Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen

L. Panning; M. Kröger; J. Wallaschek

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Titel in Übersetzung	Vibration damping by friction forces: Theory, experiment, applications
Originalsprache	Deutsch
Titel des Sammelwerks	Schwingungsdämpfung
Untertitel	Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen
Seiten	71-95
Seitenumfang	25
Publikationsstatus	Veröffentlicht - 2007
Veranstaltung	Schwingungsdämpfung - Wiesloch, Deutschland Dauer: 16 Okt. 2007 → 17 Okt. 2007

Publikationsreihe

Name	VDI Berichte
Nummer	2003
ISSN (Print)	0083-5560

Abstract

In many technical applications, structures are assembled by a large number of substructures, parts and linear or non-linear connecting elements such as springs, dampers or active elements. While the resulting stiffness and inertia properties of interconnected parts may be predicted with sufficient accuracy, the evaluation of the damping amount and, thus, the vibration amplitude of structures subjected to external loads is a complicated, elaborate and time-consuming task. The existing friction interfaces, e.g. in flange or bolt connections, can be utilized to provide a significant amount of damping due to energy dissipation caused by microslip or macroscopic relative displacements between the contacting bodies. By designing these interconnections accurately or, alternatively, creating additional friction contacts, the damping can be increased remarkably, affecting the vibration amplitudes, reliability and lifetime of a structure. Starting with the theoretical background of existing contact models and solution techniques for non-linear differential equations with friction forces, a systematic procedure for designing friction interfaces in order to maximize the damping is presented. The influence on the structural stiffness and the expected damping ratio will be discussed. The developed theoretical models are accompanied by experimental tests at different sample structures with friction contacts to show the great potential of friction damping. Beam structures, space structures, turbine blades and combustion engines will serve as examples of the variety of different technical applications where friction damping can be used successfully to reduce vibration amplitudes.

ASJC Scopus Sachgebiete

Ingenieurwesen (insg.)
Allgemeiner Maschinenbau

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Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen. / Panning, L.; Kröger, M.; Wallaschek, J.
Schwingungsdämpfung: Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen. 2007. S. 71-95 (VDI Berichte; Nr. 2003).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/Konferenzband › Beitrag in Buch/Sammelwerk › Forschung › Peer-Review

Panning, L, Kröger, M & Wallaschek, J 2007, Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen. in Schwingungsdämpfung: Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen. VDI Berichte, Nr. 2003, S. 71-95, Schwingungsdämpfung, Wiesloch, Deutschland, 16 Okt. 2007.

Panning, L., Kröger, M., & Wallaschek, J. (2007). Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen. In Schwingungsdämpfung: Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen (S. 71-95). (VDI Berichte; Nr. 2003).

Panning L, Kröger M, Wallaschek J. Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen. in Schwingungsdämpfung: Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen. 2007. S. 71-95. (VDI Berichte; 2003).

Panning, L. ; Kröger, M. ; Wallaschek, J. / Schwingungsdämpfung Durch Reibung : Theorie, Experiment, Anwendungen. Schwingungsdämpfung: Modellbildung - numerische Umsetzung - experimentelle Verfahren - praxisrelevante passive und adaptive Anwendungen. 2007. S. 71-95 (VDI Berichte; 2003).

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AB - In many technical applications, structures are assembled by a large number of substructures, parts and linear or non-linear connecting elements such as springs, dampers or active elements. While the resulting stiffness and inertia properties of interconnected parts may be predicted with sufficient accuracy, the evaluation of the damping amount and, thus, the vibration amplitude of structures subjected to external loads is a complicated, elaborate and time-consuming task. The existing friction interfaces, e.g. in flange or bolt connections, can be utilized to provide a significant amount of damping due to energy dissipation caused by microslip or macroscopic relative displacements between the contacting bodies. By designing these interconnections accurately or, alternatively, creating additional friction contacts, the damping can be increased remarkably, affecting the vibration amplitudes, reliability and lifetime of a structure. Starting with the theoretical background of existing contact models and solution techniques for non-linear differential equations with friction forces, a systematic procedure for designing friction interfaces in order to maximize the damping is presented. The influence on the structural stiffness and the expected damping ratio will be discussed. The developed theoretical models are accompanied by experimental tests at different sample structures with friction contacts to show the great potential of friction damping. Beam structures, space structures, turbine blades and combustion engines will serve as examples of the variety of different technical applications where friction damping can be used successfully to reduce vibration amplitudes.

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Research@Leibniz University

Schwingungsdämpfung Durch Reibung: Theorie, Experiment, Anwendungen

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