TY - JOUR
T1 - Transfer matrix method for linear vibration analysis of flexible multibody systems
AU - Lu, Hanjing
AU - Rui, Xiaoting
AU - Zhang, Xuping
PY - 2023/4/14
Y1 - 2023/4/14
N2 - Achieving high computational efficiency has been well recognized as a research challenge in the vibration analysis of flexible multibody systems. This paper presents a novel transfer matrix method to model and analyze the linear vibration of flexible multibody systems. The transfer equations, the transfer matrices, and the consistency equations of the general flexible body elements with multi-input ends are deduced for the first time. Subsequently, the automatic deduction theorem of the overall transfer equation is developed for flexible multibody systems. Based on the theorem, the overall transfer equation can be deducted automatically and the natural vibration characteristics can be obtained. The dynamic equations and augmented eigenvectors are formulated to solve the forced vibration response. Further, the proposed method is applied to study the dynamics of an ultra-precision machine tool with flexible body elements. The natural vibration characteristics and the forced vibration response are solved and validated with the data from the modal tests and the working conditions. The proposed method has the following advantages: easy deduction of the overall transfer equation, low order of system matrix, and high computational speed.
AB - Achieving high computational efficiency has been well recognized as a research challenge in the vibration analysis of flexible multibody systems. This paper presents a novel transfer matrix method to model and analyze the linear vibration of flexible multibody systems. The transfer equations, the transfer matrices, and the consistency equations of the general flexible body elements with multi-input ends are deduced for the first time. Subsequently, the automatic deduction theorem of the overall transfer equation is developed for flexible multibody systems. Based on the theorem, the overall transfer equation can be deducted automatically and the natural vibration characteristics can be obtained. The dynamic equations and augmented eigenvectors are formulated to solve the forced vibration response. Further, the proposed method is applied to study the dynamics of an ultra-precision machine tool with flexible body elements. The natural vibration characteristics and the forced vibration response are solved and validated with the data from the modal tests and the working conditions. The proposed method has the following advantages: easy deduction of the overall transfer equation, low order of system matrix, and high computational speed.
KW - Flexible body elements
KW - Forced vibration response
KW - Natural vibration characteristics
KW - Transfer matrix method for flexible multibody systems
KW - Ultra-precision machine tool
KW - Vibration analysis
UR - http://www.scopus.com/inward/record.url?scp=85149705524&partnerID=8YFLogxK
U2 - 10.1016/j.jsv.2023.117565
DO - 10.1016/j.jsv.2023.117565
M3 - Journal article
AN - SCOPUS:85149705524
SN - 0022-460X
VL - 549
JO - Journal of Sound and Vibration
JF - Journal of Sound and Vibration
M1 - 117565
ER -