Milling Chatter Recognition Based on Dynamic and Wavelet Packet Decomposition

doi:10.12422/j.issn.1672-6952.2023.06.012

Journal of Liaoning Petrochemical University ›› 2023, Vol. 43 ›› Issue (6): 75-81.DOI: 10.12422/j.issn.1672-6952.2023.06.012

• Mechanical Engineering • Previous Articles Next Articles

Milling Chatter Recognition Based on Dynamic and Wavelet Packet Decomposition

Chunyu ZHANG¹(), Changfu LIU¹, Xiaodan ZHU¹(), Xinli YU¹, Xingchen LUO¹, Tianhao LU¹, Bingjie LI²

^1.School of Mechanical Engineering，Liaoning Petrochemical University，Fushun Liaoning 113001，China
^2.School of Artificial Intelligence and Software，Liaoning Petrochemical University，Fushun Liaoning 113001，China

Received:2022-07-01 Revised:2022-12-25 Online:2023-12-25 Published:2023-12-30
Contact: Xiaodan ZHU

基于动态特性和小波包的铣削颤振识别

张春雨¹(), 刘长福¹, 朱晓丹¹(), 于新丽¹, 罗星辰¹, 陆天昊¹, 李冰杰²

^1.辽宁石油化工大学机械工程学院，辽宁抚顺 113001
^2.辽宁石油化工大学人工智能与软件学院，辽宁抚顺 113001

通讯作者: 朱晓丹
作者简介:张春雨（2000⁃），男，本科生，机械设计制造及其自动化专业，从事信号处理方面的研究；E⁃mail：2680453250@qq.com。
基金资助:
辽宁省自然科学计划（博士启动）项目(2022?BS?293);辽宁石油化工大学科研启动基金项目(2021XJJL?005);辽宁省大学生创新创业训练计划项目(202110148017)

Abstract

Abstract:

In the process of metal milling, especially in the machining of low?stiffness workpieces, chatter is a key factor affecting many aspects such as surface quality, machining efficiency and tool life. In order to avoid the chatter, a milling chatter recognition method based on dynamic and Wavelet Packet Decomposition(WPD) is proposed from the signal processing. The modal parameters of the system are obtained by modal experiments. Based on the principle that the chatter frequency will peak near the natural frequency of the system, the original milling force signal is decomposed by WPD, and the sub?signals containing rich chatter information are selected for signal reconstruction. Finally, the time?frequency and Hilbert spectrum characteristics of the reconstructed signal are compared and analysed, and the chatter recognition is performed. At last, the proposed method is verified by the experiments. The results demonstrate the effectiveness and reliability of the proposed method.

Key words: Chatter recognition, Wavelet Packet Decomposition, Dynamic, Signal reconstruction, Time frequency analysis

摘要：

在金属铣削尤其是低刚度工件加工过程中，颤振是影响工件表面质量、加工效率和刀具寿命等的关键因素。为了避免加工产生的颤振，从信号处理的角度出发，提出了一种基于系统动态特性和小波包的铣削颤振识别方法。通过模态实验获取系统的模态参数，依据颤振频率在系统固有频率附近会出现峰值的特点，采用小波包对原始切削力信号进行分解，然后选取包含丰富颤振信息的频段进行重构，最后对比和分析铣削力信号时频谱图和希尔伯特频谱，实现颤振识别，并对所提出的方法进行了实验验证。结果表明，所提出的方法具有有效性和可靠性。

关键词: 颤振监测, 小波包分解, 动态特性, 信号重构, 时频分析

CLC Number:

TH17

Chunyu ZHANG, Changfu LIU, Xiaodan ZHU, Xinli YU, Xingchen LUO, Tianhao LU, Bingjie LI. Milling Chatter Recognition Based on Dynamic and Wavelet Packet Decomposition[J]. Journal of Liaoning Petrochemical University, 2023, 43(6): 75-81.

张春雨, 刘长福, 朱晓丹, 于新丽, 罗星辰, 陆天昊, 李冰杰. 基于动态特性和小波包的铣削颤振识别[J]. 辽宁石油化工大学学报, 2023, 43(6): 75-81.

Figures/Tables 11

References 21

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元素	质量分数/%	元素	质量分数/%
Cu	0.15～0.40	Mg	0.80～1.20
Si	0.40～0.80	Zn	0.25
Fe	0.70	Cr	0.04～0.35
Mn	0.15	Ti	0.15

元素	质量分数/%	元素	质量分数/%
Cu	0.15～0.40	Mg	0.80～1.20
Si	0.40～0.80	Zn	0.25
Fe	0.70	Cr	0.04～0.35
Mn	0.15	Ti	0.15

模态参数	数值
模态参数	x方向	y方向
一阶固有频率/Hz	1 100.0	1 119.0
一阶刚度×10^－7/(N·m^－1)	1.799 5	2.180 8
一阶阻尼比×10²	4.77	3.64
二阶固有频率/Hz	1 880.0	1 889.0
二阶刚度×10^－7/(N·m^－1)	5.710 4	9.253 0
二阶阻尼比×10²	3.99	2.65

模态参数	数值
模态参数	x方向	y方向
一阶固有频率/Hz	1 100.0	1 119.0
一阶刚度×10^－7/(N·m^－1)	1.799 5	2.180 8
一阶阻尼比×10²	4.77	3.64
二阶固有频率/Hz	1 880.0	1 889.0
二阶刚度×10^－7/(N·m^－1)	5.710 4	9.253 0
二阶阻尼比×10²	3.99	2.65

模态参数	数值
一阶固有频率/Hz	415.0
一阶刚度×10^－6/( N·m^－1)	2.159 2
一阶阻尼比×10²	3.73

Milling Chatter Recognition Based on Dynamic and Wavelet Packet Decomposition

基于动态特性和小波包的铣削颤振识别

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References 21

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