CN105571363A - Coupling device for superconducting tubes - Google Patents
Coupling device for superconducting tubes Download PDFInfo
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- CN105571363A CN105571363A CN201610069732.5A CN201610069732A CN105571363A CN 105571363 A CN105571363 A CN 105571363A CN 201610069732 A CN201610069732 A CN 201610069732A CN 105571363 A CN105571363 A CN 105571363A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D15/00—Heat-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
- F28D15/02—Heat-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
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- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Containers, Films, And Cooling For Superconductive Devices (AREA)
Abstract
The invention belongs to the technical field of heat conducting equipment, and particularly relates to a coupling device for superconducting tubes. The technical problem that existing superconducting tubes cannot be coupled is solved. The coupling device comprises a box with a vacuum closed inner cavity, at least one heat source end inserting hole which allows the superconducting tubes to be inserted and is capable of enabling the superconducting tubes to extend into the box is formed in one end of the box, and at least one heat receiving end connecting-out inserting hole which allows the superconducting tubes to be inserted and is capable of enabling the superconducting tubes to extend into the box is formed in the other end of the box. A superconducting medium is arranged in the vacuum closed inner cavity of the box. When a temperature difference exists between the superconducting tubes inserted into the heat source end inserting holes and the superconducting tubes inserted into the heat receiving end connecting-out inserting holes, heat exchange can be carried out under the action of a heat transmission medium. The coupling device has the beneficial effects that efficient heat transfer and exchange between the superconducting tubes can be carried out, and the coupling device can be adopted as the coupling device between the superconducting tubes and is driven only by a heat source, so that energy saving and zero carbon emission are achieved; the coupling device can be driven to run as long as the temperature difference exists between the two ends of the coupling device, and the coupling device is very convenient and fast to use and efficient; and the coupling device has great prospects when used on the aspect of building air conditioning engineering.
Description
Technical field
The invention belongs to heat transfer equipment technical field, especially relate to a kind of superconducting pipe coupling device.
Background technology
In the middle of the extensive utilization of superconducting pipe technology, because superconducting pipe structure limit with length, must need to be coupled between superconduction tube and tube, make it point flow transmission of cold exchange heat and cold and hot amount, so that utilize superconducting pipe cleverly flexibly.And in traditional building HVAC field, the coupling of heat pipe, the transmission of cold and hot amount between heat pipe is by heat exchanger substantially, condensate correcting-distribuing device etc.Because the heat transfer medium in heat pipe is fluid substantially, so traditional heat-exchanger rig advantage has cold heat distribution controlled and evenly, the method for salary distribution is flexible and changeable.But be a novel technology due to superconducting pipe and construct the coupling that special, traditional heat-exchanger rig can not realize superconducting pipe.Because superconducting pipe is the super-contact mode transferring heat with light/sound/electromagnetic wave form, by cold and hot amounts of electromagnetic transmitting transmission such as infrared rays, if therefore use traditional heat exchange mode, the distribution of cold and hot amount has uncontrollability.
In order to solve prior art Problems existing, people have carried out long-term exploration, propose solution miscellaneous.Such as, Chinese patent literature discloses a kind of filler coupling coil pipe evaporative condenser [application number: 201210254738.1], comprises coil heat exchanger, blower fan, water pump and water-locator; Described coil heat exchanger is connected to form by inlet header and outlet header by multiple heat exchange section of jurisdiction, and described heat exchange section of jurisdiction comprises coil pipe and filler.Described coil pipe is provided with at least a slice and flows to the filler of lower floor's heat exchanger tube for guiding spraying cooling water from upper strata heat exchanger tube.Although such scheme to some extent solves the problem of heat exchanger coupling, the coupling for superconducting pipe does not still propose solution.
Summary of the invention
The object of the invention is for the problems referred to above, provide a kind of simple and reasonable, the superconducting pipe coupling device of the coupling between superconducting pipe can be carried out.
