CN202662302U - 0-shaped lead-bismuth heat exchange device for achieving double-side flowing heat transfer - Google Patents
0-shaped lead-bismuth heat exchange device for achieving double-side flowing heat transfer Download PDFInfo
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- CN202662302U CN202662302U CN2012202749393U CN201220274939U CN202662302U CN 202662302 U CN202662302 U CN 202662302U CN 2012202749393 U CN2012202749393 U CN 2012202749393U CN 201220274939 U CN201220274939 U CN 201220274939U CN 202662302 U CN202662302 U CN 202662302U
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- bismuth
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- heat transfer
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E30/00—Energy generation of nuclear origin
- Y02E30/30—Nuclear fission reactors
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Abstract
The utility model belongs to the field of nuclear energy heat exchange devices and particularly relates to a 0-shaped lead-bismuth heat exchange device for achieving double-side flowing heat transfer. Coolant flowing heat-exchange channels are welded on outer circumferences of a left ring sleeve and a right ring sleeve of the 0-shaped lead-bismuth heat exchange device. Lead-bismuth alloy fluid flows through an inner pipe, and a coolant passes through the coolant flowing heat-exchange channels are welded on the outer circumferences. The lead-bismuth alloy fluid flows through the device and exchanges heat with the coolant in an annular space channel, lead-bismuth alloy transfers heat to the coolant of a secondary circuit through the device, so that the heat of the lead-bismuth alloy fluid is carried away. The 0-shaped lead-bismuth heat exchange device adopts two heat transfer flowing modes including forced circulation and natural circulation, has the advantages of being simple in structure, low in manufacture cost, good in heat exchange performance, small in lead-bismuth alloy fluid pressure drop loss, free of limitation to coolant types and the like and is suitable for a lead-bismuth heat exchange system.
Description
Technical field
The utility model belongs to the nuclear energy field of heat exchange equipment, particularly a kind of plumbous bismuth heat-exchanger rig of " 0 " type of realizing the bilateral flowing heat transfer.
Background technology
The ADS(accelerate driven system of Accelerator driven system) is a kind of efficient nuclear waste transmuting technology.Its composition is: middle energy high current proton precessional magnetometer; Outer source neutron produces target; Subcritical reactor.Because what the ADS system coolant adopted is the lead bismuth alloy fluid, therefore, effectively derive its with heat very important.At present, in the world by also not building up the ADS reactor, just carrying out experimental loop research abroad.No matter be the shell and tube Intermediate Heat Exchanger that European Experiment Test Accelerator drive system (XADS) adopts; Or the tubular heat exchanger that Korea S HELIOS adopts; Double-pipe exchanger and tubular heat exchanger that U.S. MTL adopts; Also has Italian CIRCE tube-sheet heat exchanger; The thimble tube heat interchanger of Italy NACIE Natural Circulation experimental loop design; Have a mind to again large Libiee's Sa university and adopt the steel flight to strengthen the turbulent flow coaxial sleeve heat exchanger; Add at last the single casing type heat exchanging of the TALL of Sweden KTH (KTH); The most of double-pipe exchanger that adopts of above-mentioned heat exchange, recycle design is mainly taked forced circulation, and Natural Circulation is also more and more paid attention to.
Double-pipe exchanger is as a kind of heat transmission equipment commonly used, and its advantage is simple in structure, is applicable to high-temperature, high pressure fluid, particularly the heat transfer of low capacity fluid.Single hose double-tube heat exchanger transferring heat limited in one's ability, but " U " molded cannula heat interchanger is again owing to there being 180 ° of back bending, thus cause plumbous bismuth fluid-pressure drop loss excessive." 0 " of the present invention jacket tubular heat exchanger, can solve single tube double-pipe exchanger heat transfer capacity little, can solve the excessive problem of " U " molded cannula droop loss again.
Domestic present ADS research is at the early-stage, is carrying out plumbous bismuth experimental loop design studies.Wherein heat-exchanger rig is a very important link, is directly connected to the realization of plumbous bismuth loop and following shut-down system and moves successfully.
