CN105758239A - Integrated machining equipment for superconducting radiator and machining and using method - Google Patents
Integrated machining equipment for superconducting radiator and machining and using method Download PDFInfo
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- CN105758239A CN105758239A CN201610275123.5A CN201610275123A CN105758239A CN 105758239 A CN105758239 A CN 105758239A CN 201610275123 A CN201610275123 A CN 201610275123A CN 105758239 A CN105758239 A CN 105758239A
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- 238000000034 method Methods 0.000 title claims abstract description 63
- 238000003754 machining Methods 0.000 title abstract 9
- 230000008569 process Effects 0.000 claims abstract description 16
- 230000007246 mechanism Effects 0.000 claims abstract description 8
- 239000012530 fluid Substances 0.000 claims description 21
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 20
- 230000009471 action Effects 0.000 claims description 12
- 238000010438 heat treatment Methods 0.000 claims description 11
- 239000003795 chemical substances by application Substances 0.000 claims description 7
- 239000000084 colloidal system Substances 0.000 claims description 6
- NJPPVKZQTLUDBO-UHFFFAOYSA-N novaluron Chemical compound C1=C(Cl)C(OC(F)(F)C(OC(F)(F)F)F)=CC=C1NC(=O)NC(=O)C1=C(F)C=CC=C1F NJPPVKZQTLUDBO-UHFFFAOYSA-N 0.000 claims description 4
- 238000007789 sealing Methods 0.000 claims description 4
- 241000973497 Siphonognathus argyrophanes Species 0.000 claims description 3
- 150000001875 compounds Chemical class 0.000 claims description 3
- 238000001514 detection method Methods 0.000 claims description 3
- 238000005213 imbibition Methods 0.000 claims description 3
- 239000000203 mixture Substances 0.000 claims description 3
- 230000000630 rising effect Effects 0.000 claims description 3
- 238000010923 batch production Methods 0.000 abstract 1
- 238000004519 manufacturing process Methods 0.000 description 4
- 230000008859 change Effects 0.000 description 3
- 230000002528 anti-freeze Effects 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 229910000831 Steel Inorganic materials 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000036772 blood pressure Effects 0.000 description 1
- 238000005260 corrosion Methods 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 238000004134 energy conservation Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000009434 installation Methods 0.000 description 1
- 238000012797 qualification Methods 0.000 description 1
- 230000002787 reinforcement Effects 0.000 description 1
- 239000010959 steel Substances 0.000 description 1
Classifications
-
- 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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- Sustainable Development (AREA)
- Physics & Mathematics (AREA)
- Thermal Sciences (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Containers, Films, And Cooling For Superconductive Devices (AREA)
Abstract
The invention provides integrated machining equipment for a superconducting radiator and a machining and using method.Manual operation is always adopted for traditional superconducting radiator machining, it is difficult to master precision of the whole process, quality of a produced product cannot be guaranteed, and batch production cannot be conducted.The integrated machining equipment for the superconducting radiator comprises a lower guide rail, one side of the lower guide rail (11) is provided with a fixed stand column (3), the other side of the lower guide rail is provided with a sliding stand column (20), the lower portion of the fixed stand column is provided with a lower supporting plate A (10), the upper portion of the fixed stand column is provided with an upper supporting plate A (6), the lower portion of the sliding stand column is provided with a lower supporting plate B (28), the upper portion of the sliding stand column is provided with an upper supporting plate B (21), the upper supporting plate A and the upper supporting plate B are provided with a vertical adjusting mechanism, and the upper supporting plate A and the lower supporting plate B are provided with a transverse micro-adjusting mechanism.The integrated machining equipment for the superconducting radiator and the machining and using method are applied to the field of superconducting radiator machining and particularly applied to superconducting radiators.
Description
Technical field:
The present invention relates to superconducting radiator manufacture field, particularly relate to a kind of superconducting radiator with being integrally machined equipment and processing using method.
