Modeling the Effect of Chemistry Changes on Phase Transformation Timing, Hardness, and Distortion in Carburized 8620 Gear Steel

Heat Treat 2021: Proceedings from the 31st Heat Treating Society Conference and Exposition Pub Date : 2021-09-14 DOI:10.31399/asm.cp.ht2021p0309

Jason Meyer, Stefan Habean, D. Londrico, J. Sims

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Abstract

AISI 8620 low carbon steel is widely used due to its relatively low cost and excellent case hardening properties. The nominal chemistry of AISI 8620 can have a large range, affecting the phase transformation timing and final hardness of a carburized case. Different vendors and different heats of steel can have different chemistries under the same AISI 8620 range which will change the result of a well-established heat treatment process. Modeling the effects of alloy element variation can save countless hours and scrap costs while providing assurance that mechanical requirements are met. The DANTE model was validated using data from a previous publication and was used to study the effect of chemistry variations on hardness and phase transformation timing. Finally, a model of high and low chemistries was executed to observe the changes in hardness, retained austenite and residual stress caused by alloy variation within the validated heat treatment process.

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模拟化学变化对渗碳8620齿轮钢相变时间、硬度和变形的影响

AISI 8620低碳钢由于其相对较低的成本和优异的表面硬化性能而被广泛使用。AISI 8620的标称化学性质可以有很大的变化范围，从而影响渗碳件的相变时间和最终硬度。在相同的AISI 8620范围内，不同的供应商和不同的钢热可能具有不同的化学成分，这将改变既定热处理工艺的结果。对合金元素变化的影响进行建模可以节省无数的时间和废料成本，同时保证满足机械要求。DANTE模型使用先前发表的数据进行了验证，并用于研究化学变化对硬度和相变时间的影响。最后，建立了高、低化学模型，观察了在验证的热处理过程中合金变化引起的硬度、残余奥氏体和残余应力的变化。

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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Heat Treat 2021: Proceedings from the 31st Heat Treating Society Conference and Exposition

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