CN203216064U - Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device - Google Patents

Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device Download PDF

Info

Publication number
CN203216064U
CN203216064U CN2013202392785U CN201320239278U CN203216064U CN 203216064 U CN203216064 U CN 203216064U CN 2013202392785 U CN2013202392785 U CN 2013202392785U CN 201320239278 U CN201320239278 U CN 201320239278U CN 203216064 U CN203216064 U CN 203216064U
Authority
CN
China
Prior art keywords
heat pipe
sparse core
pipe
heat
core net
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
CN2013202392785U
Other languages
Chinese (zh)
Inventor
周雪君
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to CN2013202392785U priority Critical patent/CN203216064U/en
Application granted granted Critical
Publication of CN203216064U publication Critical patent/CN203216064U/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Images

Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/40Solar thermal energy, e.g. solar towers
    • Y02E10/44Heat exchange systems

Landscapes

  • Sorption Type Refrigeration Machines (AREA)

Abstract

The utility model relates to a sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device. The sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device comprises a sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection element and a heat insulation water tank; the heat insulation water tank or a union box is in heat transfer connection with the sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection element; the sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection element comprises a cover glass pipe and an inner glass pipe, and the cover glass pipe and the inner glass pipe are concentrically nested, arranged, sealed and connected; the inner glass pipe extends forward from the sealed and connected part of the inner glass pipe, and the inner glass pipe is sealed off for producing a heat pipe after the interior of the inner glass pipe is vacuum-pumped and filled with a working fluid; an absorption film is produced on the surface of the inner glass pipe; the sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device is characterized in that a sparse core network constituted by a plurality of thin strip capillary wicks with the width of 2-10mm is contained in the heat end of the heat pipe. The sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device disclosed by the utility model can accelerate the start of the heat pipe to the greatest extent, and also keep the internal pressure of the glass heat pipe at low level during air drying.