Background technology:
Current north of china in winter heating, commonly used be heat-transfer working medium with water heating installation, the heat-transfer working medium of this radiator is to circulate under elevated pressure, have that heat transfer efficiency is low, power consumption is high and the defect such as Thermal Conduction Equipment rapid wear, and superconducting radiator is based on superconductive medium phase-change heat transfer principle, it is mainly by the fine vacuum main body of radiator, and special special antirust heating agent multiple tube and the hot antifreeze efficient heat transfer complex media (superconducting fluid) of speed etc. form;Replace traditional water with efficient heat-conducting medium superconducting fluid, utilize superconducting fluid brand-new operation principle of circulating heat transfer in the pipeline of vacuum sealing, be truly realized water-saving energy-conservation, antifreeze anti-corrosion, brand-new heating simple and direct, maintenance-free is installed;Traditional superconducting radiator produces and has been used up manual work, it is difficult to grasp the degree of accuracy of each production process, the product quality produced cannot ensure, the heat-transfer working medium of the interior pipe of submergence heating it is filled with in superconductive radiating case, and the vacuum in the kind of heat-transfer working medium, loading and vacuum superconductive radiator, heat transfer efficiency has considerable influence, and a kind of appearance being integrally machined equipment solves this problem.
Summary of the invention:
It is an object of the invention to provide a kind of superconducting radiator with being integrally machined equipment and processing using method.
Above-mentioned purpose is realized by following technical scheme:
A kind of superconducting radiator is with being integrally machined equipment, its composition includes: lower guideway, on described lower guideway, side is provided with vertical columns, opposite side is provided with slip column, in the bottom of described vertical columns, bottom plate A is installed, the top of described vertical columns is provided with mounting plate A, the bottom of described slip column is provided with bottom plate B, the top of described slip column is provided with mounting plate B, described mounting plate A and mounting plate B has upper and lower guiding mechanism, and described mounting plate B and bottom plate B has transverse micro-adjustment mechanism.
Described superconducting radiator is with being integrally machined equipment, described vertical columns is connected on lower guideway by pedestal securing member, described vertical columns bottom plate A is connected to 1 ~ 2 the next cylinder, described the next cylinder drives fast joint by push rod, it is connected with each other by connecting tube A between described fast joint, described fast joint is connected to the both sides of connecting tube A, and described connecting tube A has intake-outlet, and described intake-outlet is connected with electric boiler.
Described superconducting radiator is with being integrally machined equipment, described vertical columns upper end has height adjusting support plate, be dynamically connected on described height adjusting support plate adjustment handle A, described adjustment handle A connects height adjusting screw rod, described height adjusting screw rod traverse mounting plate A, contiguous block A and gripper shoe, described mounting plate A is also slidably connected with vertical columns, described mounting plate A is connected to 1 ~ 2 pressurized cylinder, described pressurized cylinder is connected with air compressor by pipeline, and described pressurized cylinder drives fast joint respectively through push rod.
Described superconducting radiator is with being integrally machined equipment, described slip column bottom plate B is connected to 1 ~ 2 fast joint, described fast joint is linked together by connecting tube B, described connecting tube B is connected to and laterally finely tunes on screw rod, described transverse direction fine setting screw rod by contiguous block B and regulates handle B connection, and is fastened by locking nut.
Described superconducting radiator is with being integrally machined equipment, described slip column upper end has height adjusting support plate equally, be dynamically connected on described height adjusting support plate adjustment handle A, described adjustment handle A connects height adjusting screw rod, described height adjusting screw rod traverse mounting plate B, contiguous block B and gripper shoe, described mounting plate B is also slidably connected with slip column, described mounting plate B is connected to 1 ~ 2 beadlet gun body, the front end of described beadlet gun body has fast joint, described beadlet gun body also has the pipeline being connected with vacuum pump, the top of described each gun body has beadlet folder, described each beadlet gun body rear portion is connected to magnetic force cylinder, described magnetic force cylinder upper outer surface has magnetic force block, described magnetic force cylinder interior has piston and rifle pin.
Described superconducting radiator, with being integrally machined equipment, is connected to guide rail splice between described lower guideway.
