CN202134530U - Minisize LHP heat dissipation system of integrated EHD pump - Google Patents

Minisize LHP heat dissipation system of integrated EHD pump Download PDF

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Publication number
CN202134530U
CN202134530U CN201120058533U CN201120058533U CN202134530U CN 202134530 U CN202134530 U CN 202134530U CN 201120058533 U CN201120058533 U CN 201120058533U CN 201120058533 U CN201120058533 U CN 201120058533U CN 202134530 U CN202134530 U CN 202134530U
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CN
China
Prior art keywords
ehd
evaporator
condenser
lhp
miniature
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Expired - Lifetime
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CN201120058533U
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Chinese (zh)
Inventor
万珍平
徐燕小
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South China University of Technology SCUT
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South China University of Technology SCUT
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28DHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
    • F28D15/00Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies
    • F28D15/02Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes
    • F28D15/04Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure
    • F28D15/043Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure forming loops, e.g. capillary pumped loops
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2924/00Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
    • H01L2924/0001Technical content checked by a classifier
    • H01L2924/0002Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00

Abstract

The utility model discloses a minisize LHP (Loop Heat Pipe) heat dissipation system of an integrated EHD (Electrohydrodynamic) pump, including an EHD evaporator and an EHD condenser which are in connection through a steam pipe and a liquid pipe; the EHD evaporator is successively provided with a cover plate with a liquid pipe interface, a capillary core, a high voltage pole and an insulation separator plate, wherein the high voltage pole and the insulation separator plate are mutually applied and placed on an evaporation surface in the evaporator; the capillary core is applied on an inner surface of the cover plate. The EHD condenser is successively provided with a cover plate with a liquid pipe interface, an insulation separator plate with a hole, a high voltage pole and heat dissipation fins, wherein the insulation separator plate and the high voltage pole are mutually applied and arranged on an inner surface of the cover plate. One ends of the heat dissipation fins are placed in the condenser, and the other ends traverse the condenser to be placed outside. The heat dissipation system can perform instant and fully cooling to electronic components with high hot-fluid density, so as to meet the heat dissipation requirements of high performance minisize electronic components.