For achieving the above object, present invention employs following technical proposal: this superconducting pipe coupling device, comprise the casing with vacuum tightness inner chamber, it is characterized in that, described casing one end is provided with at least one and inserts for superconducting pipe and superconducting pipe can be made to extend to heat source side jack in casing, the other end is provided with at least one confession superconducting pipe insertion and the heat receiving terminal that superconducting pipe can be made to extend in casing picks out jack, superconductive medium is provided with in the vacuum tightness inner chamber of described casing, and heat exchange can be carried out under the effect of hot transmission medium when there is the temperature difference between the superconducting pipe that heat source side jack inserts and heat receiving terminal pick out superconducting pipe that jack inserts.Preferably, here vacuum tightness inner chamber is vacuum ionic space, when there is the temperature difference in the superconduction pipe end inserted respectively when coupling device both sides, the present invention is conducted heat by vacuum particle space-efficient, allow the heat exchange rapidly and uniformly of both sides superconducting pipe, be divided into according to the heat exchange mode of superconducting pipe in device: tubular type multi-to-multi coupling device, board-like one-to-many coupling device, wherein tubular type multi-to-multi coupling device, can be divided into again according to hollow box body shape: tubular type cylindrical shape multi-to-multi coupling device, the rectangular-shaped multi-to-multi coupling device of tubular type.
In above-mentioned superconducting pipe coupling device, described superconductive medium is suspended in vacuum tightness inner chamber and/or is deposited on cabinet wall, and described superconductive medium comprises any one or multiple combination in carbon, metallic element and inorganic elements.
In above-mentioned superconducting pipe coupling device, described metallic element comprises any one or multiple combination in strontium, sodium, titanium and cobalt, and described inorganic elements comprises EF-44 or CH-104.Preferably, here superconductive medium is not only suspended in vacuum tightness inner chamber, part can be deposited on luminal wall surface in vacuum tightness, during apparatus of the present invention work, there is the temperature difference and drive as thermal source in the superconducting pipe due to device two ends, superconductive medium produces chemical reaction, release energy, produce dynamical physical transformation thereupon, make metallic element molecule, along device inwall, the heat taking the photograph self-heat power is continuously delivered to the low one end of temperature, because the raw physical phenomenon of this material producing also can supervene fever phenomenon, further promotion efficient heat transfer reaction, and while generation heat, carbon molecule wherein can produce far-infrared radiation heat, owing to there is Working fluid flow in the middle of the structure of superconducting pipe, then certainly exist heat convection.Namely in this device, there is heat conduction, convection current, radiation three kinds of heat exchange mode superposition actings in conjunction, so can reach the effect of high efficient heat exchanging simultaneously.
In above-mentioned superconducting pipe coupling device, the superconducting pipe of described tank ends adopts pipe type heat transfer mode to carry out heat exchange, and the quantity that the quantity of superconducting pipe inserted of described heat source side jack and heat receiving terminal pick out the superconducting pipe that jack inserts is respectively several, and the projection of described heat source side jack on casing cross section and heat receiving terminal pick out the projection of jack on casing cross section shifts to install.
In above-mentioned superconducting pipe coupling device, described casing is rectangle, and described heat source side jack is a row along casing one end end face transverse direction or genesis analysis, it is two rows that described heat receiving terminal picks out jack along the vertical or horizontal distribution of casing other end end face, and the projection of described heat source side jack on casing cross section and heat receiving terminal pick out the projection of jack on casing cross section is that I shape distributes and arranges.Namely coupling device is here the rectangular-shaped multi-to-multi coupling device of tubular type, and preferably, the quantity of heat source side jack is here 6, and the quantity that heat receiving terminal picks out jack is 12 and is arranged in a row, and often arranges 6.
In above-mentioned superconducting pipe coupling device, described casing is cylindrical, and described heat source side jack is a row along casing one end end face transverse direction or genesis analysis, it is a row that described heat receiving terminal picks out jack along the vertical or horizontal distribution of casing other end end face, and the projection of described heat source side jack on casing cross section and heat receiving terminal pick out the projection of jack on casing cross section is that cross distribution is arranged.Namely coupling device is here cylindrical shape multi-to-multi coupling device, and preferably, the quantity of heat source side jack is here 6, and the quantity that heat receiving terminal picks out jack is 6 and is arranged in a row.