The described superconducting radiator processing using method being integrally machined equipment, its step is the first step: quantitative filling: namely radiator is fixed by (a) on equipment, and is connected on fill proportioning device by hydraulic quick coupler by radiator;B () opens the control panel of the equipment that is integrally machined, adjust control panel data input pin and set desired data, and the consumption of the radiator rating to institute's fill and the superconducting fluid corresponding to institute's fill capacity is set;C () runs working procedure by the micro computer in control panel, first make solenoid valve conduction by the program after setting, make vacuum pump start working, and carries out evacuation process to being connected, by vacuum pump, radiator and batcher, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, the dosing pump in batcher is made to start working, according to radiator post number, by the capacity of 30 ~ 40g/ post, by heat-transfer working medium (superconducting fluid) dose in medium tank to capacity cylinder;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program after setting, make vacuum pump quit work;F () runs working procedure by the micro computer in control panel, make the valve opening of capacity cylinder, make heat-transfer working medium (superconducting fluid) be drawn in radiator, opens solenoid valve, closes vacuum line, and imbibition process terminates;Second step: bonding in vacuum: (a) adjusts control panel data input pin and set desired data, and the radiator rating that will carry out vacuum sealing operation is set;B () runs working procedure by the micro computer in control panel, first solenoid valve conduction is made by the program after setting, magnetic force cylinder is made to start action, the result of magnetic force cylinder action makes rifle pin promote beadlet to move forward to the middle part closing colloid, c () exports through the signal of sensor, micro computer in control panel runs corresponding working procedure, when gas circuit is completely enclosed by the program after setting, make solenoid valve conduction, make vacuum pump start working, carry out evacuation process to being connected, by vacuum pump, radiator and beadlet folder, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, magnetic force cylinder is made to start again at work, the beadlet that will be present in closing in colloid rifle needle passageway propels heating agent multiple tube mouth place in radiator by rifle needle passageway, is closed by the heating agent compound mouth of pipe;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make vacuum pump and magnetic force cylinder quit work;3rd step: performance detects: radiator is connected on water circulation pipe by (a) by pipeline;B () adjusts control panel data input pin and sets desired data, the capacity of radiator and discharge and the water temperature of passed through radiator that will carry out performance detection is set;(3) open electric boiler and add the water in pipe line and boiler;(4) run working procedure by micro computer in control panel, first make solenoid valve conduction by the program after setting, make circulating pump start action, the action of circulating pump make in pipeline water start the cycle over flowing;(5) export through the signal of pressure and temperature sensor, micro computer in control chamber runs corresponding working procedure, when pipeline is completely enclosed by the program after setting, make solenoid valve conduction, make circulating pump work, heat up to being connected, by pipeline, circulating pump and electric boiler, the pipeline space formed and improve flow process;(6) when the water temperature of pipeline interior volume is gradually increasing by low temperature, improve sensing data display on control chamber and observe the startup situation of heat-transfer working medium (superconducting fluid), when temperature rises gradually from 30 ~ 45 DEG C, heat-transfer working medium (superconducting fluid) should start gradually or even be gasified totally, when temperature rises gradually from 45 ~ 75 DEG C, the rising of water temperature rises should be directly proportional to the temperature of heat-transfer working medium (superconducting fluid);(7) run working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make circulating pump quit work;(8) running working procedure by the micro computer in control chamber, make the valve opening that pressure transducer and temperature sensor disconnect, device for detecting performance work process terminates, and cylinder all unlocks end-of-job.
Beneficial effects of the present invention:
1. the present invention be integrally machined equipment, " being integrally machined equipment " mode of employing, the positive and negative pressure force transducer in each portion of coupling apparatus, temperature sensor and flow transducer, control to press production stage by computer, by the control to a series of production process such as the vacuum of product, boosting, speed row, blood pressure lowering, locking, the quality making product is significantly improved, and the qualification rate, the labor intensity alleviating operator that improve product, improves productivity ratio.
The present invention is integrally machined equipment, adopt integrated full-automatic unit, utilize the integrated circuit based on microcomputerized control chip, adopt and each operation is preset operation routine, and can according to actually used situation, adjust and change sets the mode exported, the work in each portion of complete machine is coordinated control.
