CN102300440A - Flexible radiating guide tube - Google Patents
Flexible radiating guide tube Download PDFInfo
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- CN102300440A CN102300440A CN2010102053202A CN201010205320A CN102300440A CN 102300440 A CN102300440 A CN 102300440A CN 2010102053202 A CN2010102053202 A CN 2010102053202A CN 201010205320 A CN201010205320 A CN 201010205320A CN 102300440 A CN102300440 A CN 102300440A
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Abstract
The invention discloses a flexible radiating guide tube. The flexible radiating guide tube comprises an outer tube, a heat conducting piece, a radiating piece, at least one soaking ring, at least one liquid suction guide tube and at least one inner tube, wherein the outer tube is a flexible tube; at least one accommodating chamber is formed in the outer tube; the heat conducting piece and the radiating piece are respectively combined at the two ends of the outer tube; an electronic load is connected with the surface of the heat conducting piece; the soaking ring is connected with the inner edge of the heat conducting piece; the inner tube and the liquid suction guide tube are accommodated in the accommodating chamber of the outer tube; the liquid suction guide tube is coated by the inner tube; the two ends of the liquid suction guide tube are respectively combined with the heat conducting piece and the radiating piece; the accommodating chamber between the inner tube and the outer tube is separated to form at least one circulating pipeline; at least one fluid heat conducting media is filled in the circulating pipeline so that the heat energy generated by a load heat source can heat the fluid heat conducting media between the heat conducting piece and the soaking ring after being absorbed by the heat conducting piece; and the fluid heat conducting media is conducted to the radiating piece for radiating and cooling along the liquid suction guide tube by a capillary action, and is circulated back to the soaking ring at the end of the heat conducting piece through the circulating pipeline by the radiating piece.
Description
Technical field
The present invention relates to a kind of flexible radiating conduit, particularly a kind of utilization is provided with at least one imbibition conduit in inside, conducts the flexible radiating conduit of at least a fluid heat-conducting medium heat radiation and directionless restriction circulation with capillarity.
Background technology
Press, the electronic load that existing integrated circuit, power transistor, chipset, the contour heat energy of light-emitting diode (LED) light fixture produce, need to utilize the collocation of radiator or cooling mechanism in the use, can normal running, existing electronic load adopts the radiating fin of passive type or the cooling air mode of radiator to apply use, except radiating rate slow, the cooling efficient of thermal source or focus also is very poor, and the each point exothermic temperature that connects on the face of electronic load and radiator is inhomogeneous, and the industry that do not meet utilizes demand, and is eliminated gradually.
Or have so germinate the ameliorator, dispose and injection cooling fluid or cooling fluid in pipe with metal tubes, and link the radiator mode again the heat radiation of above-mentioned electronic load is provided, but because cooling fluid or the slow problem of cooling fluid flow rate, if promote cooling fluid or cooling fluid by thermal convection merely, can't reach the effect of rapid heat radiation at all, and can install direction by limited electronic load, for example: led lamp installing direction is above radiator, when promptly throwing light and making progress, as only dispelling the heat by the thermal convection mode, basic be difficult to upwards promote cooling fluid or cooling fluid is smooth and easy and flow fast, therefore, must add small-sized electric pumping pressurization usually and promote cooling fluid or cooling fluid, but this kind mode, certainly will allow the small-sized electric pumping consume extra electric power and equipment cost, not have an economic benefit, and, installing also and must take up room, making its application category limited.
Above-mentioned existing metal tubes configuration electronic load, so that the mechanism of heat radiation to be provided, the another one shortcoming is to be that this metal tubes such as need cooperate the installing occasion or the mechanism design of electronic load, for example: be disposed in the narrow and small casing, then can't be disposed smoothly, thereby influence its industrial utilization, and, this metal tubes is on bending angle and configuration path, can be subject to the bending angle limit and the deformation limit of metal tubes, can't be applicable in the electronic product mechanism of various difformities and arrangement of components position, must walk around or keep away some mechanism or electronic building brick such as this metal tubes, and the configuration that must significantly bend or unroll, the heat radiation of then existing metal tubes configuration also can't be suitable for, thereby limits the category of its application.
