Analytical solution of the critical velocity in pipes conveying fluid under thermal loading
CHEN Yanfei, AO Chuan , DONG Shaohua , LIU Hao, MA Shang , XIA Tongjing
1 National Engineering Laboratory for Pipeline Safety / Beijing Key Laboratory of Urban Oil and Gas Distribution Technology, China University of Petroleum-Beijing, Beijing 102246, China 2 State Key Laboratory of Structural Analysis for Industrial Equipment, Dalian University of Technology, Dalian 116024, China
Pipes conveying fluid play an important role in the oil & gas industry. It is critical to determine the critical velocity for structural stability design and safety evaluation of these pipes. Pipes conveying fluid under thermal load are also often used in practical engineering fields, such as crude oil pipeline heating transportation and heated pipelines. Compared with the basic pipes conveying fluid, the natural vibration frequency and critical velocity of a pipeline under thermal load are different from those of the basic pipeline. Based on Hamilton’s principle, the partial differential equation of vibration of supported pipes conveying fluid under thermal loads is derived and the equation is reduced to a univariate fourth-order homogeneous ordinary differential equation by separating variables. A general solution is obtained according to the critical flow velocity conditions of supported pipes conveying fluid. Furthermore, the analytical solutions of the critical velocity are obtained considering various boundary conditions. Finally, numerical examples are presented for analyzing the influence of linear thermal stress and nonlinear thermal stress on the critical velocity under various boundary conditions. The predictions using the proposed analytical solution are compared with results using the differential quadrature method available in the literature. It is demonstrated that the proposed analytical solution can give an accurate solution efficiently, which can be used in engineering practice. The critical flow rate of the pipes conveying a fluid system under linear thermal stress and non-linear thermal stress decreases with an increase of thermal load, and the decrease becomes larger and larger. In the same case, the critical velocity under nonlinear thermal stress is greater than that under linear thermal stress, and the gap between them increases with an increase of thermal load. Comparing the boundary conditions, it is found that fixed boundary conditions can bear the largest thermal load. Therefore, applying fixed boundary conditions to the pipes conveying fluid system under the thermal load is beneficial to improve the stability of the system. In this paper, the analytical method for critical velocity of pipes conveying fluid under thermal load can be obtained conveniently and quickly at the engineering site, which provides a reference for the design and safety evaluation of pipes conveying fluids under thermal load.
CHEN Yanfei, AO Chuan, DONG Shaohua, LIU Hao, MA Shang, XIA Tongjing. Analytical solution of the critical velocity in pipes conveying fluid under thermal loading. Petroleum Science Bulletin, 2021, 01: 138-144.
