; Fig. 2 is a perspective view of the first embodiment; Fig. 3 is another perspective view of the first embodiment; Fig. 4 illustrates test results of the first embodiment, a conventional TEC and a conventional non-TEC cooler; Fig. 5 is a side view of the second embodiment of present invention; Fig. 6 is another side view of the second embodiment; Fig. 7 is a perspective view of the second embodiment; Fig. 8 is another perspective view of the second embodiment; Fig.9 is a planar view of the third embodiment; and Fig. 10 is a planar view of the fourth embodiment.

The present invention provides a thermoelectric cooling apparatus for cooling an electronic device such as a CPU, or a computer chip. The thermoelectric cooling apparatus cools the electronic device by two stages. In the first stage, the thermoelectric cooling apparatus precools the electronic device by dissipating a portion of the heat produced by the electronic device in a distant location. Thereby the heat of the electronic device is reduced to a degree that a TEC can efficiently process. In the second stage, a TEC of the apparatus dissipate the residual of the heat produced by the electronic device.

With reference to Fig.1 to Fig.3, the first embodiment of the present invention is for cooling a CPU 100. The thermoelectric cooling apparatus contains a front heat absorbing block 1, three front heat pipes 2 (front heat conductive device), a front radiator 3, a thermoelectric cooler 4, and a back radiating module 5. The front heat absorbing block 1 has a first surface 11 and a second surface 12. The first surface 11 is the opposite side of the second surface 12 and the first surface 11 contacts the CPU 100. Each of the front heat pipes 2 has a first portion 21 and a second portion 22. The first portion 21 is connected with the front heat absorbing block 1. The second portion 22 extends from an end of the first portion 21 to a remote end away from the front heat absorbing block 1. The three front heat pipes 2 are parallel to each other. The front radiator 3 is connected with the second portions 22 of the three front heat pipes 2. The thermoelectric cooler 4 has a cold side 41 and a hot side 42. The cold side 41 is the opposite side of the hot side 42. The cold side 41 contacts the second surface 12 of the front heat absorbing block l for transmitting heat collected from the front heat absorbing block 1 from the cold side 41 to the hot side 42. The back radiating module 5 contacts the hot side 42 of the thermoelectric cooler 4 for radiating heat collected therefrom.

The first embodiment further contains a temperature sensor 300 and a control circuit 400. The temperature sensor 300 directly contacts the CPU 100 and providing an indication thereof to the control circuit 400 wherein the control circuit 400 is coupled to the thermoelectric cooler 4 for varying amount of electricity in accordance with the indication.

The first portion 21 of the front heat pipe 2 is embedded in the front heat absorbing block I and the second portion 22 of the front heat pipe 2 is installed in the front radiator 3. The back radiating module 5 contains a back heat absorbing block 51, three back heat pipes 52 and a back radiator 53. The back heat absorbing block 51 contacts the hot side 42 of the thermoelectric cooler 4.

Each of the back heat pipes 52 has a first portion 521, a second portion 522 and a third portion 523. The first portion 521 is connected with the back heat absorbing block 51 and the second portion 522 extends from an end of the first portion 521 to a remote end away from the back heat absorbing block 51. The third portion 523 extends from the other end of the first portion 521 thereof to a remote end away from the back heat absorbing block 51. The back radiator 53 is connected with the second portions 522 and the third portions 523 of the back heat pipes 52. The first portion 521 of the back heat pipes 52 is embedded in the back heat absorbing block 51. The second and the third portions 522, 523 of the back heat pipes 52 are installed in the back radiator 53.

The front radiator 3 contains plural parallel first cooling fins 31 having plural first channels 32 formed therebetween. The back radiator 53 contains plural parallel second cooling fins 531 having plural second channels 532 formed therebetween. The first channels 32 are aligned with the second channels 532. A fan 200 is attached to the front radiator 3 and blows the first channels 32 first, then the second channels 532, because the back radiator 53 dissipates more heat than the front radiator 3.

The front heat absorbing block 1 is fastened to the CPU 100 by clippers to provide a tight contact surface therebetween thereby the heat produced by the CPU 100 can be absorbed by the front heat absorbing block l efficiently. The heat produced by the CPU 100 is dissipated through two routes. The first route is through the front heat absorbing block 1, the front heat pipes 2, and the front radiator 3 in order. The second route is through the front heat absorbing block 1, the thermoelectric cooler 4, the back heat absorbing block 51, the back heat pipes 52 and the back radiator 53 in order. The front radiator 3 is located away from the front heat absorbing block 1 to dissipate a portion of the heat produced by the CPU 100. Thereby the temperature of the CPU 100 is reduced to a degree that the thermoelectric cooler 4 operates almost always under low wattage applications, under which the thermoelectric cooler 4 operates efficiently.

