Dynamic response of pipes conveying two-phase flow based on Timoshenko beam model

The dynamic behavior of pipes subjected to internal gas–liquid two-phase flow has been studied using the Timoshenko beam model and the slip-ratio factor model. In this paper, the governing equations were carried out using the generalized integral transform technique (GITT) by transforming the govern...

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Bibliographic Details
Published inMarine systems & ocean technology : journal of SOBENA--Sociedade Brasileira de Engenharia Naval Vol. 12; no. 3; pp. 196 - 209
Main Authors Ma, Tianqi, Gu, Jijun, Duan, Menglan
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.09.2017
Springer Nature B.V
Subjects
Amplitude
Computational fluid dynamics
Differential equations
Divergence
Dynamic response
Dynamic stability
Engineering
Euler-Bernoulli beams
Flow rates
Flow stability
Flow velocity
Fluid flow
High flow
Instability
Integral transforms
Low aspect ratio
Mathematical models
Multiphase flow
Offshore Engineering
Ordinary differential equations
Partial differential equations
Pipes
Ratios
Fluid–structure interaction
Internal flow
Timoshenko beam model
Pipe-conveying two-phase flow
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Summary:The dynamic behavior of pipes subjected to internal gas–liquid two-phase flow has been studied using the Timoshenko beam model and the slip-ratio factor model. In this paper, the governing equations were carried out using the generalized integral transform technique (GITT) by transforming the governing partial differential equations into a set of second-order ordinary differential equations. The comparison between Timoshenko beam model and Euler–Bernoulli beam model has been conducted through parametric study on dimensionless frequencies and amplitudes over various aspect ratios, internal fluid flow rates, and volumetric gas fractions. The results show that the frequencies of Timoshenko beam model are less and the amplitude is larger than that of Euler–Bernoulli beam model at low aspect ratio. In addition, the amplitude for Timoshenko beam model increases more dramatically than that of Euler–Bernoulli beam model when the pipe is about to lose stability. The high flow rate leads to the divergence of the dynamic system, as well as the two-phase flow accelerates the instability and has significant influence on the dynamic response when the pipe is long and the internal liquid flows fast.
ISSN:1679-396X
2199-4749
DOI:10.1007/s40868-017-0029-z