Design features of rubber metal compensators and numerical simulation of their stress-strain state upon hydrostatic compression

Kiryukhin, A.; Mil`man, O.; Ptakhin, A.; Shaidurova, G.; Shaidurov, A.

Growing Science » Engineering Solid Mechanics » Design features of rubber metal compensators and numerical simulation of their stress-strain state upon hydrostatic compression

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Engineering Solid Mechanics

ISSN 2291-8752 (Online) - ISSN 2291-8744 (Print) Quarterly Publication Volume 5 Issue 3 pp. 177-184 , 2017

Design features of rubber metal compensators and numerical simulation of their stress-strain state upon hydrostatic compression Pages 177-184 Download PDF

Authors: Aleksei Vladimirovich Kiryukhin, Oleg Osherovich Mil`man, Anton Viktorovich Ptakhin, Galina Ivanovna Shaidurova, Aleksandr Aleksandrovich Shaidurov

DOI: 10.5267/j.esm.2017.6.001

Keywords: Crack initiation angle, Vibration, Pressure oscillation, Dynamic forces, Airborne noise, Energy generating facility, Vibration protection, Pipeline, Compensator, Active vibration protection in spatial motions

Abstract: This article discusses possibilities of application of widely applied and promoted abroad methods of active dampening of vibration and pressure oscillations (antinoise technology) in order to reduce vibration transfer via vibro-insulating couplings (compensators) of fluid pipelines. This is required in solution of issues of vibration insulation of equipment with regard to foundation and environment along pipelines with working mediums, for instance, in transporting of oil and gas, in energy and transport engineering. Reasonability of operation of active system in combination with means of passive dampening of these impacts is demonstrated. In terms of efficiency and minimum energy consumptions by active system it is reasonable to apply active dampening of vibration and oscillations downstream of the vibro-insulator (compensator) where their level is significantly lower than in the source. In the case of pipeline this implies dampening of vibration and oscillation downstream of compensator and damper, however, such works are nearly unavailable. This is attributed to significant coupling between vibration and pressure oscillation in compensator and pipeline itself, complicating solution of the problem. It is concluded that for efficient application of active dampening in pipeline compensators it is required to develop compensators with minimum coupling between vibration and oscillations.

How to cite this paper

 Kiryukhin, A., Mil`man, O., Ptakhin, A., Shaidurova, G & Shaidurov, A. (2017). Design features of rubber metal compensators and numerical simulation of their stress-strain state upon hydrostatic compression.Engineering Solid Mechanics, 5(3), 177-184.

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