电极材料性质对掺杂层腐蚀和性能的影响。电火花合金化有效性评价标准

A. D. Verkhoturov, V. Ivanov, A. Dorokhov, L. Konevtsov, S. Velichko
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引用次数: 21

摘要

介绍。电火花合金化金属表面的方法是由俄罗斯科学家拉扎连科和拉扎连科提出的。可以将该工艺应用于工件表面的任何导电材料的硬化合金层材料,以确保零件执行表面的高硬度,耐热性,耐磨性等性能。本文表明,根据d元素在元素周期表中的位置和电极材料的(s+d)电子数确定d元素的性质,有可能制定确定电火花合金化过程效率和掺杂层性质的准则。确定性能标准的类似方法可推荐用于其他高能材料暴露工艺。材料和Мethods。采用45钢作为边缘型材的材料和IV-VI族难熔d金属:Ti、V、Cr、Zr、Nb、Vo、Hf、Ta、W;_ также d金属:Mn, Fe, Co, Ni, Cu, Zn, Pd, Ag, Cd, Re, Os, Ir, Pt, Au和p金属:Al, Bi, Sb, Sn, Pb作为制造掺杂层的阳极材料。电火花合金化使用的装置:EFI-10M, EFI-46A, EFI-25M, EFI-66, Electrom-10, ELFA-541, Elitron-22, IMEI-01-2A;电晕- 1101;显微镜MII-4, MIM-10, BIOLAM-M, EMA-100, Axiosplan-2;P-201“口径”分析器;微测温仪PMT-3M, DUH-W201,岛津在腐蚀的研究中,我们使用了安装“阿托维奇吸收分光光度计,瓦里安AA-4”。采用GOS-3OM发生器和SLS-10-1装置进行激光加工。对模型阳极材料单次暴露和多次暴露的电火花合金化工艺方案进行了推广。在阴极处有一个不同程度填充阴极材料的孔或代表阳极材料和阴极相互结晶的区域。当暴露于气体介质中的火花放电时,由于腐蚀物质更强烈地转移到相反的电极,特别是阴极,因此在形成孔方面存在差异。本文给出了难熔d金属的显微硬度、熔点、弹性模量等性质与它们在元素周期表上的位置的关系。根据d元素在元素周期表中的位置,建立了d元素在电火花合金中的尺寸和体积关系。模型电极材料的性质依赖于原子稳定构型的统计重量,以及过渡金属阳极的侵蚀依赖于(s+d)-电子数和电极间介质。发现了d金属在电火花合金化和其他类型的高能冲击下对表面的侵蚀模式。结论。基于本研究结果,可以说明为了获得更高的涂层性能和更高的电火花合金化效率,有必要优先考虑具有最大原子稳定构型统计重量的阳极材料。可以说,电极材料的性能与电火花合金化过程中其腐蚀量和形成掺杂层效率参数有关,具体条件下,这些参数是通过选择比值的方法以及与先前建立的依赖关系的定量实验数据的比较来确定的。有可能采用一种共同的方法来制定通过高能撞击赋予材料新特性的标准。提出了一种假设,用于确定d元素的物理和操作性质对其在元素周期表中的位置的类似变化依赖关系,以及各种局部高能撞击方法的原子稳定构型的统计权重。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effect of the Nature of Electrode Materials on Erosion and Properties of Doped Layers. The Criteria for Evaluating the Effectiveness of Electrospark Alloying
Introduction. The method of electrospark alloying of metal surfaces was proposed by the Russian scientists B. R. Lazarenko and N. I. Lazarenko. It is possible to apply this process to the surface of the workpiece from any conductive materials of a hardened alloyed layer of material to ensure high hardness, heat resistance, wear resistance and other properties of the executive surfaces of the parts. The paper shows the possibility of formulating criteria for determining the efficiency of the electrospark alloying process and the properties of the doped layer, depending on the properties of d-elements determined by their position in the periodic table and a number of (s+d)-electrons of electrode materials. A similar approach to determining performance criteria can be recommended for other high-energy materials exposure processes. Materials and Мethods. The authors used steel 45 as the material of the rim sections and refractory d-metals of IV-VI groups: Ti, V, Cr, Zr, Nb, Vo, Hf, Ta, W; а также d-metals: Mn, Fe, Co, Ni, Cu, Zn, Pd, Ag, Cd, Re, Os, Ir, Pt, Au and p-metals: Al, Bi, Sb, Sn, Pb as anode materials for creating doped layers. The installations used for electric-spark alloying: EFI-10M, EFI-46A, EFI-25M, EFI-66, Electrom-10, ELFA-541, Elitron-22, IMEI-01-2A; Corona- 1101; microscope MII-4, MIM-10, BIOLAM-M, EMA-100, Axiosplan-2; Profiler P-201 “Caliber”; microthermometry PMT-3M, DUH-W201, Shimadzu. In the study of erosion there we used the installation of “Atovic absorption spectrophotometer, Varian AA-4”. The generator GOS-3OM and installation SLS-10-1 wer used for laser processing. Results. The generalization of the schemes of the process of electric-spark alloying in single and repeated exposure of the model anode material was made. At the cathode there is a hole with a different degree of filling of the cathode material or representing the zone of mutual crystallization of the anode material and the cathode. When exposed to spark discharge in a gaseous medium, there are differences in the formation of holes due to the more intense transfer of eroded material to the opposite electrode, especially to the cathode. Dependences of some properties (microhardness, melting point, elastic modulus) of refractory d-metals on their location in the IV–VI periods of the periodic table are obtained and presented. Dimensional and volumetric relations of d-elements in electrospark alloying were established, depending on their location in the periodic table. Dependences of the properties of model electrode materials on the statistical weight of atomic stable configurations, as well as the dependence of the erosion of the anode of transition metals on the number (s+d)- electrons and the interelectrode medium. The patterns of d-metals erosion under electrospark alloying and other types of high-energy impact to the surface have been found. Conclusions. Based on the results of this research, it can be stated that in order to achieve higher coating properties and greater efficiency of electrospark alloying, it is necessary to give preference to anodic materials having the maximum statistical weight of atomic stable configurations. It can be said that the properties of the electrode materials relate to their erosion amount and the parameters of the efficiency for forming the doped layer during electrospark alloying, which for specific conditions are determined by the method of selection of ratios and comparison with quantitative experimental data of previously established dependencies. A common approach to the formulation of criteria for imparting new properties to materials by high-energy impacting on them is possible. There is formulated a hypothesis for determining similar change dependences of the physical and operational properties of d-elements on their location in the periodic Table and the statistical weight of atomic stable configuration for various methods of local high-energy impact.
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Mordovia University Bulletin
Mordovia University Bulletin MULTIDISCIPLINARY SCIENCES-
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