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Continuous thermal processing device and thermal processing method of MgB2 superconduction wire/strip

A heat treatment device and superconducting wire technology, applied in the field of heat treatment, can solve the problems of long heating and cooling time, affecting the superconductivity of wire/strip, and adhesion of wire/strip, and achieve the effect of improving heat treatment, increasing length and improving quality

Active Publication Date: 2018-03-13
NORTHWEST INSTITUTE FOR NON-FERROUS METAL RESEARCH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0004] Traditional MgB 2 The wire / strip heat treatment method is static heat treatment, that is, MgB 2 The wire / strip is rolled into a disc and heat-treated at a constant temperature. If the wire / strip is long, it needs to be placed in a large-scale heat treatment equipment, but the heating and cooling time of a large-scale heat treatment equipment is long, which may easily lead to MgB 2 MgB of wire / strip 2 The transformation of the superconducting core wire or the diffusion reaction with the cladding material will generate a non-superconducting impurity phase, and the long-term high temperature will make the MgB 2 Sticking between wires / strips, eventually affecting MgB 2 Superconducting properties of wire / strip

Method used

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  • Continuous thermal processing device and thermal processing method of MgB2 superconduction wire/strip

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Experimental program
Comparison scheme
Effect test

Embodiment 1

[0032] Such as figure 1The shown continuous heat treatment device includes a heat treatment furnace 3, and the heat treatment furnace 3 includes a furnace body 3-3, a temperature controller 3-9 and a furnace frame 3-8 for supporting the furnace body 3-3. The furnace body 3-3 is pierced with a furnace tube 3-4, and both ends of the furnace tube 3-4 protrude from the furnace body 3-3, and the two ends of the furnace tube 3-4 are respectively equipped with a furnace tube inlet end The cap mouth 3-1 and the furnace pipe outlet end cap mouth 3-7, the furnace pipe 3-4 is equipped with an air inlet 3-2 at one end of the furnace pipe inlet cap mouth 3-1, and the furnace pipe 3-4 An air outlet 3-6 is provided at one end of the cap opening 3-7 of the outlet end of the furnace tube, and a sleeve cooler 4 is set on the furnace tube 3-4 close to the cap opening 3-7 of the outlet end of the furnace tube. The tube cooler 4 is provided with a cooling water inlet 4-1 and a cooling water outle...

Embodiment 2

[0036] This embodiment includes the following steps:

[0037] Step 1. Put the 12-core MgB 2 The starting end of the superconducting strip is connected to one end of the lead wire 2 passing through the cap opening 3-1 of the inlet end of the furnace tube, and then wound on the pay-off wheel 1, and then the other end of the lead wire 2 is passed through the cap opening 3 of the outlet end of the furnace tube -7 is wound on the take-up reel 5; the 12-core MgB 2 The cross-section of the superconducting tape is a rectangle of 0.4mm×3.2mm;

[0038] Step 2. Adjust the temperature in the furnace tube 3-4 to 650°C through the temperature controller 3-9, pass the argon gas into the furnace tube 3-4 through the air inlet 3-2, and push the air from the air outlet 3-6 Discharge, then close the air inlet 3-2 and the exhaust hole 3-6, make the furnace tube 3-4 stable at 650°C for 10 minutes, and then pass the water into the sleeve cooler 4 through the cooling water inlet 4-1 , discharged ...

Embodiment 3

[0047] This embodiment includes the following steps:

[0048] Step 1, the 7-core MgB 2 The starting end of the superconducting wire is connected to one end of the lead wire 2 passing through the cap opening 3-1 of the inlet end of the furnace tube, and then wound on the pay-off wheel 1, and then the other end of the lead wire 2 is passed through the cap opening 3-1 of the outlet end of the furnace tube. 7 is wound on the take-up reel 5; The 7-core MgB 2 The diameter of the superconducting wire is 1.0mm;

[0049] Step 2. Adjust the temperature in the furnace tube 3-4 to 700°C through the temperature controller 3-9, pass the argon gas into the furnace tube 3-4 through the air inlet 3-2, and push the air from the air outlet 3-6 Discharge, then close the air inlet 3-2 and the exhaust hole 3-6, make the furnace tube 3-4 stable at 700°C for 10 minutes, and then pass the water into the sleeve cooler 4 through the cooling water inlet 4-1 , discharged from the cooling water outlet 4...

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Abstract

The invention discloses a continuous thermal processing device. In the device, a take-up wheel is driven to rotate through a transmission belt by a motor, a lead is driven to pull a material to be thermally processed to sequentially pass through a heating region and a cooling region of the thermal processing device, dynamic continuous thermal processing and cooling processing are performed, rapidtemperature rising and reduction of the material is achieved in one step, the temperature difference of the material at different positions during the thermal processing process is reduced, the thermal processing quality is improved, and the application range of the device is expanded. The invention also discloses a thermal processing method of an MgB2 superconduction wire / strip. By the method, the MgB2 superconduction wire / strip is placed in the thermal processing device, continuous and rapid temperature rising and reduction thermal processing under inert gas production is performed, a non-super conduction impurity phase is prevented from being generated from an MgB2 superconduction core wire, an adhesion phenomenon among MgB2 lines / strips is prevented, and the continuous thermal processing device is flexible, controllable, convenient and efficient.

Description

technical field [0001] The invention belongs to the technical field of heat treatment, in particular to a continuous heat treatment device and MgB 2 Superconducting wire / strip heat treatment method. Background technique [0002] Heat treatment is a thermal processing process that changes the chemical composition and organization of the surface or interior of a material through temperature to obtain the desired properties. The conventional heat treatment method is static heat treatment, that is, the material to be heat treated is loaded into a heat treatment device, and the heat treatment process is realized by controlling the temperature and time of heat treatment. The larger the amount of heat treatment, the larger the specification of the heat treatment device is required, but the heating and cooling time of the large heat treatment device is longer, the temperature difference between different positions in the material is large during heat treatment, the effect of heat t...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01B13/00H01L39/24H10N60/01
CPCH01B13/0016H10N60/0856
Inventor 王庆阳闫果潘熙锋杨芳熊晓梅郗丹冯建情李成山张平祥
Owner NORTHWEST INSTITUTE FOR NON-FERROUS METAL RESEARCH
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