KR840008202A - Vacuum Interrupter (INTERRUPTER) - Google Patents

Abstract

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Description

Vacuum Interrupter (INTERRUPTER)

Since this is an open matter, no full text was included.

1 is a longitudinal cross-sectional view of a seed field application vacuum interrupter according to the present invention.

FIG. 2 is a longitudinal sectional view of the movable composite electrode shown in FIG.

3 is an exploded perspective view of the movable composite electrode shown in FIG.

Claims (24)

A pair of openable contact electrodes, each contact electrode being formed of an arc diffusion portion on a disc and a contact portion protruding on the arc-shaped surface of the arc diffusion portion, and a vacuum container surrounding the contact electrode and having electrical insulation. When the pair of contact electrodes are opened, a vacuum interceptor having a means for applying a magnetic field in the longitudinal direction to the arc formed between these contact electrodes, wherein at least one contact electrode of the pair of contact electrodes is Wherein the arc diffusion portion is made of a material having a% conductivity of 2-30% and the contact portion of the one contact electrode is made of a material having a conductivity of 20-60%. The vacuum interceptor according to claim 1, wherein the arc diffusion portion 20 is formed of 20-70% by weight of copper, 5-40% by weight of iron, and 5-40% by weight of chromium. Characterized by consisting of a metal. The vacuum interceptor according to claim 1, wherein the arc diffusion portion 20 is made of a material containing copper, iron, and chromium, and the contact portion is formed of copper, chromium, and molybdenum. Characterized by consisting of a composite metal. The vacuum interceptor according to claim 3, wherein the arc diffusion unit 20 is made of a material having a% conductivity of 10-15% in IACS. The vacuum interrupter according to claim 3, wherein the contact portion 19 is formed of 20-70% by weight of copper, 5-70% by weight of chromium and 5-70% by weight of molybdenum. Characterized by consisting of metal. The vacuum interceptor according to claim 1, wherein the arc diffusion unit 20 is composed of a composite metal formed of 30-70% by weight of copper and 30-70% by weight of nonmagnetic stainless steel. I did it. The vacuum interceptor according to claim 5, wherein the arc diffusion portion 20 is composed of a composite metal formed of 30-70 wt% copper and 30-70 wt% nonmagnetic stainless steel. Characterized. The vacuum interceptor according to claim 1, wherein the arc diffusion unit 20 is composed of a composite metal formed of 30-70 wt% copper and 30-70 wt% magnetic stainless steel. that. The vacuum interceptor according to claim 8, wherein the arc diffusion unit 20 is composed of a composite metal formed of 30-70 wt% copper and 30-70 wt% ferritic stainless steel. To do. The vacuum interceptor according to claim 8, wherein the arc diffusion unit 20 is composed of a composite metal formed of 30-70 wt% copper 30-70 wt% maltincite stainless steel. To do. It is a vacuum interceptor according to claim 8, wherein the contact portion 19 is a composite metal formed of 20-70% by weight of chromium, 5-70% by weight of chromium and 70% by weight of molybdenum. Characterized in that configured. The vacuum interceptor according to claim 9, wherein the contact portion 19 is formed of 20-70% by weight of copper, 5-70% by weight of chromium and 5-70% by weight of molybdenum. Characterized by consisting of metal. Claim 13 of claim 10, wherein the contactor 19 is a composite metal formed of 20-70% by weight of copper, 5-70% by weight of chromium and 5-70% by weight of molybdenum. Characterized in that consisting of. The vacuum interceptor according to claim 1, wherein the arc diffusion unit 20 has a plurality of holes penetrating the arc diffusion unit 20 in an axial direction with an area occupancy of 10-90%. It is composed of a composite metal formed by copper being infiltrated into the structure of the stainless steel, and the contact portion 19 is formed of 20-70 wt% copper, 5-70 wt% molybdenum and 5-70 wt% chromium. Characterized by consisting of a composite metal. The vacuum interrupter according to claim 1, wherein the arc diffusion portion 20 has a 10-90% area occupancy rate and is formed in the structure of the magnetic stainless steel structure having a plurality of holes penetrating the arc diffusion portion in the axial direction. A composite metal formed by infiltration of copper or silver, wherein the contact portion 19 is formed of 20-70 wt% copper, 5-70 wt% chromium and 5-70 wt% molybdenum Characterized in that consisting of. The vacuum interceptor according to claim 1, wherein the arc diffusion portion is made of austenitic stainless steel having a% conductivity of 2-3%. The vacuum interceptor according to claim 1, wherein the arc diffusion portion is made of ferritic stainless steel having a 5% conductivity of about 2-5%. The vacuum interceptor according to claim 1, wherein the arc diffusion portion is made of maltincite stainless steel having a% conductivity of about 3.0%. The coil electrode 15 and the coil electrode 15 in which the vacuum injector according to claim 1 and the seed field applying means 14 and 15 are provided behind the arc diffusion unit 20. Electrical lead member for the coil electrode which is made of a material having electrical conductivity higher than that of the arc diffusion portion 20 and electrically contacted with the arc diffusion portion 20 and mechanically and electrically front-bonded to the back surface of the arc diffusion portion 20. It is formed by (14). A process in which the arc injector 20 described in claim 1, wherein the arc diffusion unit 20, together with a) at least one metal having a melting point lower than the melting point of copper, is placed in a container with powder of -60 mesh. And b) heating and maintaining the above-described metal powder and the above-mentioned copper wire at a temperature lower than the melting point in the non-proliferation-free atmosphere, and manufacturing a porous base material from the metal powder. And heat-protected and maintained at a temperature lower than the melting point of the porous base material, and the molten copper is infiltrated into the porous base material. The process of placing the powder of at least one metal -60 mesh of the vacuum interceptor according to claim 1, wherein the arc diffusion unit 20 has a melting point lower than that of copper welding; e) heat-protecting the above-described metal powder in a non-oxidizing atmosphere at a temperature lower than the melting point of the metal and manufacturing a porous substrate; f) placing the porous substrate together with the porous substrate obtained in the container; g) It is characterized in that it is manufactured by the process of heating and maintaining the porous substrate and copper plate in the non-oxidation atmosphere at a temperature above the melting point of copper and lower than the melting point of the porous substrate, and immersing the molten copper in the porous substrate. The vacuum injector according to claim 1, wherein the arc diffusion unit 20 press-forms a mixture of -60 meshes of different metal values having a melting point lower than that of copper and copper. And I) sintering the green compact obtained in the non-oxidizing component crisis at a temperature lower than the melting point of the other metals described above. The vacuum interceptor described in claim 1, wherein the arc diffusion unit 20 is composed of a metal having a melting point higher than the melting point of copper in the non-oxidizing component crisis and juxtaposition ( Iii) heating and maintaining the plurality of pipes at a temperature lower than the melting point of the metal and combining them with each other; k) placing the obtained porous substrate and solid copper material together; and l) scattering. It is characterized in that it is manufactured by the process of heating and maintaining the porous base material and the solid copper material at the temperature higher than the melting point of the copper base material and at a temperature lower than the melting point of the porous base material and immersing the molten copper in the porous base material. Scope of claim The copper interceptor described in claim 1, wherein the arc diffusion unit 20 is a copper melting point together with a perforated board and a solid copper material made of a metal having a melting point higher than the melting point of copper. The above is produced by maintaining the heat protection at a temperature lower than the melting point of the metal of the perforated board. ※ Note: It is to be disclosed based on the initial application.