In above-mentioned superconducting pipe coupling device, the superconducting pipe of described tank ends adopts plate-type heat-exchange mode to carry out heat exchange, the quantity of the superconducting pipe that described heat source side jack inserts is one, and described heat receiving terminal picks out the quantity of the superconducting pipe that jack inserts for several.Namely coupling device is here board-like one-to-many coupling device, the feature of board-like one-to-many coupling device is that the cold and hot source of device only accesses a superconducting pipe as house steward, the device other end can be accessed by many superconducting pipes and carries out heat exchange as arm, makes cold and hot amount be diverted to arm from house steward and transmits.
In above-mentioned superconducting pipe coupling device, described casing is rectangle, there are in casing one end at least two heat source side jacks, and described superconducting pipe inserts in one of them heat source side jack and passes from remaining heat source side jack, described superconducting pipe is provided with the heat-conductive assembly being positioned at vacuum tightness inner chamber, and the superconducting pipe that described heat receiving terminal picks out jack insertion is arranged on the dividing plate one_to_one corresponding in vacuum tightness inner chamber with some respectively and adopts wall-type heat exchange mode to be connected.Demarcation strip 4 is there is in the middle of the vacuum tightness inner chamber of heat receiving terminal, material is the alloys such as carbon steel/metallic copper/stainless steel/aluminium/titanium/nickel, major part heat carries out partition heat conduction heat exchange by dividing plate and superconducting pipe, superconducting pipe can be made like this to receive heat more even, heat source side only need access a superconducting pipe as house steward, heat receiving terminal inserts many superconducting pipes simultaneously and carries out heat exchange between dividing plate, forms one-to-many plate-type heat exchange structure.
In above-mentioned superconducting pipe coupling device, described heat-conductive assembly comprises the heat pipe be arranged in vacuum tightness inner chamber, described heat pipe two ends are connected with heat source side jack respectively, and described superconducting pipe is arranged in heat pipe, and on heat pipe, be provided with some radiating fins.
In above-mentioned superconducting pipe coupling device, described casing, heat pipe, radiating fin and dividing plate are combined by any one material in carbon steel, metallic copper, stainless steel, aluminium, titanium and nickel or multiple material respectively and make.
Compared with prior art, the advantage of this superconducting pipe coupling device is: 1. can carry out the efficient heat transfer heat exchange between superconducting pipe, can be used as the coupling device between superconducting pipe, promote superconducting pipe in engineering or industrial development and application, as architectural engineering field of solar energy utilization, geothermal energy utilization field etc.; 2. device only drives by thermal source, energy-conservation zero carbon.Two ends exist the temperature difference just can drive operation, very convenient and efficient; 3. structure is simple, and stable performance, handles very skillfully, and through reasonably designing, being used in building changes in temperature engineering aspect has prospect greatly.
Accompanying drawing explanation
Fig. 1 is the front view of embodiment one in the present invention.
Fig. 2 is the left view of embodiment one in the present invention.
Fig. 3 is A-A cross section view in Fig. 2.
Fig. 4 is the top view of embodiment one in the present invention.
Fig. 5 is B-B cross section view in Fig. 4.
Fig. 6 is the rearview of embodiment two in the present invention.
Fig. 7 is the front view of embodiment two in the present invention.
Fig. 8 is the left view of embodiment two in the present invention.
Fig. 9 is C-C cross section view in Fig. 2.
Figure 10 is the top view of embodiment two in the present invention.
Figure 11 is D-D cross section view in Fig. 4.
Figure 12 is the rearview of embodiment two in the present invention.
Figure 13 is the front view of embodiment three in the present invention.
Figure 14 is the left view of embodiment three in the present invention.
Figure 15 is E-E cross section view in Figure 14.
Figure 16 is the rearview of embodiment three in the present invention.
Figure 17 is the top view of embodiment three in the present invention.
Figure 18 is F-F cross section view in Figure 17.
Figure 19 is G-G cross section view in Figure 17.
In figure, vacuum tightness inner chamber 11, casing 1, superconducting pipe 2, heat source side jack 3, heat receiving terminal pick out jack 4, dividing plate 5, heat pipe 6, radiating fin 7.
