access icon openaccess Study on dynamic characteristics analysis of CNC pipe thread lathe based on the energy of modal effective mass

This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 05/10/2018, Accepted 19/10/2018, Revised 18/10/2018, Published 22/10/2018

Owing to the modal analysis of complex structure system exist in the problems such as the local mode cannot be identified and the overall modal vibration mode cannot be extracted, this study deduces a formula of modal effective parameters based on the kinetic energy and introduces to the simulation of mechanical characteristics of the SCK230 CNC pipe thread repair the lathe bed. The simulation shows that this method can identify the local mode of three directions effectively, and determines whether the numbers of solved modalities satisfy the requirement of precision. In order to improve the natural frequencies of the bed and analyse the influence of the opening of the bed on its dynamic performance, three optimisation schemes are proposed based on this, and verified the feasibility of the optimisation scheme. Through structural optimisation, improve the dynamic characteristic of the lathe bed and reduce the manufacturing cost, and the optimisation of the structure can be achieved without experimental modal analysis.

Inspec keywords: computerised numerical control; optimisation; modal analysis; vibrations; lathes; pipes

Other keywords: dynamic characteristic; local mode; complex structure system; modal vibration mode; natural frequencies; modal effective mass; mechanical characteristics; kinetic energy; optimisation scheme; dynamic characteristics analysis; structural optimisation; modal effective parameters; manufacturing cost; dynamic performance; lathe bed; experimental modal analysis; SCK230 CNC pipe thread repair

Subjects: Production equipment; Numerical analysis; Vibrations and shock waves (mechanical engineering); Mechanical components; Control applications in machining processes and machine tools; Control engineering computing; Optimisation; Control technology and theory (production); Optimisation techniques

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