Hybrid multibody system method for the dynamic analysis of an ultra-precision fly-cutting machine tool

IF 3.4 Q1 ENGINEERING, MECHANICAL 国际机械系统动力学学报(英文) Pub Date : 2022-10-20 DOI:10.1002/msd2.12051
Hanjing Lu, Xiaoting Rui, Ziyao Ma, Yuanyuan Ding, Yiheng Chen, Yu Chang, Xuping Zhang
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引用次数: 4

Abstract

The dynamics of an ultra-precision machine tool determines the precision of the machined surface. This study aims to propose an effective method to model and analyze the dynamics of an ultra-precision fly-cutting machine tool. First, the dynamic model of the machine tool considering the deformations of the cutter head and the lathe head is developed. Then, the mechanical elements are classified into M subsystems and F subsystems according to their properties and connections. The M-subsystem equations are formulated using the transfer matrix method for multibody systems (MSTMM), and the F-subsystem equations are analyzed using the finite element method and the Craig–Bampton reduction method. Furthermore, all the subsystems are assembled by combining the restriction equations at connection points among the subsystems to obtain the overall transfer equation of the machine tool system. Finally, the vibration characteristics of the machine tool are evaluated numerically and are validated experimentally. The proposed modeling and analysis method preserves the advantages of the MSTMM, such as high computational efficiency, low computational load, systematic reduction of the overall transfer equation, and generalization of its computational capability to general flexible-body elements. In addition, this study provides theoretical insights and guidance for the design of ultra-precision machine tools.

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超精密飞切机床动力学分析的混合多体系统方法
超精密机床的动力学特性决定了加工表面的精度。本研究旨在提出一种有效的方法来建模和分析超精密飞切机床的动力学。首先,建立了考虑刀头和车床刀头变形的机床动力学模型;然后,根据机械元件的性质和联系将其分为M子系统和F子系统。采用多体系统传递矩阵法(MSTMM)建立了m -子系统方程,采用有限元法和Craig-Bampton约简法对f -子系统方程进行了分析。将各子系统连接点处的约束方程组合起来,得到机床系统的整体传递方程。最后,对机床的振动特性进行了数值计算和实验验证。所提出的建模和分析方法保留了MSTMM的计算效率高、计算量小、系统地简化了整体传递方程以及将其计算能力推广到一般柔体单元等优点。此外,该研究为超精密机床的设计提供了理论见解和指导。
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Issue Information Cover Image, Volume 4, Number 3, September 2024 Design of bionic water jet thruster with double-chamber driven by electromagnetic force A data-assisted physics-informed neural network (DA-PINN) for fretting fatigue lifetime prediction Comparison of the performance and dynamics of the asymmetric single-sided and symmetric double-sided vibro-impact nonlinear energy sinks with optimized designs
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