Aspect relevant previous patented technology document, as I265772 number " liquid cooling is a system " patent of invention case of TaiWan, China patent gazette, the liquid cooling that then discloses the existing metal tubes configuration of typical case is a system, similarly, can produce the clear metal tubes that reaches of metal tubes radiating efficiency and dispose problem and the shortcoming that bending is subject to mechanism space, shape and electronic building brick allocation position obstruction.
In addition, such as No. 553602 " heat radiator improvement structure " novel patent case of TaiWan, China patent gazette, then disclose the radiator that cooperates the pliability radiating tube to be formed with small-sized pumping, offer the usefulness of electronic load as heat radiation, though the problem of above-mentioned metal tubes bending configuration can be improved, but still cooling fluid or the slow problem of cooling fluid flow rate can't be solved, and the small-sized pumping pressurized delivered of essential dependence, essential consume extra electric power and increase equipment cost, do not have an economic benefit.
From the above mentioned, the heat abstractor of existing electronic load, dispel the heat uneven by radiating rate, the efficient of cooling air mode are not good with the face that connects, as dispelling the heat by the circulation of metal tubes configuration in the former case, then this electronic load is provided with limited location, in addition, promote the liquid circulation heat radiation, then need expend additional power, cost is higher and take installing space as adding small-sized electric pumping pressurization.
Summary of the invention
In order to overcome the above-mentioned shortcoming that prior art exists, the invention provides a kind of flexible radiating conduit, its cost is low, need not expend volume electric power and equipment, no matter and under the state of liquid, gas or gas, liquid two phase change, the flexible radiating conduit of at least a fluid heat-conducting medium from body circulation radiating effect all can be provided fast, and, has pliability, what be not subjected to electronic load is provided with position, direction and mechanism, spatial limitation, can be applied in the installation and the application of the electronic load of difformity, mechanism's space size.
To achieve these goals, the present invention takes following technical scheme:
A kind of flexible radiating conduit is characterized in that, comprising:
One outer tube is a pliability pipe, at least one room of inner formation;
One heat-conducting piece is linked to room one end of outer tube, and the surface of heat-conducting piece absorbs to heat-conducting piece with the thermal source with electronic load at least one electronic load combination;
One heat sink is linked to the other end of the room of outer tube;
At least one soaking ring, for imbibition material constitutes, this soaking ring is incorporated into the heat-conducting piece inner edge, forms at least one perforation in this soaking ring;
At least one imbibition conduit and at least one interior pipe, this imbibition conduit is that imbibition material constitutes, pipe is coated on the outside of imbibition conduit in being somebody's turn to do, allow part, imbibition conduit two ends expose, the corresponding perforation of inserting the soaking ring of this imbibition conduit one end links with the heat-conducting piece inner edge again, this imbibition conduit other end links the inner edge of heat sink, make this imbibition conduit be linked to the soaking ring, in the room space between heat-conducting piece and heat sink, at least separated between pipe and outer tube in being somebody's turn to do and formed at least one circulating line, at least fill a kind of fluid heat-conducting medium in this circulating line, after seeing through the heat-conducting piece absorption at thermal source, heat the middle fluid heat-conducting medium of heat-conducting piece and soaking ring again, make the fluid heat-conducting medium produce liquid, gas two phase change, relend by capillarity and conduct to the cooling of heat sink radiating and cooling, be circulated back in the soaking ring of heat-conducting piece end via circulating line by heat sink again along the imbibition conduit.