The utility model content
The purpose of this utility model is limited in one's ability for single hose double-tube heat exchanger transferring heat in the prior art, but " U " molded cannula heat interchanger is again owing to there being 180 ° of back bending, thereby cause the excessive deficiency of plumbous bismuth fluid-pressure drop loss, a kind of plumbous bismuth heat-exchanger rig of " 0 " type of realizing the bilateral flowing heat transfer is provided, it is characterized in that, the shape of whole heat interchanger is similar to arabic numeral " 0 "; At the right ring ANALYSIS OF COOLANT FLOW heat exchanger channels 8 of right eyelet thimble excircle welding of " 0 " type lead bismuth alloy flow channel 7, the upper end arranges the first coolant entrance 1, and the lower end arranges the first coolant outlet 4; At the left ring ANALYSIS OF COOLANT FLOW heat exchanger channels 9 of left eyelet thimble excircle welding of " 0 " type lead bismuth alloy flow channel 7, the upper end arranges the second coolant entrance 2, and the lower end arranges the second coolant outlet 5; Top at " 0 " type lead bismuth alloy flow channel 7 arranges lead bismuth alloy fluid intake 3, and the bottom arranges lead bismuth alloy fluid egress point 6.
Described coolant entrance and outlet can be exchanged.
Described cooling medium is water or organic conduction oil,
Described organic conduction oil is glycerine or hydrogenated terphenyl.
Described lead bismuth alloy flow channel adopts stainless steel AISI304 or AISI316 material to make, and other mechanical part materials are comprised of materials such as aluminium alloy, austenitic steel or potteries.
The beneficial effects of the utility model are that this device is a kind of device of realizing flowing heat transfer at bilateral, comprise two kinds of heat transfer flow modes of forced circulation and Natural Circulation; Wherein the lead bismuth alloy fluid is walked inner tube, and chilled water is walked outside annular space passage.The lead bismuth alloy cooling medium heat exchange in this device and the annular space passage of flowing through is conducted heat to the cooling medium of secondary circuit by the liquid lead bismuth alloy through this device, takes away thus the heat of plumbous bismuth fluid; It is simple in structure that outstanding advantages is that this device has, low cost of manufacture, and heat exchange property is good, and plumbous bismuth fluid-pressure drop loss is little, to characteristics such as the type of cooling medium are unrestricted, easily realizes promoting.
Description of drawings
Fig. 1 is the plumbous bismuth heat-exchanger rig of a kind of " 0 " type schematic diagram.
Fig. 2 is the A-A cross sectional view of Fig. 1.
Embodiment
The utility model provides a kind of plumbous bismuth heat-exchanger rig of " 0 " type of realizing the bilateral flowing heat transfer.Be explained below in conjunction with accompanying drawing.
Fig. 1 is the plumbous bismuth heat-exchanger rig of " 0 " type schematic diagram.Heat-exchanger rig shown in the figure is a kind of device that carries out flowing heat transfer at bilateral, and the shape of whole heat interchanger is similar to arabic numeral " 0 "; At the right ring ANALYSIS OF COOLANT FLOW heat exchanger channels 8 of right eyelet thimble excircle welding of " 0 " type lead bismuth alloy flow channel 7, the upper end arranges the first coolant entrance 1, and the lower end arranges the first coolant outlet 4; At the left ring ANALYSIS OF COOLANT FLOW heat exchanger channels 9 of left eyelet thimble excircle welding of " 0 " type lead bismuth alloy flow channel 7, the upper end arranges the second coolant entrance 2, and the lower end arranges the second coolant outlet 5; Top at " 0 " type lead bismuth alloy flow channel 7 arranges lead bismuth alloy fluid intake 3, and the bottom arranges lead bismuth alloy fluid egress point 6.
Fig. 2 is the plumbous bismuth heat-exchanger rig of " 0 " type cross sectional view.Among the figure, " 0 " type lead bismuth alloy flow channel 7 interior mobile be the lead bismuth alloy fluid, what flow in left and right ring ANALYSIS OF COOLANT FLOW heat exchanger channels is cooling medium.The lead bismuth alloy fluid flows into the plumbous bismuth fluid passage 7 from lead bismuth alloy fluid intake 3; Cooling medium flows into from the first coolant entrance 1 and the second coolant entrance 2, flows in right coolant channel 8 and left coolant channel 9; The exchange of heat is carried out in both and plumbous bismuth fluid passage 7; At last, the lead bismuth alloy fluid flows out from lead bismuth alloy outlet 6, and cooling medium flows out from the first coolant outlet 4 and the second coolant outlet 5.Perhaps, the first coolant outlet 4 and the second coolant outlet 5 can be used as coolant entrance, and the first coolant entrance 1 and the second coolant entrance 2 can be used as coolant outlet.
