Optimized Nitriding for Subsequent Induction Heat Treatment

IF 0.3 Q4 THERMODYNAMICS
S. Hoja, D. Nadolski, M. Steinbacher, R. Fechte-Heinen
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引用次数: 2

Abstract

Abstract Nitriding is used to achieve a high hardness in the surface layer through the precipitation of nitrides. However, to realize high nitriding hardness depths, treatment times of many hours are necessary, which usually also result in a decrease in strength within the nitrided layer and base material. With induction heat treatment, on the other hand, high hardness depths can be achieved in a very short time. However, the maximum hardness increase is limited by the alloy content of the material. By combining nitriding and induction hardening, high hardness depths can be achieved in short treatment times as an alternative to deep nitriding. In addition to a significant saving in process energy surface layer properties that cannot be achieved with the individual processes are expected. In order to fully exploit the potential of the combination treatment, at first suitable conditions must be set during nitriding for the subsequent induction hardening. In the present work, nitriding layers with low-porosity compound layers as well as only diffusion layers were produced and analyzed on typical nitriding and tempering steels for this purpose.
为后续感应热处理优化氮化
渗氮是通过氮化物的析出在表层获得高硬度的方法。然而,为了实现高氮化硬度深度,需要进行长时间的处理,这通常也会导致氮化层和基材内部强度的下降。另一方面,通过感应热处理,可以在很短的时间内获得高硬度深度。然而,最大的硬度增加受限于材料的合金含量。通过结合氮化和感应淬火,可以在短时间内获得高硬度深度,作为深氮化的替代方案。除了显著节省工艺能量外,还期望单个工艺无法实现的表面层特性。为了充分发挥组合处理的潜力,首先必须在渗氮过程中为后续的感应淬火设定合适的条件。本文在典型的渗氮回火钢上制备了含低孔隙率复合渗氮层和纯扩散渗氮层,并进行了分析。
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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来源期刊
CiteScore
1.50
自引率
33.30%
发文量
43
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