A. V. Serov, R. A. Latypov, P. I. Burak, N. V. Serov
{"title":"功能涂层电接触焊接工艺流程:第2部分","authors":"A. V. Serov, R. A. Latypov, P. I. Burak, N. V. Serov","doi":"10.1134/S0036029525700983","DOIUrl":null,"url":null,"abstract":"<p><b>Abstract</b>—Electrocontact welding (ECW) is a promising resource-saving technology for producing functional coatings from waste materials in tool and machine-building production. A clear technique is necessary for choosing materials, equipment, and tools, the sequence and description of operations, and technological parameters (modes) that influence the properties and quality of the coatings produced by this method. To develop a technique for producing, strengthening, and restoring machine parts, functional ECW coatings are studied using a 011-1-10 Remdetal setup. The welding pulse and pause durations are set using an RVI-501 controller. The welding current is calibrated using a 5-mm-thick MM copper strip and an IST-02 welding current meter. An analysis of the electrical resistance of the ECW joint zone shows that the optimum compression force of welding electrodes on a 65G steel plowshare is 1.7 kN for a U12 steel tape. To ensure the maximum process efficiency and complete overlap of weld spots (accounting for the relative movement of electrodes and the part), dependences are derived to determine the following main ECW parameters for all schemes and equipment options: welding current, pulse duration and pause time, electrode compression force, welding speed, weld spot overlap coefficients, and cooling fluid flow rate. Their influence on the process and the coating quality is discussed. The proposed algorithm for calculating and setting welding parameters simplifies the application of the technology and improves the coating quality by minimizing defects caused by parameter errors. The algorithm can be used in machine-building and repair production for designing processes to produce functional coatings for hardening and restoring machine parts.</p>","PeriodicalId":769,"journal":{"name":"Russian Metallurgy (Metally)","volume":"2025 1","pages":"180 - 185"},"PeriodicalIF":0.3000,"publicationDate":"2025-08-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Technological Processes of the Electrocontact Welding of Functional Coatings: Part 2\",\"authors\":\"A. V. Serov, R. A. Latypov, P. I. Burak, N. V. Serov\",\"doi\":\"10.1134/S0036029525700983\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><b>Abstract</b>—Electrocontact welding (ECW) is a promising resource-saving technology for producing functional coatings from waste materials in tool and machine-building production. A clear technique is necessary for choosing materials, equipment, and tools, the sequence and description of operations, and technological parameters (modes) that influence the properties and quality of the coatings produced by this method. To develop a technique for producing, strengthening, and restoring machine parts, functional ECW coatings are studied using a 011-1-10 Remdetal setup. The welding pulse and pause durations are set using an RVI-501 controller. The welding current is calibrated using a 5-mm-thick MM copper strip and an IST-02 welding current meter. An analysis of the electrical resistance of the ECW joint zone shows that the optimum compression force of welding electrodes on a 65G steel plowshare is 1.7 kN for a U12 steel tape. To ensure the maximum process efficiency and complete overlap of weld spots (accounting for the relative movement of electrodes and the part), dependences are derived to determine the following main ECW parameters for all schemes and equipment options: welding current, pulse duration and pause time, electrode compression force, welding speed, weld spot overlap coefficients, and cooling fluid flow rate. Their influence on the process and the coating quality is discussed. The proposed algorithm for calculating and setting welding parameters simplifies the application of the technology and improves the coating quality by minimizing defects caused by parameter errors. 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Technological Processes of the Electrocontact Welding of Functional Coatings: Part 2
Abstract—Electrocontact welding (ECW) is a promising resource-saving technology for producing functional coatings from waste materials in tool and machine-building production. A clear technique is necessary for choosing materials, equipment, and tools, the sequence and description of operations, and technological parameters (modes) that influence the properties and quality of the coatings produced by this method. To develop a technique for producing, strengthening, and restoring machine parts, functional ECW coatings are studied using a 011-1-10 Remdetal setup. The welding pulse and pause durations are set using an RVI-501 controller. The welding current is calibrated using a 5-mm-thick MM copper strip and an IST-02 welding current meter. An analysis of the electrical resistance of the ECW joint zone shows that the optimum compression force of welding electrodes on a 65G steel plowshare is 1.7 kN for a U12 steel tape. To ensure the maximum process efficiency and complete overlap of weld spots (accounting for the relative movement of electrodes and the part), dependences are derived to determine the following main ECW parameters for all schemes and equipment options: welding current, pulse duration and pause time, electrode compression force, welding speed, weld spot overlap coefficients, and cooling fluid flow rate. Their influence on the process and the coating quality is discussed. The proposed algorithm for calculating and setting welding parameters simplifies the application of the technology and improves the coating quality by minimizing defects caused by parameter errors. The algorithm can be used in machine-building and repair production for designing processes to produce functional coatings for hardening and restoring machine parts.
期刊介绍:
Russian Metallurgy (Metally) publishes results of original experimental and theoretical research in the form of reviews and regular articles devoted to topical problems of metallurgy, physical metallurgy, and treatment of ferrous, nonferrous, rare, and other metals and alloys, intermetallic compounds, and metallic composite materials. The journal focuses on physicochemical properties of metallurgical materials (ores, slags, matters, and melts of metals and alloys); physicochemical processes (thermodynamics and kinetics of pyrometallurgical, hydrometallurgical, electrochemical, and other processes); theoretical metallurgy; metal forming; thermoplastic and thermochemical treatment; computation and experimental determination of phase diagrams and thermokinetic diagrams; mechanisms and kinetics of phase transitions in metallic materials; relations between the chemical composition, phase and structural states of materials and their physicochemical and service properties; interaction between metallic materials and external media; and effects of radiation on these materials.