In accordance to Fig. 4, which contains test results of the first embodiment (curve C3), the conventional TEC (curve C2) and the conventional non-TEC cooler (curve C1), the first embodiment has better performance than the conventional TEC and the conventional non-TEC cooler under high wattage applications (more than 60 watts) and the heat resistance of the first embodiment is always under 0.25, which is the constant heat resistance of the conventional non-TEC cooler.

With reference to Figs. 5-8, the second embodiment of the present invention for cooling the CPU 100 mainly contains: a front heat absorbing block la, three front heat pipes 2a (front heat conductive device), a front radiator 3a, two thermoelectric coolers 4a, and two back radiating modules 5a.

The front heat absorbing block la has a bottom surface lla and two side surfaces 12a, 13a. The bottom surface 1 la contacts the CPU 100. Each of the front heat pipes 2a has a first portion 21a and a second portion 22a. The first portion 21a is connected with and embedded in the front heat absorbing block la. The second portion 22a extends from an end of the first portion 21a to a remote end away from the front heat absorbing block la and crooked into the front radiator 3a. One front heat pipe 2a has the second portion 22a extends from one direction and the other two front heat pipe 2a has the second portions 22a extends from the opposite direction. Each of the two thermoelectric coolers 4a has a cold side 41a and a hot side 42a and the cold side 41a is the opposite side of the hot side 42a. Each of the two thermoelectric coolers 4a contacts one of the two side surfaces 12a, 13a of the front heat absorbing block la with the cold side 41a for transmitting heat collected from the front heat absorbing block la from the cold side 41a to the hot side 42a. The two back radiating modules 5a contact the hot sides 42a of the two thermoelectric coolers 4a respectively for radiating heat collected therefrom.

The second embodiment further contains the temperature sensor 300 and the control circuit 400. The temperature sensor 300 directly contacts the CPU and providing an indication thereof to the control circuit 400 wherein the control circuit 400 is coupled to the thermoelectric coolers 4a for varying amount of electricity in accordance with the indication.

Each of the two back radiating modules 5a contains a back heat absorbing block 51a, two back heat pipes 52a and a back radiator 53a. The back heat absorbing block 51 a, contacts a hot side 42a of one of the two thermoelectric coolers 4a. Each of the two back heat pipes 52a, has a first portion 521a, and a second portion 522a. The first portion 521a is connected with and embedded in the back heat absorbing block 51a. The second portion 522a extends from an end of the first portion 521a to a remote end away from the back heat absorbing block 51a and crooked into and is connected with the back radiator 53a.

The front radiator 3a contains plural parallel first cooling fins 31a having plural first channels 32a formed therebetween. The two back radiators 53a contain plural parallel second cooling fins 531a having plural second channels 532a formed therebetween. The first channels 32a are aligned with the second channels 532a.

The front radiator 3a is placed above of the two back radiators 53a and a fan 200 is placed above the front radiator 3a. Thereby the fan 200 blows the front radiator 3a first, then the back radiator 53a. This preferred arrangement is based on that the back radiator 53a dissipates more heat than the front radiator 3a.

The water-cooling loop 2b dissipates the heat in the front heat absorbing block lb and the back heat absorbing block 51b through repeating the following steps: 1. The pump 500 pumps cold cooling water to the front heat absorbing block lb; 2. The cold cooling water runs through the front heat absorbing block lb via the heat pipes and also takes away the heat collected by the front heat absorbing block lb; therefore, the cold cooling water becomes warm cooling water; 3. The warm cooling water then runs through the back heat absorbing block 51b via the heat pipes and also takes away the heat collected by the back heat absorbing block 5 lb; therefor the warm cooling water becomes hot cooling water; and 4. The hot cooling water is cooled to becoming cold cooling water by the front radiator 3b and the cooled cold cooling water is then delivered to the pump 500. Furthermore, the front radiator 3b associated with the fan 200 helps with the cooling processes.

With reference to Fig. 10, the fourth embodiment contains a front heat absorbing block lo, a first water-cooling loop 2-lc, a second watercooling loop 2-2c, a front radiator 3 c, a back radiator 53 c, a thermoelectric cooler 4c, a back heat absorbing block 51c, a first pump 501 and a second pump 502. The front heat absorbing block to has a first surface tic and a second surface 12c. The first surface tic is the opposite side of the second surface 12c and the first surface l to contacts the CPU lOO. The thermoelectric cooler 4c has a cold side 41 c and a hot side 42c.The cold side 41 c is the opposite side of the hot side 42c.

