Modeling and validation of residual stresses induced by heat treatment of AA 7075-T6 samples toward the prediction of part distortion

IF 2.7 4区工程技术 Q2 ENGINEERING, MANUFACTURING Machining Science and Technology Pub Date : 2023-05-04 DOI:10.1080/10910344.2023.2215309

Mohamed Ali Louhichi, G. Poulachon, P. Lorong, J. Outeiro, E. Monteiro, D. Cotton

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Abstract

Abstract Residual stresses distributions induced by heat treatment of AA 7075-T6 alloy were modeled and simulated. Models of quenching followed by tempering were developed and simulated using the Finite Element Method (FEM). To determine the convection coefficients used in these models, an inverse method coupled with optimization algorithms was developed. The simulated residual stresses distributions were validated by comparing these stresses with those determined experimentally using layer removal and contour methods. The layer removal method consisting into remove successive layers of material by milling was also modeled and simulated using FEM to predict not only the residual stresses, but also part distortion. The predicted part distortion was close to that measured experimentally, which proves the hypothesis that the residual stresses induced by the layer removal method do not affect part distortion. The contour method was used to validate the residual stresses determined by layer removal, and to evaluate the effects of the temperature gradient on the residual stress distribution.

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AA 7075-T6样品热处理引起的残余应力的建模和验证，用于预测零件变形

对AA 7075-T6合金热处理后的残余应力分布进行了模拟。建立了淬火后回火的有限元模型，并用有限元方法对其进行了模拟。为了确定这些模型中使用的对流系数，开发了一种与优化算法相结合的反演方法。通过将这些应力与使用层去除和轮廓法实验确定的应力进行比较，验证了模拟的残余应力分布。还对通过铣削去除连续材料层的层去除方法进行了建模和模拟，不仅预测了残余应力，还预测了零件变形。预测的零件变形与实验测量的结果接近，证明了层去除方法引起的残余应力不影响零件变形的假设。采用等高线法验证了去除层后确定的残余应力，并评估了温度梯度对残余应力分布的影响。

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来源期刊

Machining Science and Technology 工程技术-材料科学：综合

CiteScore

5.70

自引率

3.70%

发文量

审稿时长

6 months

期刊介绍： Machining Science and Technology publishes original scientific and technical papers and review articles on topics related to traditional and nontraditional machining processes performed on all materials—metals and advanced alloys, polymers, ceramics, composites, and biomaterials. Topics covered include: -machining performance of all materials, including lightweight materials- coated and special cutting tools: design and machining performance evaluation- predictive models for machining performance and optimization, including machining dynamics- measurement and analysis of machined surfaces- sustainable machining: dry, near-dry, or Minimum Quantity Lubrication (MQL) and cryogenic machining processes precision and micro/nano machining- design and implementation of in-process sensors for monitoring and control of machining performance- surface integrity in machining processes, including detection and characterization of machining damage- new and advanced abrasive machining processes: design and performance analysis- cutting fluids and special coolants/lubricants- nontraditional and hybrid machining processes, including EDM, ECM, laser and plasma-assisted machining, waterjet and abrasive waterjet machining