The effect of flexible radiating conduit of the present invention, be to be to make fluid heat-conducting medium no matter be liquid as cooling fluid by the capillarity of this imbibition conduit, gas heat radiation or gas, liquid cooling is state but, radiating effect smoothly all can circulate, and outer tube has flexible bending characteristic, not limited electronic load is arranged at, down, left or right direction, the position, mechanism and shape, and can be by the room of the formation that separates between pipe in this and the outer tube, making the interior fluid heat-conducting medium of imbibition conduit and room have the temperature difference separates, and the thermal convection circulation radiating effect that formation tool capillarity is quickened, allow the thermal source of electronic load can be recycled cooling rapidly, and, see through the setting of soaking ring, make the each point exothermic temperature that connects on the face of electronic load even, do not use additional power and equipment to reach, and the energy-conserving and environment-protective of tool high efficiency and heat radiation are from the circulation heat radiation function of the directionless restriction of body.
Description of drawings
Fig. 1 is the three-dimensional appearance structural representation of flexible radiating conduit first embodiment of the present invention.
Fig. 2 is the three-dimensional decomposition texture schematic diagram of Fig. 1.
Fig. 3 is the cutaway view Amplified image of Fig. 1.
Fig. 4 is that flexible radiating conduit first of the present invention is used illustration.
Fig. 5 is that flexible radiating conduit second of the present invention is used illustration.
Fig. 6 is that flexible radiating conduit the 3rd of the present invention is used illustration.
Fig. 7 is that flexible radiating conduit second of the present invention is implemented illustration.
Fig. 8 is that flexible radiating conduit the 3rd of the present invention is implemented illustration.
Fig. 9 is that flexible radiating conduit the 4th of the present invention is implemented illustration.
Figure 10 is the cutaway view Amplified image of Fig. 9.
Figure 11 is the A-A ' cutaway view of Figure 10.
Figure 12 is the heat-conducting piece end actual amount measuring point schematic diagram of flexible radiating conduit of the present invention.
Figure 13 is the heat sink end actual amount measuring point schematic diagram of flexible radiating conduit of the present invention.
Figure 14 is the actual measurement data and curves figure of the measuring point of Figure 12 and Figure 13.
Figure 15 is the actual measurement data and curves figure of the measuring point of existing air-cooling type radiator.
The primary clustering symbol description
100 flexible radiating conduits, 10 outer tubes
11 rooms, 111 sealed threads
112 sealed thread 113 circulating lines
114 fluid heat-conducting mediums, 115 circulating lines
116 circulating lines, 117 circulating lines
118 circulating lines, 20 heat-conducting pieces
21 junction surfaces, 211 threads
212 jacks, 30 heat sinks
31 junction surfaces, 311 threads
312 jacks, 40 soaking rings
41 perforation, 50 imbibition conduits
Manage in pipe 70 imbibitions in 60
200 electronic loads, 200 ' electronic load
300 radiating fin group A1 measuring points
A2 measuring point A3 measuring point
A4 measuring point T time shaft
The P temperature axis
Embodiment
See also Fig. 1, Fig. 2 and shown in Figure 3, first embodiment for flexible radiating conduit 100 of the present invention, wherein, this flexible radiating conduit 100 comprises an outer tube 10, and this outer tube 10 is a heat carrier, and be a pliability pipe, for example: soft silicone tube, can do flexible bending, form at least one room 11 in this outer tube 10, these room 11 upper end inwalls are provided with some sealed threads 111, and these room 11 lower end inwalls are provided with some sealed threads 112.
One heat-conducting piece 20, for Heat Conduction Material constitutes, as metal materials such as aluminium, copper or alloys, can link for an electronic load 200 in outer surface, the pattern of this electronic load 200 is not limit, be to be example in the present invention with a led lamp, this heat-conducting piece 20 also forms a junction surface 21 in inner edge, these junction surface 21 outer rims are provided with some threads 211, these thread 211 correspondences are threaded into the sealed thread 111 of room 11 upper ends of outer tube 10, make this heat-conducting piece 20 be incorporated into room 11 upper ends of this outer tube 10, these junction surface 21 inner edges then are provided with at least one jack 212.