The equipment that is integrally machined of the present invention, adopts and quantitative filling system, bonding in vacuum system and performance detecting system is carried out system combination, each key link in the radiator course of processing is effectively controlled, and then improves the quality of product further.
The present invention is integrally machined equipment, it is uniformly controlled each sensor by microcomputer chip circuit, by each sensor, signal passed to quantitative unit, pressure signal is passed to electromagnetic valve, temperature signal is passed to the time relay, with the unlatching of pressure signal change commander's electromagnetic valve, temperature signal change commander's discharge capacity electromagnetic valve, the pressure spot of final pressure electromagnetic valve is the closing steel ball in terminal control adapter, makes the concordance of the total quality of radiator obtain reinforcement.
Accompanying drawing illustrates:
Accompanying drawing 1 is the structural representation of the equipment that is integrally machined of the present invention.
Accompanying drawing 2 is the structure schematic side view of the equipment that is integrally machined of the present invention.
Accompanying drawing 3 is that the structure A-A of the equipment that is integrally machined of the present invention is to top view.
Accompanying drawing 4 is that the structure B-B of the equipment that is integrally machined of the present invention is to schematic diagram.
Accompanying drawing 5 is that the structure C-C of the equipment that is integrally machined of the present invention is to schematic diagram.
In figure: 1 height adjusting screw rod;2 adjust handle A;3 vertical columns;4 pipelines;5 pressurized cylinders;6 mounting plate A;7 contiguous block A;8 pedestal securing members;9 the next cylinders;10 bottom plate A;11 lower guideways;12 fast joints;13 height adjusting support plates;14 beadlet folders;15 contiguous block B;16 magnetic force cylinders;17 magnetic force blocks;18 pistons;19 beadlet gun body;20 slip columns;21 mounting plate B;22 connecting tube A;23 guide rail splices;24 lateral adjustments contiguous blocks;25 lateral adjustments screw rods;26 regulate handle B;27 locking nuts;28 bottom plate B;29 connecting tube B;30 intake-outlets;
Detailed description of the invention:
Embodiment 1:
A kind of superconducting radiator is with being integrally machined equipment, its composition includes: lower guideway, on described lower guideway 11, side is provided with vertical columns 3, opposite side is provided with slip column 20, in the bottom of described vertical columns, bottom plate A10 is installed, the top of described vertical columns is provided with mounting plate A6, the bottom of described slip column is provided with bottom plate B28, the top of described slip column is provided with mounting plate B21, described mounting plate A and mounting plate B has upper and lower guiding mechanism, and described mounting plate B and bottom plate B has transverse micro-adjustment mechanism.
Embodiment 2:
Superconducting radiator according to embodiment 1 is with being integrally machined equipment, described vertical columns is connected on lower guideway by pedestal securing member 8, described vertical columns bottom plate A is connected to 1 ~ 2 the next cylinder 9, described the next cylinder drives fast joint 12 by push rod, it is connected with each other by connecting tube A22 between described fast joint, described fast joint is connected to the both sides of connecting tube A, and described connecting tube A has intake-outlet 30.
Embodiment 3:
Superconducting radiator according to embodiment 1 is with being integrally machined equipment, described vertical columns upper end has height adjusting support plate 13, be dynamically connected on described height adjusting support plate adjustment handle A2, described adjustment handle A connects height adjusting screw rod 1, described height adjusting screw rod traverse mounting plate A, contiguous block A7 and gripper shoe, described mounting plate A is also slidably connected with vertical columns, described mounting plate A is connected to 1 ~ 2 pressurized cylinder 5, described pressurized cylinder is connected with air compressor by pipeline 4, described pressurized cylinder drives fast joint respectively through push rod.
Embodiment 4:
Superconducting radiator according to embodiment 1 is with being integrally machined equipment, described slip column bottom plate B is connected to 1 ~ 2 fast joint, described fast joint is linked together by connecting tube B29, described connecting tube B is connected to and laterally finely tunes on screw rod 25, described transverse direction fine setting screw rod by contiguous block B24 and regulates handle B26 connection, and is fastened by locking nut 27.