Description

A sparse core net working medium high position is gathered all-glass vacuum heat collector tube device
Technical field
The utility model relates to a sparse core net working medium high position and gathers all-glass vacuum heat collector tube device.
Background technology
Vacuum heat collection element arranges a vacuum heat-insulating layer between its cover glass tube and inner glass tube, can make the vacuum solar water heater that also can provide the domestic hot-water winter.With the solar water heater of heat-pipe vacuum heat collecting pipe manufacturing have more anhydrous Energy Efficiency Ratio height in the pipe, meet the safe drinking water standard, single tube damages advantage such as in the same old way work.Therefore.Anhydrous solar energy evacuated heat pipe water heater might capture the increasing market share in the pipe.
Existing a kind of workload fills all-glass heat pipe vacuum collector tube solar water heater seldom, and the heat pipe inwall adopts light-pipe structure, heat-pipe vacuum heat collecting pipe about 45 degree that tilt to install.Under non-heat exchange state, can observe the heat pipe bottom has liquid refrigerant to gather.
To its carry out and pipe in the all-glass vacuum thermal-collecting tube solar water heater check experiment of water, slow back is fast earlier to find the intensification situation of heat pipe solar energy water heater.Judgement is that the heat pipe start-up course is long, the startup stage of heat pipe, the heat collector tube element can not full power operation thereby heat up slow, the operation of heat collector tube element full power thereby quick heating after heat pipe starts.
The heat pipe of investigating all-glass heat pipe vacuum collector tube starts: because the working medium that is collected in the heat pipe bottom makes these liquid refrigerants can not participate in the two phase flow heat transfer circulation rapidly usually because its temperature of minute surface shading that is formed by getter rises slowly.Simultaneously, though because the temperature at inner other positions, heat pipe hot junction is high is in dry state and can not contributes to thermal-arrest in a very long time.Rely on the glass heat pipe tube wall heat transfer near the bottom to make liquid refrigerant vaporization and circulation participate in two phase flow heat transfer gradually later on, heat pipe is finished start-up course and is entered normal operating conditions.Problem is in the winter time, and the start-up course of heat pipe may continue more than two hours, and this makes that the performance of some glass heat pipe thermal-collecting tube can not be obviously good than the all-glass vacuum thermal-collecting tube of managing interior water, and the advantage of heat pipe fails to give full play to.
Glass surface is not suitable for processing stria to form bigger capillary lift.
Employing arranges to have enough large-area core nets at the glass heat pipe inner surface, though can utilize capillarity to solve the long problem of heat pipe start-up course, but can make the bigger increase of cost, more seriously also can fill more, the too high increase greatly that has a big risk that causes the bombing accident of vapour pressure when making empty solarization of working medium because of inside.When 0.2% when for example working medium filling weight/heat pipe plot ratio is from 2 milliliters/1000 milliliters are brought up to 5 milliliters/1000 milliliters 0.5%, the highest saturated vapor pressure increases to about 10 atmospheric pressure of 180 ℃ from about 3.7 atmospheric pressure of 140 ℃, but inside heat pipe when continuing to be warming up to 180 ℃ from 140 ℃ of about 3.7 atmospheric high-vapor-pressures internal pressure only have about 4 atmospheric pressure.Because the glass voltage endurance capability is limited, so the liquid refrigerant position height in the time of should managing to raise heat pipe and start is accelerated to start, the least possiblely when heat pipe work again hold back liquid refrigerant with minimizing working medium filling weight.
China's utility model patent 200410012193.9 Explosion-proof all-glass solar energy vacuum collecting tubes have disclosed a kind of Explosion-proof all-glass solar energy vacuum collecting tube, and the liquid refrigerant filling weight is 0.1~0.5%V in its heat pipe, and wherein V is the volume in the heat pipe.All be converted into vapour phase when making it reach a certain critical-temperature, when temperature continued to raise, pressure raise according to the rule of vapour phase, thereby had significantly reduced the operating pressure in the heat pipe under the condition of high temperature ...Simultaneously, in heat pipe, set up sorbing material, to guarantee that heat pipe quick starts again.But this utility model patent comprises that in heat pipe sorbing material sticking working medium that heat pipe evaporator section middle part arranges adds quick heating pipe and starts this mode and still can bring when increasing working medium filling weight and empty the solarization internal pressure or start still slower problem.Suppose: set originally and be limited to 4 atmospheric pressure on 44 millimeters of inner glass tube internal diameters, 58 millimeters of cover glass tube external diameters, long 2 meters the internal pressure of all-glass vacuum heat collector tube pipe, emptyly shine 230 ℃ of maximum temperatures, water is made working medium, calculating can get about 3 liters of inner glass tube volume.Look into the saturated vapor pressure table of water vapour as can be known: whole working medium filling weight of working medium vaporization just in the time of 135 ℃, its saturated vapor pressure is 3.2 atmospheric pressure and when shining 230 ℃ of temperature in high-altitude, internal pressure reaches 4 atmospheric pressure and namely equals the inner glass tube internal pressure limit.And the quality volumetric ratio of steam is 1.7 milliliters/liter can check in 135 ℃ the time.The working medium filling weight of this thermal-collecting tube is 1.7 milliliters/liter=5.1 milliliters of 3 liters of *.(5.1 milliliters of working medium are on the low side for existing thermal-collecting tube, can occur drying up in the bottom, hot junction, but this problem do not done expansion here).At this moment, quick heating pipe starts and imbibition material is set in the middle part of inside heat pipe in order to add.Suppose that the imbibition material that increases carries sticking 1.5 milliliters of working medium have altogether been arranged when the heat pipe operate as normal, and therefore aggravate inside heat pipe hot junction dry-out, dry hot junction does not participate in heat exchange has a greatly reduced quality the efficient of thermal-collecting tube.For fear of the heat-collecting capacity loss that brings because the hot junction is dry.Must increase the working medium filling weight remedies heat pipe when work and is put forward that part of working medium that sticking has by imbibition material.Suppose that the working medium filling weight that increases also is 1.5 milliliters, the quality volumetric ratio of the steam when then working medium is just all vaporized from 1.7 milliliters/go up and rise to 2.2 milliliters/liter, the critical-temperature of the highest saturated vapor pressure correspondence at this moment rises to 145 ℃ from 135 ℃; Correspondingly, when shining 230 ℃ of temperature in high-altitude, inside heat pipe pressure is increased to 5 atmospheric pressure from 4 atmospheric pressure.Conclusion is: increase imbibition material and increase the working medium filling weight in order to accelerate to be enabled in middle part, heat pipe hot junction, shine under the temperature in high-altitude, the thermal-collecting tube pressure inside can surpass original pressure of setting and increase to 5 atmospheric pressure from 4 atmospheric pressure and exceed 25%; Be equivalent to reduce winter a day heat-collecting capacity 35% and will prolong two hours without imbibition material heat pipe start-up course.Also have, only 1.5 milliliters of working medium of sticking are still not enough for sorbing material.
