Peculiarities of reducing the broadband transfer of vibration and working medium pulsation through vibration-isolating junctions of pipelines with liquid by constructive and active methods

It is shown that the vibration transfer and working medium pressure pulsations through vibration-isolating pipeline junctions of various plants may increase by two or three orders of magnitude with an increase in the vibration frequency and in the presence of incompressible working fluid. The result...

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Bibliographic Details
Published inThermophysics and aeromechanics Vol. 31; no. 1; pp. 123 - 133
Main Authors Kiryukhin, A. V., Milman, O. O., Ptakhin, A. V., Miloserdov, V. O.
Format Journal Article
LanguageEnglish
Published Novosibirsk Kutateladze Institute of Thermophysics SB RAS 01.01.2024
Springer Nature B.V
Subjects
Active damping
Broadband
Efficiency
Fluid flow
Frequency ranges
Incompressible flow
Octaves
Physics
Physics and Astronomy
Thermodynamics
Vibration
Vibration analysis
Vibration damping
Working fluids
transfer function
feedback
force sensor
vibration frequency
vibration force
active antivibration system
pipeline vibration-isolating junctions
pressure pulsation
direct connection
vibration rigidity
shock absorber
amplification factor
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Summary:It is shown that the vibration transfer and working medium pressure pulsations through vibration-isolating pipeline junctions of various plants may increase by two or three orders of magnitude with an increase in the vibration frequency and in the presence of incompressible working fluid. The results of research of the found physical models that determine this phenomenon are presented. The experimental results for a spatial three-component broadband active vibration-protection system (AVS) for vibration damping beyond the vibration isolation junction with liquid are considered. An experimental plant scheme for studying the simultaneous spatial active damping of dynamic forces, vibrations and pressure pulsations downstream from the junction has been given. Calculated dependences of the maximum efficiency of considered AVS on frequency are obtained. Efficient active damping of forces is shown to be attainable in an open loop without feedback. While damping in an open loop at the experimental plant, the efficiency of active damping of dynamic forces is obtained in three directions up to 10 dB or more in the frequency range from 5 to 800 Hz (more than seven octaves). The analysis of scientific publications reveals the uniqueness of this result. In this case, there are no zones of negative efficiency outside the active damping frequency range, which appear while using other methods of active damping.
ISSN:1531-8699
0869-8643
1531-8699
DOI:10.1134/S0869864324010128