Description

A kind of miniature LHP cooling system of integrated current body kinetic pump
Technical field
The utility model relates to the miniature LHP system of microelectronic device heat radiation, particularly a kind of miniature LHP cooling system of integrated current body kinetic pump.
Background technology
The progress with micro-electronic mechanical skill that develops rapidly along with various electronic devices and equipment high frequency, high speed and integrated circuit technique; Like computer chip etc. to high-performance, miniaturization and microminiaturized trend development; Make the caloric value and the density of heat flow rate of unit volume electronic device increase fast; The layout of heat abstractor and designed constraints are also more and more, how to realize that in limited space the heat radiation of high heat flux becomes the focus of space thermal control technical problem.With the computer CPU is example, and the density of heat flow rate that produces in its running has reached 60-100W/cm 2, in the semiconductor laser even reach 10 3W/cm 2The order of magnitude." on the other hand, the reliability of electronic device work is very responsive to temperature, device temperature 1 ℃ of every increase on 70-80 ℃ of level, reliability will descend 5%, and higher temperature levels becomes restriction electronic device bottleneck of performance day by day.The commonly used heat radiation or the type of cooling mainly contain: natural heat dissipation or cooling, forced heat radiation or cooling, liquid cools, refrigeration modes, dredge mode, hot isolation method etc.The radiating mode of having studied has not at present obviously caught up with the development trend of electronic device and equipment microminaturization, and particularly current MEMS Processing Technology Development is very swift and violent, and it is imperative developing the new heat radiation or the type of cooling.
LHP is a kind of radiator that relies on the Working fluid phase changing principle work, has been widely used in space flight thermal control field at present, on high heat flux heat dissipation problems such as solution electronic installation, also has bright prospects.The LHP systematic research mainly is based on its application at space industry both at home and abroad, does not generally consider the influence of gravity, and the LHP system applies all receives gravity effect during electronic installation in common ground system.Simultaneously, no matter be the LHP system of which kind of form, it starts and stable operating performance depends on all whether the LHP system configuration can effectively guarantee the smooth discharge of in time replenishing of liquid refrigerant and gaseous working medium, and promptly can the working medium in the LHP system directed stable circulation.
Electrohydrodynamic pump (Electrohydrodynamic; EHD) augmentation of heat transfer is with electric field and theoretical a kind of method of introducing the thermal conduction study field thereof; It is in fluid, to apply an external electric field, utilizes the interaction in electric field, flow field and temperature field and reaches the purpose of augmentation of heat transfer.In numerous active enhanced heat exchange technology, the EHD technology is a kind of new and very promising heat dissipation technology.EHD is applied to can promote in evaporator and the condenser of miniature LHP reason to be three benefits of high voltage electric field with enhanced heat exchange: the one, the electric convection effect of convection cell; The 2nd, to the exercise effect of steam bubble behavior; The 3rd, the pumping effect of convection cell.Through the position of reasonable Arrangement high-field electrode in evaporator and condenser; Can control the flow direction of working medium in miniature LHP system; Simultaneously can also produce the pumping effect to working medium; Make that working medium not only can directed stable circulation in miniature LHP, can also normally operation under the situation of antigravity, thus improve the radiating efficiency of miniature LHP.This system not only can realize working medium directed stable circulation in miniature LHP, satisfies microminiaturized easy structure again, makes the development space that having of small electronic equipment is bigger.
Although the structure of present stage LHP is varied, realize that the directed stable circulation of working medium is the scabrous problem that the researcher faces always among the LHP.
Summary of the invention
What the utility model mainly solved is; Can not directed stable circulation to the working medium that exists among the current LHP; The heat dissipation problem that is difficult to realize high heat flux in limited space; Proposed a kind of miniature LHP cooling system of integrated current body kinetic pump, realized the stable orientation circulation of working medium, an effective solution route is provided for solving the high heat flux problem.
The utility model is realized through following technical proposals:
A kind of miniature LHP cooling system of integrated current body kinetic pump comprises EHD evaporator, EHD condenser, is connected with fluid pipeline through jet chimney between said EHD evaporator and the EHD condenser;
Said EHD evaporator is provided with cover plate, capillary wick, high-field electrode, the insulating barrier of carrying liqs pipe joint successively; Said high-field electrode, insulating barrier are fitted each other and are placed the evaporating surface in the evaporator; Said capillary wick fits in the inner face of cover plate, and said capillary wick adopts the porous metals sintered plate;
Said EHD condenser is provided with the cover plate of carrying liqs pipe joint, insulating barrier, high-field electrode, radiating fin with holes successively; Said insulating barrier and high-field electrode are fitted each other and are arranged on the inner face of cover plate; One end of said radiating fin places condenser inner, and the other end passes condenser and places the outside;
One end of said jet chimney is through the sidewall and the EHD evaporator internal communication of EHD evaporator, and the other end is through the sidewall of EHD condenser and the internal communication of EHD condenser;
One end of said fluid pipeline is through the interface and the EHD evaporator internal communication of EHD evaporator cover plate, and the other end is through the interface and the EHD condenser internal communication of EHD condenser cover plate.
