IMPROVING WEAR RESISTANCE BY ELECTROLYTE-PLASMA HARDENING OF CORROSION-RESISTANT STEEL OF THE TIP

Q3 Engineering

Journal of Applied Engineering Science Pub Date : 2023-08-16 DOI:10.5937/jaes0-42291

K. Kombayev, A. Kim, Gulden Sypainova, D. Yelemanov

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引用次数: 0

Abstract

The development of new fields in the oil and gas industry of Kazakhstan, the exploitation of fields with hard-to-recover reserves, and the exclusion of harmful environmental impacts require the study of new advanced technologies in the manufacture of valves. Hardening of the throttle tip in the factory from low-carbon corrosion steel is provided traditionally: carburizing in a solid carburetor, followed by hardening and normalization in an electric furnace. However, this process is accompanied by high heat losses, long time spent on heating and cooling the furnace to the required temperature, and high-energy consumption - power costs are 60-100 kW/h. The carbon penetration rate is low, and for depths of 1-1.5 mm, it becomes necessary to heat the workpiece in a carburetor for 8-10 hours at a certain temperature, followed by hardening and normalization. The technological process of traditional hardening by cementation, followed by hardening and normalization, is accompanied by the appearance of various defects. The most common defects include the formation of microcracks, warpage, scale, and peeling of the metal, as well as high labor intensity and energy intensity. A technology has been developed for hardening the tip on an electrolytic-plasma modification installation, which includes heating the part to 910-9600C and quenching in an electrolyte flow at 330-3600C, characterized in that the part is heated by electrolyte plasma, the temperature of which exceeds 6000 K. Analytically and experimentally it was determined that heating with electrolyte plasma for quenching is achieved within 4 seconds and quenching in the electrolyte flow is achieved within 8 seconds. With cyclic electrolytic plasma hardening at the 10th cycle with 40 seconds of total processing, optimal hardening rates are achieved. An electron microscopic study of the hardened structure indicates a phase transformation and the formation of hardening martensite with a carbide network, which strengthens the steel. The tribological properties and friction coefficient of the surface layers formed during electrolytic-plasma hardening indicate an increase in the wear intensity by more than two times.

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采用电解等离子体硬化技术提高尖端耐腐蚀钢的耐磨性

哈萨克斯坦石油和天然气工业新油田的开发，难以回收储量的油田的开采，以及排除有害的环境影响，都需要研究制造阀门的新的先进技术。节气门尖端在工厂用低碳腐蚀钢进行硬化的传统方法是:在固体化油器中渗碳，然后在电炉中硬化和正火。然而，这一过程伴随着高热损失，加热和冷却炉子到所需温度的时间长，高能耗-电力成本为60-100千瓦/小时。渗碳率低，对于1-1.5 mm的深度，需要在化油器中在一定温度下加热工件8-10小时，然后进行硬化和正火处理。传统的渗胶硬化，再进行硬化和正火的工艺过程，伴随着各种缺陷的出现。最常见的缺陷包括形成微裂纹、翘曲、水垢、金属剥落，以及劳动强度和能量强度高。开发了一种在电解等离子体改性装置上硬化尖端的技术，该技术包括将零件加热到910-9600C，并在330-3600C的电解液流动中淬火，其特点是零件由电解等离子体加热，其温度超过6000 K。通过分析和实验确定，用电解液等离子体加热淬火在4秒内完成，在电解液流动中淬火在8秒内完成。在第10次循环电解等离子体硬化中，总加工时间为40秒，达到了最佳硬化速率。硬化组织的电镜研究表明，相变和硬化马氏体的形成具有碳化物网络，使钢的强度增强。在电解等离子体硬化过程中形成的表层的摩擦学性能和摩擦系数表明，磨损强度增加了两倍以上。

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来源期刊

Journal of Applied Engineering Science Engineering-Engineering (all)

CiteScore

2.00

自引率

0.00%

发文量

122

审稿时长

12 weeks

期刊介绍： Since 2002 iipp build cooperation with its clients established on wealthy experience, interchangeable respect and trust and permanently arrangement with the purpose of successfully realization of projects recognizable according to good organization and high quality of provided favors. Working as unique team of highly motivated experts, Institute iipp provides to its customers the most high-quality solutions in domain of engineering consulting.