Summary of the invention
The purpose of this utility model is to provide a sparse core net working medium high position to gather all-glass vacuum heat collector tube device.
The technical scheme in the invention for solving the technical problem: make a sparse core net working medium high position and gather all-glass vacuum heat collector tube device, comprise that a sparse core net working medium high position gathers all-glass vacuum heat collector tube element, adiabatic water tank or connection collection box, tail box, support and auxiliary.Adiabatic water tank or connection collection box gather the heat transfer of all-glass vacuum heat collector tube element with a sparse core net working medium high position and are connected.A sparse core net working medium high position is gathered all-glass vacuum heat collector tube element and is comprised cover glass tube and inner glass tube.Cover glass tube and inner glass tube nested, concentric are arranged sealing-in, inner glass tube from sealing-in place stretch out forward and inside vacuumize can working medium after sealed-off make a heat pipe.The outer surface of inner glass tube is made absorbing film.A sparse core net of being made up of the slice capillary wick of 2 to 10 millimeters of some width is set in inside, heat pipe hot junction, and sparse core net adopts elastic circlip to overlay in heat pipe hot junction inwall; The area of sparse core net is less than 5% of described heat pipe hot junction inner wall area.
Can also make described sparse core net be formed by several annular fillet capillary wick according to circumferential layout.
Can also make 40 ± 5 ℃ of the water temperatures in 700 ± 50 watts/square metre of sunshine exposures, the heat pipe cold junction outside, described heat collecting element axial line be that the north-south is in tilted layout and the angle of its axial line and incident sunlight in 90 ± 20 ° of scopes under the condition: sparse core net hold liquid refrigerant quality≤its maximum liquid refrigerant volume of holding 25%.
Can also make: the maximum liquid refrigerant volume of holding of sparse core net 〉=4 milliliters; 40 ± 5 ℃ of the water temperatures in 700 ± 50 watts/square metre of sunshine exposures, the heat pipe cold junction outside, described heat collecting element axial line be that the north-south is in tilted layout and the angle of its axial line and incident sunlight in 90 ± 20 ° of scopes under the condition, sparse core net is held quality≤0.9 milliliter of liquid refrigerant.
The beneficial effects of the utility model: the sparse core net of a utility model working medium high position is gathered all-glass vacuum heat collector tube device, when the sun sets, the reverse work of glass heat pipe: the evaporation of the liquid refrigerant of the former heat pipe cold junction inner surface that is connected with the heating load low thermal resistance is also condensed at former heat pipe hot junction inner surface, when former heat pipe hot junction inner surface liquid refrigerant gathers more and held by it during the sparse core net of downward trickling arrival.When the sun came out in second day, in a single day the heat pipe hot junction was heated, and the liquid refrigerant that is held by sparse core net evaporates rapidly and the participation two phase flow heat transfer.Sparse core net distributes wide, and the solar energy heat absorbing area that relates to is also wide thereby start rapidly; Sparse core net distributes sparse, and during the heat pipe operate as normal, for example less than 0.3 milliliter, the increase of internal pressure was very limited when it shone sky less for the liquid refrigerant that sparse core net is held.The sparse core net of a utility model working medium high position is gathered all-glass vacuum heat collector tube element, and its heat pipe start-up time foreshortened to more than 20 minute from more than 140 minute of original light pipe, is equivalent to many thermal-arrests more than hour every day in winter.Thereby both having accelerated heat pipe to greatest extent starts; The glass heat pipe pressure inside keeps low level when making empty the solarization again.
Description of drawings
Below in conjunction with drawings and Examples the utility model is further specified.
Fig. 1 is that a sparse core net working medium high position is gathered all-glass vacuum heat collector tube apparatus structure schematic diagram.
1. cover glass tubes among the figure; 2. inner glass tube; 3. heat pipe; 4. annular fillet capillary wick; 5. elastic circlip; 6. adiabatic water tank; 7. tail box.
The specific embodiment
Fig. 1 provides embodiment of the utility model.
Among Fig. 1, gather all-glass vacuum heat collector tube element, adiabatic water tank 6 and sparse core net working medium high position of tail box 7 compositions with a sparse core net working medium high position and gather all-glass vacuum heat collector tube device.Adiabatic water tank 6 gathers the heat transfer of all-glass vacuum heat collector tube element with a sparse core net working medium high position and is connected.Sparse core net accelerates the heat collecting element of integrated glass heat pipe startup and is made by cover glass tube 1 and the sealing-in of inner glass tube 2 nested, concentric layout.Inner glass tube 2 from sealing-in place stretch out forward and inside vacuumize can working medium after sealed-off make a heat pipe 3.The outer surface of inner glass tube 2 is made absorbing film.Described sparse core net accelerates the vertical or installation of tilting of heat collecting element that the integrated glass heat pipe starts.Heat pipe 3 relies on gravity work.In inside, heat pipe 3 hot junction 10 annular fillet capillary wick 4 according to circumferential layout are set and form a sparse core net.Annular fillet capillary wick 4 usefulness elastic circlips 5 overlay in heat pipe 3 hot junction inwalls.1 meter 8 of the hot junction length of heat pipe 3; 5 millimeters of the width of annular fillet capillary wick 4.The area sum of annular fillet capillary wick 4 is less than 2.8% of described heat pipe 3 hot junction inner wall areas.Side by side outside arrow is represented the cold junction position of heat pipe 3 among Fig. 1.
When the heat collecting element of Fig. 1 embodiment turns clockwise about 45 degree when tilting to install, heat pipe 3 can rely on gravity to realize the two phase flow cycle heat exchange, and solar thermal energy is passed to heating load by cold junction continuously.During heat pipe 3 work, because annular fillet capillary wick 4 can not held working medium, so the working medium filling weight does not increase, heat pipe 3 inner saturated vapor pressures are in low-level when being conducive to limit empty the solarization.
When the heat collecting element of Fig. 1 embodiment turns clockwise about 45 degree when tilting to install, annular fillet capillary wick 4 can be when heat pipe 3 not be worked a large amount of sticking liquid refrigerants, improve the position that former light pipe heat pipe is collected in the working medium of heat pipe 3 bottoms.Annular fillet capillary wick 4 absorbed solar thermal energy as much as possible and accelerates to start when the annular fillet capillary wick 4 that is distributed in whole heat pipe 3 hot junctions was conducive to heat pipe 3 and starts.
Among Fig. 1 embodiment, so allow during heat pipe 3 operate as normal the dry or dry annular fillet capillary wick 4 of part of annular fillet capillary wick 4 when heat pipe 3 work, usually not hold working medium.When the sun set, the evaporation of the condensate water of heat pipe 3 cold junction inner surfaces comprised that the whole or most working medium of all working medium of this part working medium are by annular fillet capillary wick 4 stickings.
4 pairs of annular fillet capillary wick among Fig. 1 embodiment according to the time thermal-collecting tube the state no requirement (NR), convenient on-the-spot installation and maintenance operation.