In the plumbous bismuth heat-exchanger rig of related " 0 " type, hot fluid is lead bismuth alloy, and cooling medium both can be water, also can glycerine or other organic conduction oil.
The interior diameter of related " 0 " type lead bismuth alloy flow channel 7 is 90mm-150mm, and the interior diameter of coolant flow passage is 120mm-180mm, and wall thickness is 2mm-6mm, length is 0.5m-3m.The pipe range of described heat-exchanger rig can be made suitable adjustment according to actual heat exchange amount.
Claims (6)
1. the plumbous bismuth heat-exchanger rig of " 0 " type of realizing the bilateral flowing heat transfer is characterized in that, described heat-exchanger rig is a kind of device that carries out flowing heat transfer at bilateral, and the shape of whole heat interchanger is similar to arabic numeral " 0 "; At the right eyelet thimble excircle welding right ring ANALYSIS OF COOLANT FLOW heat exchanger channels (8) of " 0 " type lead bismuth alloy flow channel (7), the upper end arranges the first coolant entrance (1), and the lower end arranges the first coolant outlet (4); At the left eyelet thimble excircle welding left ring ANALYSIS OF COOLANT FLOW heat exchanger channels (9) of " 0 " type lead bismuth alloy flow channel (7), the upper end arranges the second coolant entrance (2), and the lower end arranges the second coolant outlet (5); On the top of " 0 " type lead bismuth alloy flow channel (7) lead bismuth alloy fluid intake (3) is set, the bottom arranges lead bismuth alloy fluid egress point (6).
2. the plumbous bismuth heat-exchanger rig of " 0 " type of described realization bilateral flowing heat transfer according to claim 1 is characterized in that, described coolant entrance and outlet can be exchanged.
3. the plumbous bismuth heat-exchanger rig of " 0 " type of described realization bilateral flowing heat transfer according to claim 1 is characterized in that, described cooling medium is water or organic conduction oil,
4. the plumbous bismuth heat-exchanger rig of " 0 " type of described realization bilateral flowing heat transfer according to claim 1 is characterized in that, described organic conduction oil is glycerine or hydrogenated terphenyl.
5. the plumbous bismuth heat-exchanger rig of " 0 " type of described realization bilateral flowing heat transfer according to claim 1, it is characterized in that, described lead bismuth alloy flow channel adopts stainless steel AISI304 or AISI316 material to make, and other mechanical part materials are comprised of materials such as aluminium alloy, austenitic steel or potteries.
6. the plumbous bismuth heat-exchanger rig of " 0 " type of described realization bilateral flowing heat transfer according to claim 1, it is characterized in that, the interior diameter of lead bismuth alloy flow channel is 90mm-150mm, and the interior diameter of coolant flow passage is 120mm-180mm, and wall thickness is 2-6 mm, length is 0.5m-3m.
Priority Applications (1)
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CN2012202749393U CN202662302U (en) | 2012-06-11 | 2012-06-11 | 0-shaped lead-bismuth heat exchange device for achieving double-side flowing heat transfer |
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CN2012202749393U CN202662302U (en) | 2012-06-11 | 2012-06-11 | 0-shaped lead-bismuth heat exchange device for achieving double-side flowing heat transfer |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102831941A (en) * | 2012-06-11 | 2012-12-19 | 华北电力大学 | 0-shaped lead-bismuth heat exchange device |
CN109473184A (en) * | 2018-11-13 | 2019-03-15 | 中国核动力研究设计院 | A kind of embedded lead bismuth alloy circuit for fuel irradiation test |
-
2012
- 2012-06-11 CN CN2012202749393U patent/CN202662302U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102831941A (en) * | 2012-06-11 | 2012-12-19 | 华北电力大学 | 0-shaped lead-bismuth heat exchange device |
CN102831941B (en) * | 2012-06-11 | 2015-04-15 | 华北电力大学 | 0-shaped lead-bismuth heat exchange device |
CN109473184A (en) * | 2018-11-13 | 2019-03-15 | 中国核动力研究设计院 | A kind of embedded lead bismuth alloy circuit for fuel irradiation test |
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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: 20130109 Termination date: 20130611 |