High-field electrode in said EHD evaporator and the EHD condenser can adopt any one in wire electrode, columnar electrode, mesh electrode or the spiral electrode;
Evaporating surface in the said EHD evaporator can be rough surface, and said radiating fin surface also can be rough surface;
Said radiating fin and EHD condenser junction are coated with silica gel layer.
The outer surface of said EHD evaporator is provided with heat block.
Said insulating barrier is a N type silicon chip.
Said radiating fin is any one shape in column, sheet or the needle-like.
The utility model working mechanism and process are following:
At first in whole system, charge into an amount of liquid working substance (for dielectric working medium), then this system is vacuumized, make liquid working substance be in vacuum state; Secondly, heat block is bonding with the intimate of evaporator through silica gel, make the evaporator that passes to that the heat of heat block can maximum.When the heat block temperature of starting working rises, there is temperature gradient between heat block and the evaporator, heat is conducted to evaporator by heat block, and evaporator interior liquid working medium begins vaporization boiling, LHP system start-up.High-field electrode all is housed as positive pole in the evaporator of native system and the condenser; Evaporator wall and condenser wall are as negative pole (ground connection); The electric field action that the inner liquid working substance of evaporator is produced by high-field electrode during normal the operation; Promote liquid working substance towards the direction fluid that electric field strength increases, promptly move towards the evaporating surface direction; Simultaneously, capillary wick makes liquid working substance get into vaporization chamber quickly to the capillary pump suction of liquid working substance, and steam overflows the enhanced water evaporation heat transfer in the accelerated evaporation device.Steam reaches condenser along jet chimney; Steam state working medium is condensed into liquid refrigerant and emits heat in condenser; Liquid refrigerant receives the electric field action that high-field electrode produces simultaneously; Flow and be back to the inner capillary wick of evaporator through fluid pipeline towards the fluid pipeline direction, the capillary pressure head that capillary wick is stable adds to the evaporator heating surface continuously with liquid refrigerant.So circulation realizes that heat energy is by the continuous transfer of heat block to condenser.
Beneficial effect compared with prior art of the present invention is:
(1), the described LHP cooling system of the utility model is furnished with high-field electrode in evaporator; Make the liquid working substance in the evaporator flow towards the direction that electric field strength increases; Promptly move towards the evaporating surface direction of EHD evaporator; Make that not only working medium can directed stable circulation in LHP, also improved overflowing and having strengthened the capillary pump suction of porous metals sintered plate in the evaporator of steam in the evaporator, thereby improved the heat transfer efficiency of evaporator.
(2), the described LHP cooling system of the utility model also is furnished with high-field electrode in condenser; Liquid working substance influent pipeline in the condenser is produced the pumping effect; Make working medium towards fluid pipeline direction motion and improved the back-flow velocity of liquid working substance, thereby strengthened the heat transfer of condenser.
(3), the utility model adopted the porous metals sintered plate as capillary wick in evaporator, improved the pump suction of capillary wick, thereby improved the heat transfer power of LHP.
(4), the utility model adopts the means of simple and easy to do technology, improved heat transfer efficiency greatly, obtained positive beneficial technical effects.
Description of drawings
Fig. 1 is the structural representation of the miniature LHP cooling system of the utility model integrated current body kinetic pump;
Fig. 2 is an EHD evaporator structural representation among Fig. 1;
Fig. 3 is an EHD condenser device structural representation among Fig. 1;
Fig. 4 is an EHD evaporator high-field electrode structural representation;
Fig. 5 is the high-field electrode structural representation in the EHD condenser.
Embodiment
Below in conjunction with specific embodiment the utility model is done further concrete detailed description the in detail, but the execution mode of the utility model is not limited thereto, the technological parameter for not indicating especially can carry out with reference to routine techniques.
Embodiment
As shown in Figure 1, the miniature LHP cooling system of the utility model integrated current body kinetic pump comprises EHD evaporator 2, EHD condenser 8, is connected with fluid pipeline 13 through jet chimney 7 between said EHD evaporator 2 and the EHD condenser 8; Said EHD evaporator 2 is provided with cover plate 6, capillary wick 5, high-field electrode 4, the insulating barrier 3 of carrying liqs pipe joint successively; Said high-field electrode 4, insulating barrier 3 is fitted each other and place evaporating surface 14 (see figure 2)s in the evaporator 2, and said capillary wick 5 fits in the inner face of cover plate 6; Said capillary wick 5 can adopt the porous metals sintered plate; Said cover plate 6 is sealed and matched with EHD evaporator 2; Said EHD condenser 8 is provided with the cover plate 12 of carrying liqs pipeline 13 interfaces, insulating barrier 11, high-field electrode 10, radiating fin 9 with holes successively; Said insulating barrier 11 is fitted each other with high-field electrode 10 and is arranged on the inner face of cover plate 12; One end of said radiating fin 9 places condenser 8 inside, and the other end passes condenser 8 and places the outside.Said cover plate 12 is sealed and matched with EHD condenser 8; Radiating fin 9 is coated with silica gel layer with EHD condenser 8 junctions.