Claims (4)

1. a sparse core net working medium high position is gathered all-glass vacuum heat collector tube device, comprises that a sparse core net working medium high position gathers all-glass vacuum heat collector tube element, adiabatic water tank or connection collection box, tail box, support and auxiliary; Adiabatic water tank or connection collection box gather the heat transfer of all-glass vacuum heat collector tube element with a sparse core net working medium high position and are connected; A sparse core net working medium high position is gathered all-glass vacuum heat collector tube element and is comprised cover glass tube and inner glass tube, cover glass tube and inner glass tube nested, concentric are arranged sealing-in, inner glass tube from sealing-in place stretch out forward and inside vacuumize can working medium after sealed-off make a heat pipe, the outer surface of inner glass tube is made absorbing film, it is characterized in that containing a sparse core net of being made up of the slice capillary wick of 2 to 10 millimeters of some width in inside, heat pipe hot junction, sparse core net adopts elastic circlip to overlay in heat pipe hot junction inwall; The area of sparse core net is less than 5% of described heat pipe hot junction inner wall area.
2. according to the described heat collector of claim 1, it is characterized in that described sparse core net is formed by several annular fillet capillary wick according to circumferential layout.
3. according to the described heat collector of claim 1, it is characterized in that 700 ± 50 watts/square metre of sunshine exposures, 40 ± 5 ℃ of the water temperatures in the heat pipe cold junction outside, described heat collecting element axial line be that the north-south is in tilted layout and the angle of its axial line and incident sunlight in 90 ± 20 ° of scopes under the condition: sparse core net hold liquid refrigerant quality≤its maximum liquid refrigerant volume of holding 25%.
4. according to claim 1 or 2 described heat collectors, it is characterized in that: the maximum liquid refrigerant volume of holding of sparse core net 〉=4 milliliters; 40 ± 5 ℃ of the water temperatures in 700 ± 50 watts/square metre of sunshine exposures, the heat pipe cold junction outside, described heat collecting element axial line be that the north-south is in tilted layout and the angle of its axial line and incident sunlight in 90 ± 20 ° of scopes under the condition, sparse core net is held quality≤0.9 milliliter of liquid refrigerant.
CN2013202392785U 2013-05-04 2013-05-04 Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device Expired - Fee Related CN203216064U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2013202392785U CN203216064U (en) 2013-05-04 2013-05-04 Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2013202392785U CN203216064U (en) 2013-05-04 2013-05-04 Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device