One heat sink 30, for Heat Conduction Material constitutes, as metal materials such as aluminium, copper or alloys, form a junction surface 31 in inner edge, these junction surface 31 outer rims are provided with some threads 311, these thread 311 correspondences are threaded into the sealed thread 112 of room 11 lower ends of outer tube 10, make this heat sink 30 be incorporated into room 11 lower ends of this outer tube 10, and these junction surface 31 inner edges then are provided with at least one jack 312.
The combining structure that the room of above-mentioned heat-conducting piece 20, heat sink 30 and outer tube 10 is 11, do not exceed in the corresponding screw lock mode of 112 of thread 211, sealed thread 111 and thread 311, sealed threads, such as be the combining structure of equivalence, as equivalent structure such as binding or chimeric, when not taking off category of the present invention.
At least one soaking ring 40, for imbibition material constitutes, as imbibition materials such as adhesive-bonded fabric, sponges, this soaking ring 40 is incorporated into 21 surfaces, junction surface of heat-conducting piece 20 inner edges, form at least one perforation 41 in this soaking ring 40, these perforation 41 kisses are to the jack 212 of this heat-conducting piece 20.
At least one imbibition conduit 50 and at least one interior pipe 60, this imbibition conduit 50 constitutes for imbibition material, as adhesive-bonded fabric, imbibition materials such as sponge, should interior pipe 60 be that heat-resisting thermal insulation material constitutes, as rubber or plastics, pipe 60 is coated on the outside of imbibition conduit 50 in being somebody's turn to do, only allow part, imbibition conduit 50 two ends expose, the corresponding respectively perforation 41 of soaking ring 40 and the jack 212 of heat-conducting piece 20 of inserting in these imbibition conduit 50 two ends, the jack 312 of heat sink 30, make this imbibition conduit 50 be linked to soaking ring 40, in room 11 spaces that heat-conducting piece 20 and heat sink are 30, allow this interior pipe 60 and 10 quilts of outer tube separate and form at least one circulating line 113, at least fill a kind of fluid heat-conducting medium 114 in this circulating line 113, the pattern of this fluid heat-conducting medium 114 is not limit, be to be example with the cooling fluid in the present invention, other is as the fluid media (medium) of water or wet goods tool radiating effect, when not taking off category of the present invention.
The connecting structure that above-mentioned imbibition conduit 50 two ends and heat-conducting piece 20, heat sink are 30, not being plugged in jack 212 and jack 312 exceeds, other equivalent connecting structure is as binding or chimeric, when not taking off category of the present invention.
Please cooperate shown in Figure 4 again, first application examples for flexible radiating conduit 100 of the present invention, wherein, when showing the electronic load 200 generation thermals source of this led lamp kenel, after this thermal source sees through heat-conducting piece 20 absorptions, heat the fluid heat-conducting medium 114 of heat-conducting piece 10 and soaking ring 40 centres again, make fluid heat-conducting medium 114 produce liquid, gas two phase change, relend by capillarity and conduct to the cooling of heat sink 30 radiating and coolings downwards along imbibition conduit 50, be circulated back to the soaking ring 40 (shown in the direction of arrow among Fig. 4) of heat-conducting piece 20 ends again via circulating line 113 by heat sink 30, at last, absorb this fluid heat-conducting medium 114 by this soaking ring 40 again, move this soaking ring 40 and the heat-conducting piece 20 surperficial Homogeneouslly-radiating functions that go up every bit that electronic load 200 are provided and linked and repeat above-mentioned circulation radiating and cooling.
By above-mentioned heat radiation circulating path, can allow the thermal source of electronic load 200 or the high temperature of focus take to heat sink 30 ends and to lower the temperature via imbibition conduit 50 capillarities rapidly rapidly, and, no matter whether this fluid heat-conducting medium 114 has generation liquid, gas heat radiation or gas, liquid cooling two phase change but, all can see through this imbibition conduit 50 and quicken conducting effect, and in this pipe 60 and outer tube 10 to separate formation temperature poor, make fluid heat-conducting medium 114 and the fluid heat-conducting medium in the circulating line 113 114 in the imbibition conduit 50 form one hot one cold thermal convection secondary acceleration cycle effect, allow the heat radiation cycle rate of fluid heat-conducting medium 114 quicken.