Like Fig. 1, shown in 2.Specifically; Insulating barrier 3 is used for high-field electrode 4 and evaporating surface 14 are separated; High-field electrode 4 can be strengthened the evaporation heat transfer of EHD evaporator, and liquid working substance is had the pumping effect, can quicken liquid working substance to evaporating surface 14 motions; Improve the speed of overflowing of steam, capillary wick 5 can improve the back-flow velocity of liquid working substance; The radiating fin 9 and the high-field electrode 10 of the surface roughening of arranging in the EHD condenser 8; Separate with insulating barrier 11 between (condensation chamber) in its high-field electrode 10 and the EHD condenser 8; Radiating fin 9 can be strengthened the condensation rate of steam; High-field electrode has the pumping effect to liquid working substance, can improve the back-flow velocity of liquid working substance, improves the radiating efficiency of this cooling system.
As shown in Figure 1, an end of said jet chimney 7 is through the sidewall and EHD evaporator 2 internal communication of EHD evaporator 2, and the other end is through the sidewall of EHD condenser 8 and the internal communication of EHD condenser 8; One end of said fluid pipeline 13 is through the interface and EHD evaporator 2 internal communication of EHD evaporator 2 cover plates 6, and the other end is through the interface and EHD condenser 8 internal communication of EHD condenser 8 cover plates 12.
Evaporating surface 14 in the said EHD evaporator 2 is a rough surface, can adopt chemical corrosion or laser processing; Said radiating fin 9 surfaces are rough surface; The outer surface of said EHD evaporator 2 is provided with heat block.
As shown in Figure 2, specifically, external heat passes to evaporator 2 inside through the evaporating surface 14 in the evaporator 2.Insulating barrier 3 vertically is attached on the evaporating surface 14 abreast, is used for the insulation of high-field electrode 4 and vaporization chamber.On insulating barrier 3, arrange the positive pole of high-field electrode 4, negative pole is evaporator 2 walls (ground connection).High-field electrode 4 links to each other with high voltage source, makes and produces electric field action in the liquid working substance, and liquid working substance is produced the pumping effect, has quickened the pump suction that overflows and increased capillary wick 5 of steam in the evaporator 2, has strengthened the heat transfer of evaporator 2.On evaporator 2 cover plates 6 internal faces, be furnished with the porous metals sintered plate as capillary wick 5, capillary wick 5 is pressed in the evaporator 2 through cover plate 6.
As shown in Figure 3, specifically, the liquid working substance in the evaporator 2 is heated to vaporize and pass through jet chimney 7 and gets in the condensers 8, and condenser 8 internal heat dissipating fins 9 combine with outside radiating fin 9, the condensation of acceleration working substance steam.Condenser 8 outside radiating fins 9 adopt fan to quicken condensing of steam through the type of cooling of forced convertion.Insulating barrier 11 vertically is attached on the internal face of condenser 8 cover plates 12 abreast, on insulating barrier 11, is furnished with the positive pole of high-field electrode 10, and negative pole is condenser 8 walls (ground connection).High-field electrode 10 links to each other with high voltage source, makes and produces electric field action in the liquid working substance, and working medium is produced the pumping effect, improves the back-flow velocity of liquid working substance, has strengthened the heat transfer efficiency of condenser 8.
Fig. 4, Fig. 5 are respectively high-field electrode 4 and the structural representation of the high-field electrode 10 in the condenser 8 in the evaporator 2, and what the present invention selected for use is wire electrode.Yet the selection of its structure and form can have a variety of, like columnar electrode, rod-shaped electrode, spiral electrode etc.
The working mechanism and the process of the miniature LHP cooling system of the integrated current body kinetic pump of the utility model are following:
At first in whole system, charge into an amount of liquid working substance (for dielectric working medium), then this system is vacuumized, make liquid working substance be in vacuum state; Heat block 1 is bonding with the intimate of evaporator 2 through silica gel, and what make that the heat of heat block 1 can maximum passes to evaporator 2.When heat block 1 temperature of starting working rises, there is temperature gradient between heat block 1 and the evaporator 2, heat is given evaporator 2 by heat block 1 conduction, and evaporator 2 interior liquid working medium begin vaporization and seethe with excitement LHP system start-up.High- field electrode 4,10 all is housed as anodal in the evaporator 2 of native system and the condenser 8; Evaporator 2 walls and condenser 8 walls are as negative pole (ground connection); The electric field action that evaporator 2 inner liquid working substances are produced by high-field electrode 4 during normal the operation; Promote liquid working substance towards the direction fluid that electric field strength increases, promptly move towards evaporating surface 14 directions; Simultaneously, the capillary pump suction of 5 pairs of liquid working substances of capillary wick makes liquid working substance get into evaporator 2 inside quickly, and steam overflows the enhanced water evaporation heat transfer in the accelerated evaporation device 2.Steam reaches in the condenser 8 through insulating barrier with holes 11 along jet chimney 7; Steam state working medium is condensed into liquid refrigerant and emits heat in condenser 8; Liquid refrigerant receives the electric field action that high-field electrode produces simultaneously; Flow and be back to evaporator 2 inner capillary wick 5 through fluid pipeline 13 towards fluid pipeline 13 directions, capillary wick 5 stable capillary pressure heads add to evaporator 2 evaporating surfaces 14 continuously with liquid refrigerant.So circulation realizes that heat energy is by the continuous transfer of heat block 1 to condenser 8.
Just can realize the utility model preferably as stated.
The foregoing description is the utility model preferred implementation; But the execution mode of the utility model is not restricted to the described embodiments; Other any do not deviate from change, the modification done under spirit and the principle of the utility model, substitutes, combination, simplify; All should be the substitute mode of equivalence, be included within the protection range of the utility model.

