Spindle unit thermal error modeling and compensation based on digital twin

IF 2.9 3区 工程技术 Q2 AUTOMATION & CONTROL SYSTEMS International Journal of Advanced Manufacturing Technology Pub Date : 2024-03-21 DOI:10.1007/s00170-024-13445-7
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Abstract

The thermal error in the spindle unit is substantial and necessitates mitigation. Current models, being predominantly static in nature, have limited efficacy in error control. Integrating digital twin technology for modeling and controlling spindle unit thermal error holds promise in enhancing the machining accuracy of machine tools. Yet, the notion of a digital twin system specifically tailored for spindle unit thermal characteristics remains uncharted territory. To navigate these challenges, this study introduces a novel digital twin system tailored for spindle unit thermal characteristics. This system is poised to revolutionize thermal error modeling and compensation by harnessing the capabilities of digital twin technology. Within this digital twin framework, both the thermal error control model and the analytical thermal characteristic model are seamlessly integrated. The control model is devised as an exponential function, utilizing operational time, inherent time constants, and both initial and equilibrium thermal errors as parameters. Delving deeper, the analytical thermal characteristic model for the spindle system is rooted in a thermal resistance network approach. This leads to a closed-loop thermal characteristic modeling process, culminating in the derivation of a steady-state thermal error. Intricate heat transfer dynamics between spindle components are dissected, and a comprehensive thermal equilibrium equation set is formulated for the spindle unit. This equation set comprehensively accounts for dynamic variations in key parameters such as preload, lubricant viscosity, thermal load intensity, thermal contact resistance, and convective coefficients. To ascertain the time constant, a meticulously designed set of thermal characteristic experiments is executed. Subsequently, the digital twin system embarks on predictive modeling of thermal errors across varied operational conditions. This prediction then forms the foundation for thermal error compensation. With the integration of the present model into the digital twin system, the results are impressive: the absolute average and maximum deviations in thermal elongation, post-error control, stand at approximately 0.40 μm and 1.24 μm, respectively.

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基于数字孪生的主轴单元热误差建模与补偿
摘要 主轴装置的热误差很大,必须加以缓解。目前的模型主要是静态模型,在误差控制方面效果有限。利用数字孪生技术对主轴单元热误差进行建模和控制,有望提高机床的加工精度。然而,专为主轴单元热特性量身定制的数字孪生系统这一概念仍是未知领域。为了应对这些挑战,本研究介绍了一种专为主轴单元热特性定制的新型数字孪生系统。通过利用数字孪生技术的能力,该系统有望彻底改变热误差建模和补偿。在数字孪生框架内,热误差控制模型和热特性分析模型实现了无缝集成。控制模型设计为指数函数,利用运行时间、固有时间常数以及初始和平衡热误差作为参数。更深入地说,主轴系统的热特性分析模型植根于热阻网络方法。这导致了一个闭环热特性建模过程,最终推导出稳态热误差。对主轴组件之间错综复杂的热传递动力学进行了剖析,并为主轴单元制定了全面的热平衡方程组。该方程组全面考虑了预紧力、润滑油粘度、热负荷强度、热接触电阻和对流系数等关键参数的动态变化。为确定时间常数,执行了一套精心设计的热特性实验。随后,数字孪生系统开始对不同运行条件下的热误差进行预测建模。这种预测为热误差补偿奠定了基础。将本模型集成到数字孪生系统后,结果令人印象深刻:误差控制后,热伸长率的绝对平均偏差和最大偏差分别约为 0.40 μm 和 1.24 μm。
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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.
期刊最新文献
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