Please cooperate shown in Figure 5 again, second application examples for flexible radiating conduit 100 of the present invention, wherein, show the state that electronic load 200 is provided with down, similarly, can comply with above-mentioned identical fluid heat-conducting medium 114 cycle heat radiation path (shown in the direction of arrow among Fig. 5), conduct to the cooling of heat sink cooling by heat-conducting piece 20 via these imbibition conduit 50 capillarities rapidly, and see through the soaking ring 40 that circulating line 113 is circulated back to heat-conducting piece 20 ends, in like manner can get, no matter this electronic load 200 is provided with direction towards a left side or towards the right side, this effect from body circulation heat radiation is also all arranged, therefore, the present invention can not be subjected to electronic load 200 that the restriction of position and direction is set, all can bring into play make the 114 directionless restrictions of fluid heat-conducting medium from body circulation heat radiation function.
Please consult shown in Figure 6 again, the 3rd application examples for flexible radiating conduit 100 of the present invention, wherein, show that these heat-conducting piece 20 surfaces link the electronic load 200 ' of a chipset, these heat sink 30 surfaces then link a radiating fin group 300, and by the pliability of this outer tube 10 bending characteristic, can in as occasions such as computer housing or motherboards, carry out the bending configuration of various angles, can make equally this chipset electronic load 200 ' heat energy rapidly and conduct to long-range radiating fin group 300 effectively and carry out radiating and cooling, and make the imbibition conduit 50 of this fluid heat-conducting medium 114 in outer tube 10,113 of soaking ring 40 and circulating lines carry out the circulation heat radiation operation from the directionless restriction of body.
Please consult shown in Figure 7 again, second embodiment for flexible radiating conduit 100 of the present invention, wherein, circulating line 113 interior the fillings at least one imbibition that show 60 of this outer tube 10 and interior pipes manage 70, pipe 70 is constituted by imbibition material in this imbibition, as adhesive-bonded fabric or sponge, to absorb this fluid heat-conducting medium 114, equally can be as the capillarity of this imbibition conduit 50, bring into play the effect of rapid conducting fluid heat-conducting medium 114, can reach the thermal convection circulating effect of the simple fluid liquid heat-conducting medium 114 of Fig. 1 to first embodiment shown in Figure 6 equally.
Please cooperate shown in Figure 8, the 3rd embodiment for flexible radiating conduit 100 of the present invention, wherein, junction surface 31 surface combination, the one soaking ring 40 that shows these heat sink 30 inner edges, perforation 41 kisses of this soaking ring 40 are to the jack 312 at this junction surface 31, pass for these imbibition conduit 50 1 ends, make the heat radiation at every bit position on surface of heat sink 30 more even, and quicken this fluid heat-conducting medium 114 in as Fig. 4 and the circulation radiating efficiency from the body circulating path shown in Figure 5.
Please consult Fig. 9 again, Figure 10 and shown in Figure 11, the 4th embodiment for flexible radiating conduit 100 of the present invention, wherein, junction surface 21 inner edges that show this heat-conducting piece 20 are provided with several jacks 212, junction surface 31 inner edges of this heat sink 30 are provided with several jacks 312, this is incorporated into and is provided with several perforation 41 in the soaking ring 40 in heat-conducting piece 20 and the heat sink 30, pipe 60 and imbibition conduit 50 combination in this several group, 41 each jack 212 that is plugged in the junction surface 21 of heat-conducting piece 20 again of respectively boring a hole are passed at each imbibition conduit 50 two ends respectively, and between each jack 312 at the junction surface 31 of heat sink 30, these several interior pipe of group 60 rooms 11 with outer tube 10 are separated form several circulating lines 115,116,117 and 118, make this be filled in each circulating line 115,116, fluid heat-conducting medium 114 in 117 and 118, more groups imbibition conduit 50 and circulating line 115 are arranged, 116,117 and 118 common form careful from body recirculating network (as shown in figure 10), can quicken this fluid heat-conducting medium 114 from body circulation radiating rate and the radiating efficiency that promotes this electronic load 200.
