Research and process optimization of crankshaft grinding parameters based on Gaussian heat source model

IF 2.9 3区 工程技术 Q2 AUTOMATION & CONTROL SYSTEMS International Journal of Advanced Manufacturing Technology Pub Date : 2024-03-14 DOI:10.1007/s00170-024-13331-2
Siyuan Wang, Qiuyun Mo, Le Li, Yanping Wang, Bin Huang, Kunming Liu
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Abstract

In the grinding process of crankshafts, the grinding parameters were improperly selected, which easily caused the high temperature in the grinding zone and led to burns on the crankshaft journal surface. To address this issue, referencing previous studies, the suitability of the Gaussian heat source model was verified by comparing it with three different heat source models. The Gaussian heat source model was applied to predict the temperature on the surface of the crankshaft connecting rod journal. Transient thermal analysis and investigation of material phase transformation were employed to explore the mechanism of grinding burns. The interaction effects among grinding parameters were analyzed using the Box-Behnken design, and a multiple linear regression equation was established for response surface optimization. The results demonstrated that applying the Gaussian heat source model and response surface optimization yielded the optimal solution, with a maximum deviation of 1.37% between the simulation and optimization results. By selecting a grinding depth (ap) of 0.40 mm, wheel speed (vs) of 40.00 m/s, and feed rate (vx) of 0.036 mm/s as the processing parameters, the temperature in the grinding zone was reduced to 659.37 °C, effectively mitigating grinding burns.

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基于高斯热源模型的曲轴磨削参数研究与工艺优化
在曲轴的磨削过程中,磨削参数选择不当,容易造成磨削区温度过高,导致曲轴轴颈表面烧伤。针对这一问题,参考之前的研究,通过将高斯热源模型与三种不同的热源模型进行比较,验证了高斯热源模型的适用性。高斯热源模型被用于预测曲轴连杆轴颈表面的温度。采用瞬态热分析和材料相变研究来探索磨削烧伤的机理。采用方框-贝肯设计分析了磨削参数之间的交互效应,并建立了响应面优化的多元线性回归方程。结果表明,应用高斯热源模型和响应面优化可获得最优解,模拟结果与优化结果之间的最大偏差为 1.37%。通过选择磨削深度(ap)为 0.40 mm、砂轮速度(vs)为 40.00 m/s、进给速度(vx)为 0.036 mm/s作为加工参数,磨削区的温度降低到 659.37 °C,有效地减轻了磨削烧伤。
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来源期刊
CiteScore
5.70
自引率
17.60%
发文量
2008
审稿时长
62 days
期刊介绍: The International Journal of Advanced Manufacturing Technology bridges the gap between pure research journals and the more practical publications on advanced manufacturing and systems. It therefore provides an outstanding forum for papers covering applications-based research topics relevant to manufacturing processes, machines and process integration.
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