KR840005862A - Electrode Material of Vacuum Interverter (INTERRUPTER) and Manufacturing Method Thereof - Google Patents

Abstract

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Description

Electrode Material of Vacuum Interverter (INTERRUPTER) and Manufacturing Method Thereof

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BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a longitudinal sectional view of a vacuum interlater having a pair of electrodes made of an electrode material according to the present invention.

Claims (13)

Electrode material for a vacuum interlater consisting of a composite metal of 20-70% by weight copper, 5-70% by weight morphite and 50-70% by weight chromium. A vacuum substrate made of a porous substrate diffusion-bonded with 5-70% by weight of morphite powder and 5-70% by weight of chromium powder and a composite metal in which 20-70% by weight of copper is infiltrated into the porous substrate. Electrode material. Scope The electrode material of the vacuum interlater according to claim 2, wherein the particle diameter of each metal powder is -100 mesh. Scope A sintered mixture of powdered metals as electrode material for a vacuum interlater according to claim 1. Scope The particle diameter of each metal powder is -100 mesh as an electrode material for a vacuum interlater according to claim 4. Mixing 5-70% by weight of molybdenum powder and 5-70% by weight of chromium having a total weight of 30-80% by weight and mixing in a container that does not react with either morphite, chromium or copper In the process of kidnapping the mixed powder and solid copper material of 20-70% by weight, the mixed powder and the solid copper material are kept at a temperature lower than the melting point of copper for a predetermined time, and the mixed powder is diffused and combined. In the process of manufacturing the porous base material of lyphene and chromium, and in the process of heating the porous material and the solid copper material above the melting point, and maintaining the heating at a temperature lower than the melting point of chromium for a certain time, and immersing molten copper in the porous material And abduction step diffusion bonding step and infiltration step are continuously performed in the same non-oxidizing atmosphere in time. Scope The production method according to claim 6, wherein the non-oxidative component crisis is characterized in that the vacuum of 5 × 10 ^-5 Torr or less. Mixing step in a certain time in the process of mixing 5-70% by weight of morphideden powder and 5-70% by weight of chromium powder, the total amount of 30-80% by weight, and the non-oxidizing atmosphere at a temperature lower than the melting point of chromium 20-70 weight melted in the porous base material obtained by heating and holding process in the same or other non-oxidation atmosphere as the process of heating and holding the mixed powder obtained by the process and manufacturing a porous base material of morphideden and chromium by diffusion bonding. A method for producing an electrode material for a vacuum interlater in a step of infiltrating% copper. Scope 8 The manufacturing method of the base material, the copper infiltration process is a process of placing a fixed copper material adjacent to the porous substrate and the porous substrate and the solid for a predetermined time in a non-oxidizing atmosphere of more than the same melting point and lower than the melting point of chromium Characterized in that it is in the process of heating and maintaining the copper material and infiltrating the molten copper by the porous base material. Scope Non-oxidative component of the copper immersion process in the manufacturing method of claim 9, characterized in that the vacuum of 5 × 10 ^-5 Torr or less. The process of molding the mixed powder obtained by mixing 20-70% by weight of copper powder, 5-70% by weight of morphite powder and 5-70% by weight of chromium powder to the green compact by press molding and chromium A method for producing an electrode material for a vacuum interlater, wherein the green compact obtained by the pressure forming step is sintered in a non-oxidizing component atmosphere at a temperature lower than the melting point of. The temperature of the sintering process is lower than the melting | fusing point of copper, although it is a manufacturing method of the range 11 characterized by the above-mentioned. ※ Note: The disclosure is based on the initial application.