Embodiment 5:
nullSuperconducting radiator according to embodiment 1 is with being integrally machined equipment,Described slip column upper end has height adjusting support plate equally,Be dynamically connected on described height adjusting support plate adjustment handle A,Described adjustment handle A connects height adjusting screw rod,Described height adjusting screw rod traverse mounting plate B、Contiguous block B15 and gripper shoe,Described mounting plate B is also slidably connected with slip column,Described mounting plate B is connected to 1 ~ 2 beadlet gun body 19,The front end of described beadlet gun body has fast joint,Described beadlet gun body also has the pipeline being connected with vacuum pump,The top of described each gun body has beadlet folder 14,Described each beadlet gun body rear portion is connected to magnetic force cylinder 16,Described magnetic force cylinder upper outer surface has magnetic force block 17,Described magnetic force cylinder interior has piston 18 and rifle pin.
Embodiment 6:
Superconducting radiator according to embodiment 1, with being integrally machined equipment, is connected to guide rail splice 23 between described lower guideway.
Embodiment 7:
A kind of superconducting radiator utilized described in embodiment 1 to 6 processing using method being integrally machined equipment, described superconducting radiator is the first step with being integrally machined its step of processing using method of equipment: quantitative filling: namely (a) by radiator on equipment fixing, and radiator is connected on fill proportioning device by hydraulic quick coupler;B () opens the control panel of the equipment that is integrally machined, adjust control panel data input pin and set desired data, and the consumption of the radiator rating to institute's fill and the superconducting fluid corresponding to institute's fill capacity is set;C () runs working procedure by the micro computer in control panel, first make solenoid valve conduction by the program after setting, make vacuum pump start working, and carries out evacuation process to being connected, by vacuum pump, radiator and batcher, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, the dosing pump in batcher is made to start working, according to radiator post number, by the capacity of 30 ~ 40g/ post, by heat-transfer working medium (superconducting fluid) dose in medium tank to capacity cylinder;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program after setting, make vacuum pump quit work;F () runs working procedure by the micro computer in control panel, make the valve opening of capacity cylinder, make heat-transfer working medium (superconducting fluid) be drawn in radiator, opens solenoid valve, closes vacuum line, and imbibition process terminates;Second step: bonding in vacuum: (a) adjusts control panel data input pin and set desired data, and the radiator rating that will carry out vacuum sealing operation is set;B () runs working procedure by the micro computer in control panel, first solenoid valve conduction is made by the program after setting, magnetic force cylinder is made to start action, the result of magnetic force cylinder action makes rifle pin promote beadlet to move forward to the middle part closing colloid, c () exports through the signal of sensor, micro computer in control panel runs corresponding working procedure, when gas circuit is completely enclosed by the program after setting, make solenoid valve conduction, make vacuum pump start working, carry out evacuation process to being connected, by vacuum pump, radiator and beadlet folder, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, magnetic force cylinder is made to start again at work, the beadlet that will be present in closing in colloid rifle needle passageway propels heating agent multiple tube mouth place in radiator by rifle needle passageway, is closed by the heating agent compound mouth of pipe;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make vacuum pump and magnetic force cylinder quit work;3rd step: performance detects: radiator is connected on water circulation pipe by (a) by pipeline;B () adjusts control panel data input pin and sets desired data, the capacity of radiator and discharge and the water temperature of passed through radiator that will carry out performance detection is set;(3) open electric boiler and add the water in pipe line and boiler;(4) run working procedure by micro computer in control panel, first make solenoid valve conduction by the program after setting, make circulating pump start action, the action of circulating pump make in pipeline water start the cycle over flowing;(5) export through the signal of pressure and temperature sensor, micro computer in control chamber runs corresponding working procedure, when pipeline is completely enclosed by the program after setting, make solenoid valve conduction, make circulating pump work, heat up to being connected, by pipeline, circulating pump and electric boiler, the pipeline space formed and improve flow process;(6) when the water temperature of pipeline interior volume is gradually increasing by low temperature, improve sensing data display on control chamber and observe the startup situation of heat-transfer working medium (superconducting fluid), when temperature rises gradually from 30 ~ 45 DEG C, heat-transfer working medium (superconducting fluid) should start gradually or even be gasified totally, when temperature rises gradually from 45 ~ 75 DEG C, the rising of water temperature rises should be directly proportional to the temperature of heat-transfer working medium (superconducting fluid);(7) run working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make circulating pump quit work;(8) running working procedure by the micro computer in control chamber, make the valve opening that pressure transducer and temperature sensor disconnect, device for detecting performance work process terminates, and cylinder all unlocks end-of-job.