The cold side 41c contacts the second surface 12c of the front heat absorbing block to for transmitting heat collected from the front heat absorbing block to from the cold side 41c to the hot side 42c. The back heat absorbing block 51c contacts the hot side 42c of the thermoelectric cooler 4c. Similarly to the third embodiment, the first water-cooling loop 2-lc is arranged for systematically linking up the front heat absorbing block lo, the front radiator 3c and the first pump 501 by utilizing heat pipes. In addition, the second water-cooling loop 2 2c is arranged for systematically linking up the back heat absorbing block 51c, the back radiator 53c and the second pump 502 by utilizing heat pipes.

Furthermore, both the first water-cooling loop 2-lc and the second water cooling loop 2-2c contain cooling water within respectively for water circulation by the first pump 501 and the second pump 502.

The front heat absorbing block I and the back heat absorbing block 51 in the first embodiment, and the front heat absorbing block la and the back heat absorbing block 51 a in the second embodiment are made of copper or aluminum. The first cooling fins 31, 31a and the second cooling fins 531, 531a are made of extruded aluminum or by punching aluminum or copper plates. The thermoelectric coolers 4, 4a in the first and the second embodiments are Marlow DT12-6 or Melcor CP 1.4-127-06L.

Numerous characteristics and advantages of the invention have been set forth in the foregoing description, together with details of the structure and function of the invention, and the novel features thereof are pointed out in appended claims. The disclosure, however, is illustrated only, and changes may be made in detail, especially, in matters of shape, size and arrangement of parts, materials and the combination thereof within the principle of the invention, to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.

Claims

1. A thermoelectric cooling apparatus for cooling an electronic device comprising: a front heat absorbing block having a first surface and a second surface, said first surface being the opposite side of said second surface, said first surface contacting said electronic device; a front heat conductive device having a first portion and a second portion, said first portion being connected with said front heat absorbing block, said second portion extending from an end of said first portion to a remote end away from said front heat absorbing block; a front radiator connected with said second portion of said front heat conductive device; a thermoelectric cooler having a cold side and a hot side, said cold side being the opposite side of said hot side, said cold side contacting said second surface of said front heat absorbing block for transmitting heat collected from said front heat absorbing block from said cold side to said hot side; and a back radiating module contacting said hot side of said thermoelectric cooler for radiating heat collected therefrom.

2. The apparatus of claim 1 further comprising a fan for blowing said front radiator.

3. The apparatus of claim 1, wherein said front heat conductive device comprises at least a heat pipe.

4. The apparatus of claim 1, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said back radiating module, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump.

5. The apparatus of claim 1, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump.

6. The apparatus of claim I further comprising a temperature sensor and a control circuit, said temperature sensor directly contacting said electronic device and providing an indication thereof to said control circuit wherein the said control circuit is coupled to said thermoelectric cooler for varying amount of electricity in accordance with said indication.

7. The apparatus of claim 1 wherein said first portion of said front heat conductive device is embedded in said front heat absorbing block and said second portion of said front heat conductive device is installed in said front radiator.

8. The apparatus of claim 1 wherein said back radiating module comprises: a back heat absorbing block, contacting said hot side of said thermoelectric cooler; at least a back heat pipe, having a first portion and a second portion, said first portion being connected with said back heat absorbing block, said second portion extending from an end of said first portion to a remote end away from said back heat absorbing block; and a back radiator, connected with said second portion of said at least a back heat pipe.

9. The apparatus of claim 8, wherein said at least a back heat pipe further comprises a third portion extending from the other end of said first portion thereof to a remote end away from said back heat absorbing block, said first portion of said at least a back heat pipe being embedded in said back heat absorbing block, said second and said third portions of said at least a back heat pipe being installed in said back radiator.

10. The apparatus of claim 8 further comprising a fan, wherein said front radiator comprises plural parallel first cooling fins having plural first channels formed therebetween, said back radiator having plural parallel second cooling fins having plural second channels formed therebetween, said first channels being aligned with said second channels, said fan blowing said first channels first, then said second channels.