Please cooperate Figure 12, Figure 13, Figure 14 and shown in Figure 15 again, be flexible radiating conduit 100 of the present invention and the measurement control curve figure that does not install the existing air-cooling type radiator of imbibition conduit 50, interior pipe 60 and fluid heat-conducting medium 114 among the present invention, this Figure 12 shows that measuring point A1 and A2 are respectively 2 points on heat-conducting piece 20 surfaces; Figure 13 shows that measuring point A3 and A4 are respectively 2 points on heat sink 30 surfaces, the following tabulation one of the measurement of flexible radiating conduit 100 of the present invention and shown in Figure 14, and the following tabulation two of existing air-cooling type radiator measurement of control group and shown in Figure 15, this lateral shaft is time shaft T, longitudinal axis is temperature axis P, wherein:
(table)
| 12 | 63.5 | 61.1 | 61.8 | 60.3 |
| 13 | 64.7 | 60.9 | 61.6 | 60.5 |
| 14 | 65.5 | 62.9 | 63.8 | 61.4 |
| 15 | 66.4 | 64.7 | 65.1 | 64 |
| 16 | 70.9 | 67.1 | 67.5 | 66.9 |
| 17 | 71.5 | 67.6 | 68 | 67.1 |
| 18 | 72.8 | 68.2 | 70.4 | 67.5 |
| 19 | 74.5 | 69.6 | 71.6 | 68.4 |
| 20 | 74.6 | 71.9 | 72.7 | 70.5 |
| 21 | 77.5 | 74.1 | 74.9 | 73.7 |
| 22 | 77.6 | 75 | 75.2 | 74.7 |
| 23 | 77.6 | 75.1 | 75.8 | 74.7 |
(table two)
| 14 | 75.7 | 67.8 | 65.9 | 65.5 |
| 15 | 76.5 | 68.1 | 67.6 | 67 |
| 16 | 78 | 69.6 | 68.1 | 68 |
| 17 | 79.5 | 70.2 | 69.3 | 69 |
| 18 | 80 | 71.1 | 69.9 | 69.5 |
| 19 | 82 | 71.4 | 70.5 | 70.1 |
| 20 | 83 | 72.8 | 70.8 | 70.6 |
| 21 | 84 | 73.2 | 72.5 | 72.1 |
| 22 | 84.1 | 73.8 | 73.4 | 72.2 |
| 23 | 87.1 | 75.1 | 74.5 | 73.5 |
By above table one and table two, and the experimental data between Figure 14 and Figure 15 can obtain following conclusion in addition under the compare of analysis:
1. measure data analysis relatively from flexible radiating conduit 100 tests of the present invention, the maximum temperature that A1 is ordered is 77.6 ℃, and the maximum temperature that A2 is ordered is 75.1 ℃, and the maximum temperature that A3 is ordered is 75.8, and the maximum temperature that A4 is ordered is 74.8 ℃.The temperature difference that A1 point and A4 are ordered is in 3 ℃ of scopes, and just reach thermal equilibrium state about 20 minutes, measuring A1 point temperature after 10 hours is 76.3 degree, and measures electronic load 200 brightness of led lamp kenel, the same with original brightness, do not see decay.
2. measure data analysis relatively from the test of existing air-cooling type radiator, the maximum temperature of ordering with respect to the A1 of Figure 12 is that the maximum temperature that 87.1 ℃, A2 are ordered is 75.1; The maximum temperature of ordering with respect to the A3 of Figure 13 is 74.5 ℃, the maximum temperature that A4 is ordered is 73.5 ℃, the temperature difference that temperature that A1 is ordered and A4 are ordered is 12.3 ℃ to the maximum, and also do not reach heat balance, A1 point measuring temperature reaches 112 ℃ after 10 hours, measuring this electronic load 200 brightness with respect to the led lamp kenel of Figure 12 again, only is original 60%, and tangible optical attenuation phenomenon is arranged.
