Quench hardening of 0·4%C steel using aqueous electrolyte plasma as heat source

Roy A.; Parihar S.J.; Singh A.; Sharma R.C.; Shekhar R.

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Quench hardening of 0·4%C steel using aqueous electrolyte plasma as heat source

机译：以水电解质等离子体为热源对0·4％C钢进行淬火淬火

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Quench hardening of 0·4%C steel has been achieved using aqueous electrolyte plasma as heat source. Cylindrical specimens (8 mm diameter) of 0·4%C steel (cathode) were placed at the centre of a cylindrical stainless steel ring of 100 mm diameter (anode) in 15 wt-%Na₂CO₃ aqueous solution. Continuous electrolyte plasma was generated by electrical discharge at voltages higher than ∼90 V in a narrow layer at the specimen (cathode) surface. The aqueous electrolyte plasma caused rapid heating of the active electrode (cathode) to 900-1200°C in few seconds at applied voltages in the range of 95-140 V. On subsequent rapid cooling, the steel specimen transformed to martensite structure. The process can be adopted for surface modification techniques such as nitriding and carburising. Feasibility of anodising using this technique may also be explored.

机译：使用含水电解质等离子体作为热源已经实现了0·4％C钢的淬火硬化。在15 wt％Na _{2 CO中，将0·4％C钢（阴极）的圆柱形试样（直径8 mm）放置在直径为100 mm（阳极）的圆柱形不锈钢环的中心。 _{3 水溶液。通过在高于90 V的电压下在样品（阴极）表面的狭窄层中放电产生连续的电解质等离子体。在施加的电压为95-140 V的范围内，水性电解质等离子体导致活性电极（阴极）在数秒内迅速加热至900-1200°C。随后的快速冷却，使钢试样转变为马氏体结构。该工艺可用于表面改性技术，例如氮化和渗碳。也可以探索使用这种技术进行阳极氧化的可行性。}}

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《Surface Engineering 》 |2009年第6期| 423-429| 共7页
作者
Roy A.; Parihar S.J.; Singh A.; Sharma R.C.; Shekhar R.;
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Department of Materials and Metallurgical Engineering, Indian Institute of Technology, Kanpur, Uttar Pradesh, India;

Department of Materials and Metallurgical Engineering, Indian Institute of Technology, Kanpur, Uttar Pradesh, India;

Department of Materials and Metallurgical Engineering, Indian Institute of Technology, Kanpur, Uttar Pradesh, India;

Department of Materials and Metallurgical Engineering, Indian Institute of Technology, Kanpur, Uttar Pradesh, India;

Department of Materials and Metallurgical Engineering, Indian Institute of Technology, Kanpur, Uttar Pradesh, India;

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1. Quench hardening of 0.4 percent C steel using aqueous electrolyte plasma as heat source [J] . A. Roy, S. J. Parihar, A. Singh Surface Engineering . 2009 ,第6期

机译：使用含水电解质等离子体作为热源的0.4％C钢的淬火硬化
2. Quench hardening of 0.4%C steel using aqueous electrolyte plasma as heat source [J] . A. Roy, S. J. Parihar, A. Singh Surface Engineering . 2009 ,第6期

机译：使用含水电解质等离子体作为热源的0.4％C钢的淬火硬化
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机译：回火热处理对用于石油和天然气的淬火Cr-Mo低合金钢的CO_2耐腐蚀性的影响
4. Surface Hardening of 18CrNi3MoA-SH Steel with Heating in Electrolytic Plasma [C] . Mazhyn Skakov, Lyaila Bayatanova, Michael Sheffler International conference on materials science and nanotechnology . 2013

机译：18crni3moa-sh钢的表面硬化，电解质等离子体加热
5. Laser quench hardening of steel: Effects of superimposed elastic pre-stress on the hardness and residual stress distribution. [D] . Meserve, Justin. 2013

机译：钢的激光淬火硬化：叠加的弹性预应力对硬度和残余应力分布的影响。
6. Effect of Grain Size on the Microstructure and Strain Hardening Behavior of Solution Heat-Treated Low-C High-Mn Steel [O] . Marek Opiela, Gabriela Fojt-Dymara, Adam Grajcar, 2020

机译：晶粒尺寸对固溶热处理低碳高锰钢的组织和应变硬化行为的影响
7. The cathodic electrolytic plasma hardening of the 20Cr2Ni4A chromium-nickel steel [O] . Bauyrzhan K. Rakhadilov, Vladimir V. Buranich, Zarina A. Satbayeva, 2020

机译：20Cr2NI4A铬镍钢的阴极电解质等离子体硬化

Quench hardening of 0·4%C steel using aqueous electrolyte plasma as heat source

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