Detailed description of the invention
Below in conjunction with the drawings and specific embodiments, the present invention will be further described in detail.
Embodiment one
As shown in figures 1 to 6, this superconducting pipe coupling device, comprise the casing 1 with vacuum tightness inner chamber 11, casing 1 one end is provided with at least one and inserts for superconducting pipe 2 and superconducting pipe 2 can be made to extend to heat source side jack 3 in casing 1, the other end is provided with at least one and inserts and the heat receiving terminal that superconducting pipe 2 can be made to extend in casing 1 picks out jack 4 for superconducting pipe 2, superconductive medium is provided with in the vacuum tightness inner chamber 11 of casing 1, and heat exchange can be carried out under the effect of hot transmission medium when there is the temperature difference between the superconducting pipe 2 that heat source side jack 3 inserts and heat receiving terminal pick out superconducting pipe 2 that jack 4 inserts, preferably, casing 1 is by carbon steel, metallic copper, stainless steel, aluminium, any one material in titanium and nickel or multiple material combine to be made, here vacuum tightness inner chamber 11 is vacuum ionic space, when there is the temperature difference in superconducting pipe 2 end inserted respectively when coupling device both sides, the present invention is conducted heat by vacuum particle space-efficient, allow both sides superconducting pipe 2 heat exchange rapidly and uniformly, be divided into according to the heat exchange mode of superconducting pipe in device: tubular type multi-to-multi coupling device, board-like one-to-many coupling device, wherein tubular type multi-to-multi coupling device, can be divided into again according to hollow box body shape: tubular type cylindrical shape multi-to-multi coupling device, the rectangular-shaped multi-to-multi coupling device of tubular type.
Particularly, superconductive medium in the present embodiment is suspended in vacuum tightness inner chamber 11 and/or is deposited on casing 1 inwall, and superconductive medium comprises any one or multiple combination in carbon, metallic element and inorganic elements, wherein, here metallic element comprises any one or multiple combination in strontium, sodium, titanium and cobalt, and inorganic elements comprises EF-44 or CH-104.Preferably, here superconductive medium is not only suspended in vacuum tightness inner chamber, part can be deposited on luminal wall surface in vacuum tightness, during apparatus of the present invention work, there is the temperature difference and drive as thermal source in the superconducting pipe 2 due to device two ends, superconductive medium produces chemical reaction, release energy, produce dynamical physical transformation thereupon, make metallic element molecule, along device inwall, the heat taking the photograph self-heat power is continuously delivered to the low one end of temperature, because the raw physical phenomenon of this material producing also can supervene fever phenomenon, further promotion efficient heat transfer reaction, and while generation heat, carbon molecule wherein can produce far-infrared radiation heat, owing to there is Working fluid flow in the middle of the structure of superconducting pipe, then certainly exist heat convection.Namely in this device, there is heat conduction, convection current, radiation three kinds of heat exchange mode superposition actings in conjunction, so can reach the effect of high efficient heat exchanging simultaneously.
Further, the superconducting pipe 2 at casing 1 two ends of tubular type multi-to-multi coupling device here adopts pipe type heat transfer mode to carry out heat exchange, and the quantity that the quantity of superconducting pipe 2 inserted of heat source side jack 3 and heat receiving terminal pick out the superconducting pipe 2 that jack 4 inserts is respectively several, and the projection of heat source side jack 3 on casing 1 cross section and heat receiving terminal pick out the projection of jack 4 on casing 1 cross section shifts to install.When casing 1 is rectangle, this coupling device is the rectangular-shaped multi-to-multi coupling device of tubular type, and heat source side jack 3 is a row along casing 1 one end end face transverse direction or genesis analysis, it is two rows that heat receiving terminal picks out jack 4 along the vertical or horizontal distribution of casing 1 other end end face, and the projection of heat source side jack 3 on casing 1 cross section and heat receiving terminal pick out the projection of jack 4 on casing 1 cross section is that I shape distributes and arranges, namely heat source side jack 3 is here vertical row 6 holes, heat receiving terminal picks out jack 4 for laterally two arranging upper and lower 6 holes, 12 holes altogether, heat source side superconducting pipe 2 inserts heat source side jack 3, heat receiving terminal superconducting pipe inserts heat receiving terminal and picks out jack 4, high efficient heat exchanging is carried out in vacuum tightness inner chamber 11, the horizontal vertical setting of types row object in two ends two is that heat transfer efficient of being more convenient for is even, said apparatus, open amount all can adjust by actual service condition flexibly, can Guan Kekai with the quantity inserting superconducting pipe, flexible modulation.