Claims (7)
1. a superconducting radiator is with being integrally machined equipment, its composition includes: lower guideway, it is characterized in that: on described lower guideway, side is provided with vertical columns, opposite side is provided with slip column, in the bottom of described vertical columns, bottom plate A is installed, the top of described vertical columns is provided with mounting plate A, the bottom of described slip column is provided with bottom plate B, the top of described slip column is provided with mounting plate B, described mounting plate A and mounting plate B has upper and lower guiding mechanism, and described mounting plate B and bottom plate B has transverse micro-adjustment mechanism.
2. superconducting radiator according to claim 1 is with being integrally machined equipment, it is characterized in that: described vertical columns is connected on lower guideway by pedestal securing member, described vertical columns bottom plate A is connected to 1 ~ 2 the next cylinder, described the next cylinder drives fast joint by push rod, it is connected with each other by connecting tube A between described fast joint, described fast joint is connected to the both sides of connecting tube A, described connecting tube A has intake-outlet, and described intake-outlet is connected with electric boiler.
3. superconducting radiator according to claim 1 and 2 is with being integrally machined equipment, it is characterized in that: described vertical columns upper end has height adjusting support plate, be dynamically connected on described height adjusting support plate adjustment handle A, described adjustment handle A connects height adjusting screw rod, described height adjusting screw rod traverse mounting plate A, contiguous block A and gripper shoe, described mounting plate A is also slidably connected with vertical columns, described mounting plate A is connected to 1 ~ 2 pressurized cylinder, described pressurized cylinder is connected with air compressor by pipeline, described pressurized cylinder drives fast joint respectively through push rod.
4. the superconducting radiator according to claim 1 or 2 or 3 is with being integrally machined equipment, it is characterized in that: on described slip column bottom plate B, be connected to 1 ~ 2 fast joint, described fast joint is linked together by connecting tube B, described connecting tube B is connected to and laterally finely tunes on screw rod, described transverse direction fine setting screw rod by contiguous block B and regulates handle B connection, and is fastened by locking nut.
null5. the superconducting radiator according to claim 1 or 2 or 3 or 4 is with being integrally machined equipment,It is characterized in that: described slip column upper end has height adjusting support plate equally,Be dynamically connected on described height adjusting support plate adjustment handle A,Described adjustment handle A connects height adjusting screw rod,Described height adjusting screw rod traverse mounting plate B、Contiguous block B and gripper shoe,Described mounting plate B is also slidably connected with slip column,Described mounting plate B is connected to 1 ~ 2 beadlet gun body,The front end of described beadlet gun body has fast joint,Described beadlet gun body also has the pipeline being connected with vacuum pump,The top of described each gun body has beadlet folder,Described each beadlet gun body rear portion is connected to magnetic force cylinder,Described magnetic force cylinder upper outer surface has magnetic force block,Described magnetic force cylinder interior has piston and rifle pin.
6. the superconducting radiator according to claim 1 or 2 or 3 or 4 or 5 is with being integrally machined equipment, it is characterized in that: be connected to guide rail splice between described lower guideway.
