Dynamic disturbance substructuring: identifying localized nonlinear vibrations

M. Brøns; D. J.  Rixen

Dynamic disturbance substructuring: identifying localized nonlinear vibrations

M. Brøns
, D. J. Rixen

Technical University of Munich

Research output: Chapter in Book/Report/Conference proceeding › Article in proceedings › Research › peer-review

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Abstract

In this work, the novel approach Dynamic disturbance (Dydis) substructuring is introduced, and the concept is demonstrated, first on a linear system and then on a simple nonlinear system. Dydis is a means to characterize nonlinear interfaces in complex dynamic engineering structures. It can be any known slight change in the system affecting the vibrational response, as a change in stiffness, mass, inertia, or pre-loading. By measuring the vibrations of systems with and without Dydis, two sets of independent data is obtained, allowing robust estimation of interface dynamics. Nonlinear systems’ natural frequencies are amplitude-dependent. Adding mass will change the frequencies and the forcing level, thus enhancing amplitude-dependent nonlinear effects. This work takes the first steps towards a nonlinear Dydis substructuring approach by applying nonlinear frequency response functions and adapting an estimation procedure to work for a simple nonlinear
case. Results are promising: in a situation polluted by noise, Dydis halves the error compared to not using it.

Original language	English
Title of host publication	Proceedings of 2022 International Conference on Noise and Vibration Engineering (ISMA 2022)
Number of pages	10
Publisher	ISMA
Publication date	2022
Publication status	Published - 2022
Event	2022 International Conference on Noise and Vibration Engineering - Leuven, Belgium Duration: 12 Sept 2022 → 14 Sept 2022

Conference

Conference	2022 International Conference on Noise and Vibration Engineering
Country/Territory	Belgium
City	Leuven
Period	12/09/2022 → 14/09/2022

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@inproceedings{330186e76a7648dfaabeb6ac549dddca,

title = "Dynamic disturbance substructuring: identifying localized nonlinear vibrations",

abstract = "In this work, the novel approach Dynamic disturbance (Dydis) substructuring is introduced, and the concept is demonstrated, first on a linear system and then on a simple nonlinear system. Dydis is a means to characterize nonlinear interfaces in complex dynamic engineering structures. It can be any known slight change in the system affecting the vibrational response, as a change in stiffness, mass, inertia, or pre-loading. By measuring the vibrations of systems with and without Dydis, two sets of independent data is obtained, allowing robust estimation of interface dynamics. Nonlinear systems{\textquoteright} natural frequencies are amplitude-dependent. Adding mass will change the frequencies and the forcing level, thus enhancing amplitude-dependent nonlinear effects. This work takes the first steps towards a nonlinear Dydis substructuring approach by applying nonlinear frequency response functions and adapting an estimation procedure to work for a simple nonlinear case. Results are promising: in a situation polluted by noise, Dydis halves the error compared to not using it.",

author = "M. Br{\o}ns and Rixen, \{D. J.\}",

year = "2022",

language = "English",

booktitle = "Proceedings of 2022 International Conference on Noise and Vibration Engineering (ISMA 2022)",

publisher = "ISMA",

note = "2022 International Conference on Noise and Vibration Engineering, ISMA 2022 ; Conference date: 12-09-2022 Through 14-09-2022",

}

TY - GEN

T1 - Dynamic disturbance substructuring: identifying localized nonlinear vibrations

AU - Brøns, M.

AU - Rixen, D. J.

PY - 2022

Y1 - 2022

N2 - In this work, the novel approach Dynamic disturbance (Dydis) substructuring is introduced, and the concept is demonstrated, first on a linear system and then on a simple nonlinear system. Dydis is a means to characterize nonlinear interfaces in complex dynamic engineering structures. It can be any known slight change in the system affecting the vibrational response, as a change in stiffness, mass, inertia, or pre-loading. By measuring the vibrations of systems with and without Dydis, two sets of independent data is obtained, allowing robust estimation of interface dynamics. Nonlinear systems’ natural frequencies are amplitude-dependent. Adding mass will change the frequencies and the forcing level, thus enhancing amplitude-dependent nonlinear effects. This work takes the first steps towards a nonlinear Dydis substructuring approach by applying nonlinear frequency response functions and adapting an estimation procedure to work for a simple nonlinear case. Results are promising: in a situation polluted by noise, Dydis halves the error compared to not using it.

AB - In this work, the novel approach Dynamic disturbance (Dydis) substructuring is introduced, and the concept is demonstrated, first on a linear system and then on a simple nonlinear system. Dydis is a means to characterize nonlinear interfaces in complex dynamic engineering structures. It can be any known slight change in the system affecting the vibrational response, as a change in stiffness, mass, inertia, or pre-loading. By measuring the vibrations of systems with and without Dydis, two sets of independent data is obtained, allowing robust estimation of interface dynamics. Nonlinear systems’ natural frequencies are amplitude-dependent. Adding mass will change the frequencies and the forcing level, thus enhancing amplitude-dependent nonlinear effects. This work takes the first steps towards a nonlinear Dydis substructuring approach by applying nonlinear frequency response functions and adapting an estimation procedure to work for a simple nonlinear case. Results are promising: in a situation polluted by noise, Dydis halves the error compared to not using it.

M3 - Article in proceedings

BT - Proceedings of 2022 International Conference on Noise and Vibration Engineering (ISMA 2022)

PB - ISMA

T2 - 2022 International Conference on Noise and Vibration Engineering

Y2 - 12 September 2022 through 14 September 2022

ER -

Dynamic disturbance substructuring: identifying localized nonlinear vibrations

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