Embodiment two
As shown in fig.7-12, the structure of the present embodiment, principle and implementation step and embodiment one similar, different places is, coupling device in the present embodiment is tubular type cylindrical shape multi-to-multi coupling device, its casing 1 is cylindrical, and described heat source side jack 3 is a row along casing 1 one end end face transverse direction or genesis analysis, it is a row that described heat receiving terminal picks out jack 4 along the vertical or horizontal distribution of casing 1 other end end face, and the projection of described heat source side jack 3 on casing 1 cross section and heat receiving terminal pick out the projection of jack 4 on casing 1 cross section is that cross distribution is arranged, the quantity of heat source side jack is here 6 and is arranged in a row, the quantity that heat receiving terminal picks out jack is 6 and is arranged in a row, heat source side superconducting pipe 2 inserts heat source side jack 3, heat receiving terminal superconducting pipe inserts heat receiving terminal and picks out jack 4, high efficient heat exchanging is carried out in vacuum tightness inner chamber 11, the horizontal vertical setting of types row object in two ends one is that heat transfer efficient of being more convenient for is even.
Embodiment three
As shown in Figure 13-19, the structure of the present embodiment, principle and implementation step and embodiment one similar, different places is, coupling device in the present embodiment is board-like one-to-many coupling device, the superconducting pipe 2 at its casing 1 two ends adopts plate-type heat-exchange mode to carry out heat exchange, the quantity of the superconducting pipe 2 that heat source side jack 3 inserts is one, heat receiving terminal picks out the quantity of the superconducting pipe 2 that jack 4 inserts for several, the feature of board-like one-to-many coupling device is that the cold and hot source of device only accesses a superconducting pipe 2 as house steward, the device other end can be accessed by many superconducting pipes 2 and carries out heat exchange as arm, make cold and hot amount be diverted to arm from house steward to transmit, casing 1 is rectangle, in casing 1 one end, there are at least two heat source side jacks 3, and superconducting pipe 2 inserts in one of them heat source side jack 3 and passes from remaining heat source side jack 3, superconducting pipe 2 is provided with the heat-conductive assembly being positioned at vacuum tightness inner chamber 11, the superconducting pipe 2 that heat receiving terminal picks out jack 4 insertion is arranged on dividing plate 5 one_to_one corresponding in vacuum tightness inner chamber 11 with some respectively and adopts wall-type heat exchange mode to be connected, wherein, here heat-conductive assembly comprises the heat pipe 6 be arranged in vacuum tightness inner chamber 11, heat pipe 6 two ends are connected with heat source side jack 3 respectively, and superconducting pipe 2 is arranged in heat pipe 6, and on heat pipe 6, be provided with some radiating fins 7, here casing 1, heat pipe 6, radiating fin 7 and dividing plate 5 are respectively by carbon steel, metallic copper, stainless steel, aluminium, any one material in titanium and nickel or multiple material combine to be made, that is, a heat pipe 6 is welded with at heat source side upper and lower opening place, material is the alloys such as carbon steel/metallic copper/stainless steel/aluminium/titanium/nickel, heat pipe is welded with radiating fin 7, material is the alloys such as carbon steel/metallic copper/stainless steel/aluminium/titanium/nickel, in order to increasing heat radiation area.In the middle of the space of heat receiving terminal, there is dividing plate 5, material is the alloys such as carbon steel/metallic copper/stainless steel/aluminium/titanium/nickel, and most of heat carries out partition heat conduction heat exchange by dividing plate 5 and superconducting pipe 2, superconducting pipe can be made like this to receive heat more even.Superconducting pipe 2 is entered by one of them heat source side jack 3, through heat pipe 6, then is picked out by residue heat source side jack 3, superconducting pipe 2 through during heat pipe 6 by its heat conduction, then to be dispelled the heat in the middle of vacuum particle space by radiating fin 7, produce the temperature difference and carry out heat exchange.Therefore, heat source side only need access a superconducting pipe 2 as house steward, and heat receiving terminal inserts many superconducting pipes 2 simultaneously and carries out heat exchange between dividing plate 5.
