Determination of stiffness and damping sensitivity for computer numerically controlled machine tool drives

Holroyd, Geoffrey, Pislaru, Crinela and Ford, Derek G. (2003) Determination of stiffness and damping sensitivity for computer numerically controlled machine tool drives. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 217 (10). pp. 1165-1177. ISSN 0954-4062

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Abstract

A generalized eigenvalue method is used to determine the undamped and damped natural
frequencies, coefŽ cients of damping and mode shapes of a computer numerically controlled (CNC)
machine tool drive. The calculated results compare well with the measured results obtained by using
vibration analysis equipment. Then the sensitivity of the various modes to changes in the stiffness and
damping characteristics of the machine drives is estimated. These values prove to be useful in
adjusting the parameters of a hybrid model for a CNC machine tool axis drive in order to alter the
simulated results in accordance with the measured results.

Item Type:	Article
Additional Information:	UoA 25 (General Engineering) © IMechE 2003
Subjects:	T Technology > TJ Mechanical engineering and machinery
Schools:	School of Computing and Engineering School of Computing and Engineering > Centre for Precision Technologies School of Computing and Engineering > Centre for Precision Technologies > Engineering Control and Machine Performance Research Group School of Computing and Engineering > Pedagogical Research Group School of Computing and Engineering > Diagnostic Engineering Research Centre School of Computing and Engineering > Diagnostic Engineering Research Centre > Energy, Emissions and the Environment Research Group School of Computing and Engineering > Diagnostic Engineering Research Centre > Measurement System and Signal Processing Research Group
Related URLs:	Author Author
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Depositing User:	Briony Heyhoe
Date Deposited:	24 Jul 2007
Last Modified:	28 Aug 2021 23:32
URI:	http://eprints.hud.ac.uk/id/eprint/309

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