Design and performance study of a bionic damping boring bar based on the woodpecker

IF 5.4 2区工程技术 Q2 ENGINEERING, MANUFACTURING

CIRP Journal of Manufacturing Science and Technology Pub Date : 2025-06-27 DOI:10.1016/j.cirpj.2025.06.011

Jiyuan Tian , Junli Li , Gang Liu , Jing Shi , Yanji Wu

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Abstract

Deep hole machining is a typical challenging process in the aerospace industry, where long overhang boring bars are prone to vibrations, resulting in poor surface quality, reduced tool life, and noise. To address the vibration issues in deep hole machining, this study proposes a bionic damping boring bar inspired by the woodpecker’s shock-absorbing head. The study first analyzes the structure of the woodpecker's head and establishes nonlinear vibration equation, which is solved using the Harmonic Balance Method (HBM). A preliminary bionic design of the boring bar was then proposed, consisting of two main structures: constrained-layer damping (CLD) shaft and bionic absorber. A three-stage biomimetic damping system was developed using metal, particulate materials, damping materials, and carbon fiber reinforced polymer (CFRP). A dynamic model of the boring bar is established to analyze the effect of structural parameters on amplitude response. Subsequently, particle swarm optimization (PSO) and orthogonal experiments are used to optimize the tool body and the bionic absorber. Finally, modal and cutting experiments are conducted, comparing the bionic damping boring bar with carbide boring bars. The results show that the bionic damping boring bar improves modal parameters and cutting stability. Compared to carbide boring bars, it has a 20 % higher natural frequency, 5 times higher damping ratio, and 1.7 times higher stiffness. At the same cutting depth, it provides smoother acceleration amplitude response in the time domain, lower harmonic amplitude in the frequency domain, and improved surface quality, resulting in higher machining accuracy.

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基于啄木鸟的仿生阻尼镗杆设计与性能研究

深孔加工是航空航天工业中一个典型的具有挑战性的加工过程，其中长悬挑镗杆容易振动，导致表面质量差，刀具寿命降低，噪音大。为了解决深孔加工中的振动问题，本研究以啄木鸟的减震头为灵感，提出了一种仿生阻尼镗杆。首先分析了啄木鸟头部的结构，建立了非线性振动方程，并采用谐波平衡法（HBM）对其进行了求解。提出了镗杆的初步仿生设计方案，包括约束层阻尼轴和仿生减振器两个主要结构。以金属、颗粒材料、阻尼材料和碳纤维增强聚合物（CFRP）为材料，研制了一种三级仿生阻尼系统。建立了镗杆的动力学模型，分析了结构参数对振幅响应的影响。随后，采用粒子群算法和正交实验对刀具本体和仿生吸收体进行优化。最后进行了模态试验和切削试验，将仿生阻尼镗杆与硬质合金镗杆进行了对比。结果表明，仿生阻尼镗杆改善了模态参数和切削稳定性。与硬质合金镗杆相比，其固有频率提高20%，阻尼比提高5倍，刚度提高1.7倍。在相同切削深度下，时域加速度幅值响应更平滑，频域谐波幅值更低，表面质量得到改善，加工精度更高。

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

CIRP Journal of Manufacturing Science and Technology Engineering-Industrial and Manufacturing Engineering

CiteScore

9.10

自引率

6.20%

发文量

166

审稿时长

63 days

期刊介绍： The CIRP Journal of Manufacturing Science and Technology (CIRP-JMST) publishes fundamental papers on manufacturing processes, production equipment and automation, product design, manufacturing systems and production organisations up to the level of the production networks, including all the related technical, human and economic factors. Preference is given to contributions describing research results whose feasibility has been demonstrated either in a laboratory or in the industrial praxis. Case studies and review papers on specific issues in manufacturing science and technology are equally encouraged.