Experimental and Numerical Investigation of the Surface Layer Conditions after Carbonitriding of Powder Metallurgical Steels. Part 1: Diffusion in Components of Graded Porosity

IF 0.3 Q4 THERMODYNAMICS HTM-Journal of Heat Treatment and Materials Pub Date : 2021-02-01 DOI:10.1515/htm-2020-0003
J. Damon, H. Surm, P. Saddei, S. Dietrich, V. Schulze
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引用次数: 2

Abstract

Abstract Case hardening processes such as carbonitriding can be used to improve the performance of powder metallurgical structural components. Due to the amount of carbon and nitrogen introduced, it is possible to adjust the hardness and residual stress of the surface layer. Due to their porosity, powder metallurgical components show a significantly increased diffusivity and therefore increased demands on the process control. In order to be able to make a quantitative statement about the effects of diffusivity as a function of porosity, common densities of 6.9 g/cm3, 7.2 g/cm3and 7.35 g/cm3for PM-steel are examined in a total of ten process sequences. By means of simulative approaches, the resulting element depth profiles can be calculated and the surface layer condition can be predicted by a subsequent heat treatment simulation. In a two-part work, the mass transport during carbonitriding is investigated in the first part and the resulting surface layer conditions after heat treatment in the second part. By considering different process combinations and porosities, model approaches of volume and pore diffusion can be formulated and quantitative element depth profiles can be predicted and validated depending on the process parameters. ◼
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粉末冶金钢碳氮共渗后表层状况的实验与数值研究。第1部分:梯度孔隙度组分中的扩散
采用渗碳等淬火工艺可提高粉末冶金组织件的性能。由于碳和氮的引入量,可以调节表层的硬度和残余应力。由于其多孔性,粉末冶金成分的扩散性显著增加,因此对过程控制的要求也增加了。为了能够定量地说明扩散率作为孔隙率的函数的影响,pm钢的常见密度为6.9 g/cm3, 7.2 g/cm3和7.35 g/cm3,在总共十个工艺序列中进行了测试。通过模拟方法,可以计算得到的元件深度分布图,并通过随后的热处理模拟来预测表面层的状况。在两部分的工作中,第一部分研究了碳氮共渗过程中的质量输运,第二部分研究了热处理后产生的表面层状况。通过考虑不同的工艺组合和孔隙率,可以建立体积和孔隙扩散的模型方法,并可以根据工艺参数预测和验证定量单元深度剖面。◼
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.50
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33.30%
发文量
43
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