3. flexible radiating conduit 100 of the present invention hangs down 13.6 ℃ than the radiator temperature of existing air-cooling type radiator, shows that flexible radiating conduit 100 of the present invention has the very fast radiating efficiency preferably that reaches.
By the bulk temperature difference of flexible radiating conduit 100 of the present invention only in 3 ℃ of small scopes, and the bulk temperature difference of existing air-cooling type radiator is more than 13 ℃, this point illustrated the present invention can be effectively electronic load 200 all heat energy be delivered to fast the radiating fin 11 of outer tube 10 and heat sink 30 have a few, make it carry out heat exchange with outside air fast, with reduction node temperature (junctiontemperatures), and then ensure the life-span of electronic load 200 and stablizing of light-source brightness.
5. the temperature difference of being ordered by A1 point in the flexible radiating conduit 100 of the present invention and A4 is only in narrow range, and the not recipient of seem card the present invention can increasing height or length is to the heat radiation conduction efficiency from the body circulation of restriction; Existing air-cooling type radiator does not then have this effect, will further increase area of dissipation as the present invention, as long as increase length, just can the effective area of dissipation of very efficient increase, and then can't reach this effect but have air-cooling type radiator now.
6. by thermally equilibrated time comparison, flexible radiating conduit 100 of the present invention can reach heat balance fast than existing air-cooling type radiator.
The above, it only is preferred embodiment of the present invention, be not that the present invention is done any pro forma restriction, every foundation technical spirit of the present invention all still belongs in the scope of technical solution of the present invention any simple modification, equivalent variations and modification that above embodiment did.
Claims (26)
1. a flexible radiating conduit is characterized in that, comprising:
One outer tube is a pliability pipe, at least one room of inner formation;
One heat-conducting piece is linked to room one end of outer tube, and the surface of heat-conducting piece absorbs to heat-conducting piece with the thermal source with electronic load at least one electronic load combination;
One heat sink is linked to the other end of the room of outer tube;
At least one soaking ring, for imbibition material constitutes, this soaking ring is incorporated into the heat-conducting piece inner edge, forms at least one perforation in this soaking ring;
At least one imbibition conduit and at least one interior pipe, this imbibition conduit is that imbibition material constitutes, pipe is coated on the outside of imbibition conduit in being somebody's turn to do, allow part, imbibition conduit two ends expose, the corresponding perforation of inserting the soaking ring of this imbibition conduit one end links with the heat-conducting piece inner edge again, this imbibition conduit other end links the inner edge of heat sink, make this imbibition conduit be linked to the soaking ring, in the room space between heat-conducting piece and heat sink, at least separated between pipe and outer tube in being somebody's turn to do and formed at least one circulating line, at least fill a kind of fluid heat-conducting medium in this circulating line, after seeing through the heat-conducting piece absorption at thermal source, heat the middle fluid heat-conducting medium of heat-conducting piece and soaking ring again, make the fluid heat-conducting medium produce liquid, gas two phase change, relend by capillarity and conduct to the cooling of heat sink radiating and cooling, be circulated back in the soaking ring of heat-conducting piece end via circulating line by heat sink again along the imbibition conduit.
2. flexible radiating conduit according to claim 1 is characterized in that, is respectively equipped with some sealed threads in the room two ends of described outer tube.
3. flexible radiating conduit according to claim 1 is characterized in that, described outer tube is a heat carrier.
4. flexible radiating conduit according to claim 1 is characterized in that, described heat-conducting piece is that Heat Conduction Material constitutes.
5. flexible radiating conduit according to claim 1 is characterized in that, described heat-conducting piece inner edge forms a junction surface.
6. flexible radiating conduit according to claim 5 is characterized in that, described junction surface outer rim is provided with some threads.
7. flexible radiating conduit according to claim 5 is characterized in that, described junction surface inner edge is provided with at least one jack.
8. flexible radiating conduit according to claim 1 is characterized in that, the electronic load that described heat-conducting piece surface is linked is a led lamp.