Specific embodiment described herein is only to the explanation for example of the present invention's spirit.Those skilled in the art can make various amendment or supplement or adopt similar mode to substitute to described specific embodiment, but can't depart from spirit of the present invention or surmount the scope that appended claims defines.
Although more employ vacuum tightness inner chamber 11 herein, casing 1, superconducting pipe 2, heat source side jack 3, heat receiving terminal pick out the terms such as jack 4, dividing plate 5, heat pipe 6, radiating fin 7, do not get rid of the possibility using other term.These terms are used to be only used to describe and explain essence of the present invention more easily; The restriction that they are construed to any one additional is all contrary with spirit of the present invention.
Claims (10)
1. a superconducting pipe coupling device, comprise the casing (1) with vacuum tightness inner chamber (11), it is characterized in that, described casing (1) one end is provided with at least one and inserts for superconducting pipe (2) and superconducting pipe (2) can be made to extend to heat source side jack (3) in casing (1), the other end is provided with at least one and inserts for superconducting pipe (2) and superconducting pipe (2) the heat receiving terminal extended in casing (1) can be made to pick out jack (4), superconductive medium is provided with in the vacuum tightness inner chamber (11) of described casing (1), and heat exchange can be carried out under the effect of hot transmission medium when there is the temperature difference between the superconducting pipe (2) that heat source side jack (3) inserts and heat receiving terminal pick out superconducting pipe (2) that jack (4) inserts.
2. superconducting pipe coupling device according to claim 1, it is characterized in that, described superconductive medium is suspended in vacuum tightness inner chamber (11) and/or is deposited on casing (1) inwall, and described superconductive medium comprises any one or multiple combination in carbon, metallic element and inorganic elements.
3. superconducting pipe coupling device according to claim 2, is characterized in that, described metallic element comprises any one or multiple combination in strontium, sodium, titanium and cobalt, and described inorganic elements comprises EF-44 or CH-104.
4. the superconducting pipe coupling device according to claim 1 or 2 or 3, it is characterized in that, the superconducting pipe (2) at described casing (1) two ends adopts pipe type heat transfer mode to carry out heat exchange, and the quantity that the quantity of superconducting pipe (2) inserted of described heat source side jack (3) and heat receiving terminal pick out the superconducting pipe (2) that jack (4) inserts is respectively several, and the projection of described heat source side jack (3) on casing (1) cross section and heat receiving terminal pick out the projection of jack (4) on casing (1) cross section shifts to install.
5. superconducting pipe coupling device according to claim 4, it is characterized in that, described casing (1) is rectangle, and described heat source side jack (3) is a row along casing (1) one end end face transverse direction or genesis analysis, it is two rows that described heat receiving terminal picks out jack (4) along the vertical or horizontal distribution of casing (1) other end end face, and the projection of described heat source side jack (3) on casing (1) cross section and heat receiving terminal pick out the projection of jack (4) on casing (1) cross section is that I shape distributes and arranges.
6. superconducting pipe coupling device according to claim 4, it is characterized in that, described casing (1) is cylindrical, and described heat source side jack (3) is a row along casing (1) one end end face transverse direction or genesis analysis, it is a row that described heat receiving terminal picks out jack (4) along the vertical or horizontal distribution of casing (1) other end end face, and the projection of described heat source side jack (3) on casing (1) cross section and heat receiving terminal pick out the projection of jack (4) on casing (1) cross section is that cross distribution is arranged.