7. one kind utilizes superconducting radiator described for one of the claim 1-6 processing using method being integrally machined equipment, it is characterized in that: described superconducting radiator is the first step with being integrally machined its step of processing using method of equipment: quantitative filling: namely (a) by radiator on equipment fixing, and radiator is connected on fill proportioning device by hydraulic quick coupler;B () opens the control panel of the equipment that is integrally machined, adjust control panel data input pin and set desired data, and the consumption of the radiator rating to institute's fill and the superconducting fluid corresponding to institute's fill capacity is set;C () runs working procedure by the micro computer in control panel, first make solenoid valve conduction by the program after setting, make vacuum pump start working, and carries out evacuation process to being connected, by vacuum pump, radiator and batcher, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, the dosing pump in batcher is made to start working, according to radiator post number, by the capacity of 30 ~ 40g/ post, by heat-transfer working medium (superconducting fluid) dose in medium tank to capacity cylinder;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program after setting, make vacuum pump quit work;F () runs working procedure by the micro computer in control panel, make the valve opening of capacity cylinder, make heat-transfer working medium (superconducting fluid) be drawn in radiator, opens solenoid valve, closes vacuum line, and imbibition process terminates;Second step: bonding in vacuum: (a) adjusts control panel data input pin and set desired data, and the radiator rating that will carry out vacuum sealing operation is set;B () runs working procedure by the micro computer in control panel, first solenoid valve conduction is made by the program after setting, magnetic force cylinder is made to start action, the result of magnetic force cylinder action makes rifle pin promote beadlet to move forward to the middle part closing colloid, c () exports through the signal of sensor, micro computer in control panel runs corresponding working procedure, when gas circuit is completely enclosed by the program after setting, make solenoid valve conduction, make vacuum pump start working, carry out evacuation process to being connected, by vacuum pump, radiator and beadlet folder, the internal duct space formed;D () is when the vacuum of pipeline interior volume reaches 0.65 ~ 0.75Pa, working procedure is run by the micro computer in control panel, magnetic force cylinder is made to start again at work, the beadlet that will be present in closing in colloid rifle needle passageway propels heating agent multiple tube mouth place in radiator by rifle needle passageway, is closed by the heating agent compound mouth of pipe;E () runs working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make vacuum pump and magnetic force cylinder quit work;3rd step: performance detects: radiator is connected on water circulation pipe by (a) by pipeline;B () adjusts control panel data input pin and sets desired data, the capacity of radiator and discharge and the water temperature of passed through radiator that will carry out performance detection is set;(3) open electric boiler and add the water in pipe line and boiler;(4) run working procedure by micro computer in control panel, first make solenoid valve conduction by the program after setting, make circulating pump start action, the action of circulating pump make in pipeline water start the cycle over flowing;(5) export through the signal of pressure and temperature sensor, micro computer in control chamber runs corresponding working procedure, when pipeline is completely enclosed by the program after setting, make solenoid valve conduction, make circulating pump work, heat up to being connected, by pipeline, circulating pump and electric boiler, the pipeline space formed and improve flow process;(6) when the water temperature of pipeline interior volume is gradually increasing by low temperature, improve sensing data display on control chamber and observe the startup situation of heat-transfer working medium (superconducting fluid), when temperature rises gradually from 30 ~ 45 DEG C, heat-transfer working medium (superconducting fluid) should start gradually or even be gasified totally, when temperature rises gradually from 45 ~ 75 DEG C, the rising of water temperature rises should be directly proportional to the temperature of heat-transfer working medium (superconducting fluid);(7) run working procedure by the micro computer in control panel, first make closed electromagnetic valve by the program set, make circulating pump quit work;(8) running working procedure by the micro computer in control chamber, make the valve opening that pressure transducer and temperature sensor disconnect, device for detecting performance work process terminates, and cylinder all unlocks end-of-job.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201610275123.5A CN105758239A (en) | 2016-04-28 | 2016-04-28 | Integrated machining equipment for superconducting radiator and machining and using method |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201610275123.5A CN105758239A (en) | 2016-04-28 | 2016-04-28 | Integrated machining equipment for superconducting radiator and machining and using method |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN105758239A true CN105758239A (en) | 2016-07-13 |
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Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201610275123.5A Pending CN105758239A (en) | 2016-04-28 | 2016-04-28 | Integrated machining equipment for superconducting radiator and machining and using method |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN105758239A (en) |
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2016
- 2016-04-28 CN CN201610275123.5A patent/CN105758239A/en active Pending
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Application publication date: 20160713 |