Claims (10)

1. the miniature LHP cooling system of an integrated current body kinetic pump comprises EHD evaporator, EHD condenser, is connected with fluid pipeline through jet chimney between said EHD evaporator and the EHD condenser, it is characterized in that:
Said EHD evaporator is provided with cover plate, capillary wick, high-field electrode, the insulating barrier of carrying liqs pipe joint successively, and said high-field electrode, insulating barrier are fitted each other and placed the evaporating surface in the evaporator, and said capillary wick fits in the inner face of cover plate;
Said EHD condenser is provided with the cover plate of carrying liqs pipe joint, insulating barrier, high-field electrode, radiating fin with holes successively; Said insulating barrier and high-field electrode are fitted each other and are arranged on the inner face of cover plate; One end of said radiating fin places condenser inner, and the other end passes condenser and places the outside.
2. the miniature LHP cooling system of integrated current body kinetic pump according to claim 1 is characterized in that:
One end of said jet chimney is through the sidewall and the EHD evaporator internal communication of EHD evaporator, and the other end is through the sidewall of EHD condenser and the internal communication of EHD condenser;
One end of said fluid pipeline is through the interface and the EHD evaporator internal communication of EHD evaporator cover plate, and the other end is through the interface and the EHD condenser internal communication of EHD condenser cover plate.
3. the miniature LHP cooling system of integrated current body kinetic pump according to claim 1 and 2 is characterized in that: the high-field electrode in said EHD evaporator and the EHD condenser adopts any one in wire electrode, columnar electrode, mesh electrode or the spiral electrode.
4. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3 is characterized in that: said capillary wick adopts the porous metals sintered plate.
5. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3 is characterized in that: the evaporating surface in the said EHD evaporator is a rough surface.
6. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3 is characterized in that: radiating fin and EHD condenser junction are coated with silica gel layer.
7. the miniature LHP cooling system of integrated current body kinetic pump according to claim 6 is characterized in that: said radiating fin surface is rough surface.
8. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3, it is characterized in that: the outer surface of said EHD evaporator is provided with heat block.
9. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3 is characterized in that: said insulating barrier is a N type silicon chip.
10. the miniature LHP cooling system of integrated current body kinetic pump according to claim 3 is characterized in that: said radiating fin is any one shape in column, sheet or the needle-like.
CN201120058533U 2011-03-08 2011-03-08 Minisize LHP heat dissipation system of integrated EHD pump Expired - Lifetime CN202134530U (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102157470A (en) * 2011-03-08 2011-08-17 华南理工大学 Micro LHP radiating system for integrated electrofluid power pump
CN104350277A (en) * 2012-06-15 2015-02-11 西门子公司 Device and arrangement for generating flow of air
CN107660104A (en) * 2017-09-30 2018-02-02 广东合新材料研究院有限公司 A kind of cold liquid homogenizer of liquid and the liquid cooling heat radiator using the cold liquid homogenizer of the liquid

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102157470A (en) * 2011-03-08 2011-08-17 华南理工大学 Micro LHP radiating system for integrated electrofluid power pump
CN104350277A (en) * 2012-06-15 2015-02-11 西门子公司 Device and arrangement for generating flow of air
US10060422B2 (en) 2012-06-15 2018-08-28 Siemens Aktiengesellschaft Device and arrangement for generating a flow of air
CN107660104A (en) * 2017-09-30 2018-02-02 广东合新材料研究院有限公司 A kind of cold liquid homogenizer of liquid and the liquid cooling heat radiator using the cold liquid homogenizer of the liquid
CN107660104B (en) * 2017-09-30 2023-10-31 广东西江数据科技有限公司 Liquid cooling liquid homogenizing device and liquid cooling radiator using same

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Granted publication date: 20120201

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