前苏联专利SU1613003A3 Articles of superconducting oxide material

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专利摘要:
A superconductive body of an oxidic superconductive material having good mechanical properties is characterized in that the oxidic material forms a matrix through which finely divided particles are mixed at least the surface of which consists of a metal or a metal alloy. Particles in the form of fibres are preferably used and the surface of the particles consists of silver or gold.
公开号:SU1613003A3
申请号:SU884356357
申请日:1988-08-30
公开日:1990-12-07
发明作者:Де Вит Гейсбертус
申请人:Н.В.Филипс Глоэлампенфабрикен (Фирма)；
IPC主号:

专利说明:

The invention relates to electrical engineering, primarily to the manufacture of Products from high-temperature superconducting materials.
The purpose of the invention is to increase the mechanical properties of the oxide superconducting material.
The proposed product of oxide superconducting material is a matrix of oxide superconducting material in which metallic fibers are distributed, having a length of less than 2 mm and a diameter of 5-100 microns, the surface layer of fibers consisting of silver or gold. The fibers are made of an alloy of iron-nickel-chromium.
The advantage of this material is. is that when the superconductivity decreases, for example, as a result of an increase in temperature, good thermal conductivity and current conductivity remain. This protection effect is achieved especially with a high degree of filling of the composite material, in which, for example, up to 40% of particles by volume can be applied. The particles are composed of one or more metals. Such particles are particularly suitable to be loaded. tensile strength. When metal particles are used, the expansion coefficient is not critical, since Metals can plastically deform.
Organic bonding layers cannot be formed on the particles,. since they cannot hold the heat at which the
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The sintering of the matrix material occurs, and the remaining parts may adversely affect the composition of the superconducting material. Particles are used in ,. fiber shape with which good mechanical properties are achieved. The fibers have a length of less than 2 mm and a diameter of 5-100 µm and can be used, for example, in an arbitrarily oriented or oriented form. Nap, fibers of plastic material are used that are not damaged during mixing and are uphthalous by means of precipitation hardening during sintering of the matrix material. ..
To eliminate the reaction of a metal with a superconducting material, particles whose surface consists of a metal, namely silver or gold, are used. This eliminates the disturbance of the oxygen content and the valence of the copper ions, which is important for the superconducting state and the high value of the transition temperature (Tg). The choice of silver and gold is determined by the fact that they do not enter into a reaction with a superconducting material. Oxygen affinity is low. The metals are not multivalent, so the valence of the copper ions is not affected.
Fibers of relatively soft metals can be used, for example. gold and silver, because these metals increase the plasticity of the composite material. Particles in the form of iron, nickel and chromium alloy fibers having a cladding layer of silver and copper are used. Such alloys may contain other elements, such as Mo and C.
Example. Metall- is used. Comical fibers having an average length of 1 -MM and an average diameter of 8 microns. The fibers are composed of components, wt%: Cr 22, Fe 18, Ni 48, Mo 9, C, Co and W
rest. Expansion ratio
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The alloy is approximately 1210 / s. Fibers are densely clad with silver about 1 micron thick.
The metal fibers are washed in water, dried and sieved. A sieve having a cell size of 1.5 mm. The mixture is prepared from 30 vol.% Metal fibers and 70 vol.% Y 5 Y.
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60 g of mixable materials and 120 g of butanone are carefully moved for 5 seconds in the grinder. Then the mixture is scraped from the walls of the grinder and once again moved for 5 s. For possible damage to metallic fibers, the agitation was brief.
The resulting mass is dried. A cake is obtained, which is broken and crushed to a coarse powder using a sieve having 1.5 mm cells. The powder consists of grains that contain metal fibers and ceramic particles.
The powder is placed in a mold made of -. a cohesive resin, for example polymethyl methanol, in 5 mm thick layers that are smoothed each time until the next layer is formed, thus eliminating the formation of voids. Then the powder is pressed to a given Form under a pressure of 10 - Pa, depending on the size of the product.
Then the intermediate product is compacted by isostatic compression in an oil tank and carefully
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five
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five
but packaged to avoid direct contact with oil. Pressure 5X 5-10 Pa. Then the product is pressed in. hotter than states in a nitrogen atmosphere at a pressure of 7–10 Pa. The heating rate is 200 ° C / h, and the product is held at a maximum temperature of 950 ° C for 15 minutes. This stage, in which sintering occurs, is carried out as quickly as possible in order to prevent damage to the metal fibers.
The product is slowly cooled in the oxygen atmosphere so that the right amount of oxygen is present in the superconducting material.

权利要求:
Claims (2)
[1]
1. An article of oxide superconducting material, characterized in that, in order to improve the mechanical properties, the oxide superconducting material forms a matrix in which metallic fibers having a length of less than 2 mm are distributed.
51613003
and a diameter of 5-100 microns, with the surface t
[2]
2. Product pop. 1, the distinctive fiber layer consists of a fiberglass so that the fibers are silver or nickel. Iron-nickel-chrome alloy.

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同族专利:

公开号 | 公开日

US4983572A|1991-01-08|

EP0306084A1|1989-03-08|

KR890005901A|1989-05-17|

NL8702059A|1989-04-03|

JPH0193464A|1989-04-12|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US3447913A|1966-03-18|1969-06-03|George B Yntema|Superconducting composite material|

GB1132551A|1966-04-29|1968-11-06|Gen Electric|Improvements in thermally stable superconductors|

EP0102489B1|1982-07-31|1987-02-04|BROWN, BOVERI & CIE Aktiengesellschaft|Multifilament superconductor and method of making the same|

US4826808A|1987-03-27|1989-05-02|Massachusetts Institute Of Technology|Preparation of superconducting oxides and oxide-metal composites|

US5204318A|1987-03-27|1993-04-20|Massachusetts Institute Of Technology|Preparation of superconducting oxides and oxide-metal composites|

CA1340569C|1987-05-05|1999-06-01|Sungho Jin|Superconductive body having improved properties, and apparatus and systems comprising such a body|

DE3724229C2|1987-07-22|1989-04-27|Battelle-Institut Ev, 6000 Frankfurt, De|

US4892861A|1987-08-14|1990-01-09|Aluminum Company Of America|Liquid phase sintered superconducting cermet|US5011823A|1987-06-12|1991-04-30|At&T Bell Laboratories|Fabrication of oxide superconductors by melt growth method|

US4999338A|1990-02-23|1991-03-12|The Dow Chemical Company|Preparation of metal/superconducting oxide composites|

US5426094A|1991-01-16|1995-06-20|Arch Development Corporation|High temperature superconductor current leads|

DE19948129A1|1999-10-07|2001-04-12|Bayer Ag|Active ingredient combinations with insecticidal and acaricidal properties|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

NL8702059A|NL8702059A|1987-09-02|1987-09-02|SUPER CONDUCTIVE BODY.|

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