Publications (1)

Publication Number Publication Date
CN203216064U true CN203216064U (en) 2013-09-25

Family

ID=49205591

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2013202392785U Expired - Fee Related CN203216064U (en) 2013-05-04 2013-05-04 Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device

Country Status (1)

Country Link
CN (1) CN203216064U (en)

Similar Documents

Publication Publication Date Title
CN203216025U (en) Thin strip capillary wick working fluid high-level accumulation all-glass vacuum heat pipe heat collection device
CN203190690U (en) All-glass vacuum heat pipe heat collection element with strip imbibing core lifting working media
CN203240792U (en) Thin-strip capillary liquid-suction core working medium high concentration eccentric direct heating pipe vacuum heat-collection device
CN203216064U (en) Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection device
CN203240811U (en) Heat collection element for accelerating start of glass heat tube through sparse core net
CN203216063U (en) Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe water heater
CN203216024U (en) Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection module
CN203216068U (en) Sparse core network working fluid high-level accumulation fin-plate heat pipe vacuum heat collection device
CN203216059U (en) Sparse core network working fluid high-level accumulation fin-plate heat pipe vacuum water heater
CN203216027U (en) Sparse core network working fluid high-level accumulation fin-plate heat pipe vacuum heat collection module
CN203216128U (en) Sparse core network working fluid high-level accumulation all-glass vacuum heat pipe heat collection element
CN203216131U (en) Sparse core network working fluid high-level accumulation fin-plate heat pipe vacuum heat collection element
CN203190664U (en) Glass heat pipe vacuum solar heat collection element with short-barrel wick arranged at lower position
CN203240774U (en) Solar heat collection device with short liquid suction core arranged at lower portion of glass heat pipe of heat collection element
CN203216022U (en) Thin strip capillary wick working fluid high-level accumulation fin-plate heat pipe vacuum heat collection device
CN203216058U (en) Thin strip capillary wick working fluid high-level accumulation fin-plate heat pipe vacuum water heater
CN203190667U (en) Solar heat collection device with work medium gathering in higher position of glass heat pipe
CN203216071U (en) Thin strip capillary wick working fluid high-level accumulation all-glass vacuum heat pipe heat collection module
CN203216023U (en) Short wick working fluid high-level accumulation fin-plate heat pipe vacuum water heater
CN203216069U (en) Short wick working fluid high-level accumulation fin-plate heat pipe vacuum heat collection device
CN203216061U (en) Short wick working fluid high-level accumulation fin-plate heat pipe vacuum heat collection module
CN203216133U (en) Thin strip capillary wick working fluid high-level accumulation all-glass vacuum heat pipe water heater
CN203216129U (en) Thin strip capillary wick working fluid high-level accumulation all-glass vacuum heat pipe heat collection element
CN203216070U (en) Short wick working fluid high-level accumulation fin-plate heat pipe vacuum heat collection element
CN203240812U (en) Solar heat collection device with liquid storage groove-shaped object arranged inside glass heat tube of heat collection element

Legal Events

Date Code Title Description
C14 Grant of patent or utility model
GR01 Patent grant
C17 Cessation of patent right
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20130925

Termination date: 20140504