7. the superconducting pipe coupling device according to claim 1 or 2 or 3, it is characterized in that, the superconducting pipe (2) at described casing (1) two ends adopts plate-type heat-exchange mode to carry out heat exchange, the quantity of the superconducting pipe (2) that described heat source side jack (3) inserts is one, and described heat receiving terminal picks out the quantity of the superconducting pipe (2) that jack (4) inserts for several.
8. superconducting pipe coupling device according to claim 7, it is characterized in that, described casing (1) is rectangle, there are in casing (1) one end at least two heat source side jacks (3), and described superconducting pipe (2) inserts in one of them heat source side jack (3) and passes from remaining heat source side jack (3), described superconducting pipe (2) is provided with the heat-conductive assembly being positioned at vacuum tightness inner chamber (11), described heat receiving terminal picks out the superconducting pipe (2) that jack (4) inserts and is arranged on dividing plate (5) one_to_one corresponding in vacuum tightness inner chamber (11) with some and adopt wall-type heat exchange mode to be connected respectively.
9. superconducting pipe coupling device according to claim 8, it is characterized in that, described heat-conductive assembly comprises the heat pipe (6) be arranged in vacuum tightness inner chamber (11), described heat pipe (6) two ends are connected with heat source side jack (3) respectively, and described superconducting pipe (2) is arranged in heat pipe (6), and be provided with some radiating fins (7) on heat pipe (6).
10. superconducting pipe coupling device according to claim 9, it is characterized in that, described casing (1), heat pipe (6), radiating fin (7) and dividing plate (5) are combined by any one material in carbon steel, metallic copper, stainless steel, aluminium, titanium and nickel or multiple material respectively to be made.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201610069732.5A CN105571363A (en) | 2016-01-31 | 2016-01-31 | Coupling device for superconducting tubes |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201610069732.5A CN105571363A (en) | 2016-01-31 | 2016-01-31 | Coupling device for superconducting tubes |
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| CN105571363A true CN105571363A (en) | 2016-05-11 |
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| Application Number | Title | Priority Date | Filing Date |
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| CN201610069732.5A Pending CN105571363A (en) | 2016-01-31 | 2016-01-31 | Coupling device for superconducting tubes |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108224574A (en) * | 2018-02-27 | 2018-06-29 | 北京纳源丰科技发展有限公司 | A kind of heat pipe heat system with evaporating type condensing |
| CN108775828A (en) * | 2018-07-16 | 2018-11-09 | 丁海平 | Superconduction heat exchange unit and its device, system |
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|---|---|---|---|---|
| CN1051750A (en) * | 1989-11-15 | 1991-05-29 | 渠玉芝 | Lnoganic medium heat-conducting material |
| CN2620927Y (en) * | 2003-03-20 | 2004-06-16 | 刘俊富 | Heat conduction superconduit structure capable of long-distance transfer heat quantity |
| CN201265840Y (en) * | 2008-08-01 | 2009-07-01 | 白豪 | Multi-heat pipe ring-configuration type heat conduction module |
| CN101907414A (en) * | 2010-07-26 | 2010-12-08 | 华北电力大学 | Combined oscillatory flow heat pipe with evaporation and heat exchange connecting section |
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2016
- 2016-01-31 CN CN201610069732.5A patent/CN105571363A/en active Pending
Patent Citations (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN1051750A (en) * | 1989-11-15 | 1991-05-29 | 渠玉芝 | Lnoganic medium heat-conducting material |
| CN2620927Y (en) * | 2003-03-20 | 2004-06-16 | 刘俊富 | Heat conduction superconduit structure capable of long-distance transfer heat quantity |
| CN201265840Y (en) * | 2008-08-01 | 2009-07-01 | 白豪 | Multi-heat pipe ring-configuration type heat conduction module |
| CN101907414A (en) * | 2010-07-26 | 2010-12-08 | 华北电力大学 | Combined oscillatory flow heat pipe with evaporation and heat exchange connecting section |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108224574A (en) * | 2018-02-27 | 2018-06-29 | 北京纳源丰科技发展有限公司 | A kind of heat pipe heat system with evaporating type condensing |
| CN108775828A (en) * | 2018-07-16 | 2018-11-09 | 丁海平 | Superconduction heat exchange unit and its device, system |
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Application publication date: 20160511 |
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