9. flexible radiating conduit according to claim 1 is characterized in that, the electronic load that described heat-conducting piece surface is linked is a chipset.
10. flexible radiating conduit according to claim 1 is characterized in that, described heat sink is that Heat Conduction Material constitutes.
11. flexible radiating conduit according to claim 1 is characterized in that, described heat sink inner edge forms a junction surface.
12. flexible radiating conduit according to claim 11 is characterized in that, described junction surface outer rim is provided with some threads.
13. flexible radiating conduit according to claim 11 is characterized in that, described junction surface inner edge is provided with at least one jack.
14. flexible radiating conduit according to claim 1 is characterized in that, described heat sink inner peripheral surface is in conjunction with a soaking ring.
15. flexible radiating conduit according to claim 14 is characterized in that, described soaking ring is an adhesive-bonded fabric.
16. flexible radiating conduit according to claim 14 is characterized in that, described soaking ring is a sponge.
17. flexible radiating conduit according to claim 1 is characterized in that, described heat sink surface combination one radiating fin group.
18. flexible radiating conduit according to claim 1 is characterized in that, described soaking ring is an adhesive-bonded fabric.
19. flexible radiating conduit according to claim 1 is characterized in that, described soaking ring is a sponge.
20. flexible radiating conduit according to claim 1 is characterized in that, described imbibition conduit is an adhesive-bonded fabric.
21. flexible radiating conduit according to claim 1 is characterized in that, described imbibition conduit is a sponge.
22. flexible radiating conduit according to claim 1 is characterized in that, separating the fluid heat-conducting medium of being filled in the circulating line of formation between described interior pipe and outer tube is cooling fluid.
23. flexible radiating conduit according to claim 1 is characterized in that, the interior filling of circulating line that separates formation between described interior pipe and outer tube is to manage at least one imbibition.
24. flexible radiating conduit according to claim 23 is characterized in that, pipe is imbibition material in the described imbibition.
25. flexible radiating conduit according to claim 23 is characterized in that, pipe is adhesive-bonded fabric in the described imbibition.
26. flexible radiating conduit according to claim 23 is characterized in that, pipe is sponge in the described imbibition.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2010102053202A CN102300440A (en) | 2010-06-22 | 2010-06-22 | Flexible radiating guide tube |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2010102053202A CN102300440A (en) | 2010-06-22 | 2010-06-22 | Flexible radiating guide tube |
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| CN102300440A true CN102300440A (en) | 2011-12-28 |
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| CN2010102053202A Pending CN102300440A (en) | 2010-06-22 | 2010-06-22 | Flexible radiating guide tube |
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104952818A (en) * | 2015-05-25 | 2015-09-30 | 联想(北京)有限公司 | Heat conducting device and electronic equipment |
| CN105611809A (en) * | 2016-03-07 | 2016-05-25 | 苏州硅果电子有限公司 | Filtering detection pipeline type liquid radiating device |
| CN105611808A (en) * | 2016-03-07 | 2016-05-25 | 苏州硅果电子有限公司 | Intelligent drive speed regulation-type automatic pipe liquid cooling device |
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| CN104952818B (en) * | 2015-05-25 | 2018-12-14 | 联想(北京)有限公司 | A kind of heat-transfer device and electronic equipment |
| CN105611809A (en) * | 2016-03-07 | 2016-05-25 | 苏州硅果电子有限公司 | Filtering detection pipeline type liquid radiating device |
| CN105611808A (en) * | 2016-03-07 | 2016-05-25 | 苏州硅果电子有限公司 | Intelligent drive speed regulation-type automatic pipe liquid cooling device |
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| CN105636414B (en) * | 2016-03-07 | 2018-04-13 | 苏州硅果电子有限公司 | A kind of intelligent automation tubing type liquid radiator |
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| CN106200845A (en) * | 2016-08-31 | 2016-12-07 | 张鋆 | A kind of desktop cpu chiller |
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Application publication date: 20111228 |