11. A thermoelectric cooling apparatus for cooling an electronic device comprising: a front heat absorbing block comprising a bottom surface and two side surfaces, said bottom surface contacting said electronic device; a front heat conductive device having a first portion and a second portion, said first portion being connected with said front heat absorbing block, said second portion extending from an end of said first portion to a remote end away from said front heat absorbing block; a front radiator, connected with said second portion of said front heat conductive device; two thermoelectric coolers, each of said two thermoelectric coolers having a cold side and a hot side, said cold side being the opposite side of said hot side, each of said two thermoelectric coolers contacting one of said two side surfaces of said front heat absorbing block with said cold side for transmitting heat collected from said front heat absorbing block from said cold side to said hot side; and two back radiating modules contacting said hot sides of said two thermoelectric coolers respectively for radiating heat collected therefrom.

12. The apparatus of claim I 1, wherein said front heat conductive device comprises at least a heat pipe.

13. The apparatus of claim I 1, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said two back radiating modules, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump.

14. The apparatus of claim 11, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump.

15. The apparatus of claim 11 further comprising a fan for blowing said front radiator.

16. The apparatus of claim I I further comprising a temperature sensor and a control circuit, said temperature sensor directly contacting said electronic device and providing an indication thereof to the control circuit wherein said control circuit is coupled to said two thermoelectric coolers for varying amount of electricity in accordance with said indication.

17. The apparatus of claim 11 wherein said first portion of said front heat conductive device is embedded in said front heat absorbing block and said second portion of said front heat conductive device is installed in said front radiator.

18. The apparatus of claim 1 1, wherein each of said two back radiating modules comprises: a back heat absorbing block, contacting a hot side of one of said two thermoelectric coolers; at least a back heat pipe, having a first portion and a second portion, said first portion being connected with said back heat absorbing block, said second portion extending from an end of said first portion to a remote end away from said back heat absorbing block; and a back radiator, connected with said second portion of said at least a back heat pipe.

19. The apparatus of claim 18, wherein said second portion of said at least a back heat pipe is crooked into said back radiator, said first portion of said at lease a back heat pipe being embedded in said back heat absorbing block.

20. The apparatus of claim 18 further comprising a fan wherein said front radiator comprises plural parallel first cooling fins having plural first channels formed therebetween, said two back radiators having plural parallel second cooling fins having plural second channels formed therebetween, said first channels being aligned with said second channels, said fan blowing said first channels first, then said second channels.

21. A thermoelectric cooling apparatus for cooling an electronic device as herein described above and illustrated in the accompanying drawings.

6. The apparatus of claim 1 further comprising a temperature sensor and a control circuit, said temperature sensor directly contacting said electronic device and providing an indication thereof to said control circuit wherein the said control circuit is coupled to said thermoelectric cooler for varying amount of electricity in accordance with said indication.

8. The apparatus of claim 1, wherein said at least a back heat pipe further comprises a third portion extending from the other end of said first portion thereof to a remote end away from said back heat absorbing block, said first portion of said at least a back heat pipe being embedded in said back heat absorbing block, said second and said third portions of said at least a back heat pipe being installed in said back radiator.

9. The apparatus of claim 1 further comprising a fan, wherein said front radiator comprises plural parallel first cooling fins having plural first channels formed therebetween, said back radiator having plural parallel second cooling fins having plural second channels formed therebetween, said first channels being aligned with said second channels, said fan blowing said first channels first, then said second channels.

11. The apparatus of claim 10, wherein said front heat conductive device comprises at least one heat pipe.

12. The apparatus of claim 10, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said two back radiating modules, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump. it\

13. The apparatus of claim 10, wherein said front heat conductive device comprises a water-cooling loop for systematically linking up said front heat absorbing block, said front radiator and a pump, said water-cooling loop having cooling water within for water circulation by said pump.

14. The apparatus of claim 10 further comprising a fan for blowing said front radiator.

1S. The apparatus of claim 10 further comprising a temperature sensor and a control circuit, said temperature sensor directly contacting said electronic device and providing an indication thereof to the condo] circuit wherein said control circuit is coupled to said two thermoelectric coolers for varying amount of electricity in accordance with said indication.

16. The apparatus of claim 10 wherein said first portion of said front heat conductive device is embedded in said front heat absorbing block and said second portion of said front heat conductive device is installed in said front radiator.

17. The apparatus of claim 10, wherein said second portion of said at least a back heat pipe is crooked into said back radiator, said first portion of said at lease a back heat pipe being embedded in said back heat absorbing block.

18. The apparatus of claim 10 further comprising a fan wherein said front radiator comprises plural parallel first cooling fins having plural first channels formed therebetween, said two back radiators having plural parallel second cooling fins having plural second channels formed therebetween, said first channels being aligned with said second channels, said fan blowing said first channels first, then said second channels.

519. A thermoelectric cooling apparatus for cooling an electronic device as herein described above and illustrated in the accompanying drawings. (