Fluid transmission pipelines, especially curved pipes, are widely used in industrial systems. Vibration characteristics of pipes are highly correlated with the reliability and safety of industrial systems. Therefore, in this paper, a new dynamic stiffness method is proposed to solve the above vibration characteristics of the curved pipes conveying fluid. The dynamic stiffness method can be used to calculate the vibration characteristics of the pipes conveying fluid under arbitrary boundary conditions, By comparing the results of finite element method with those of this method, the correctness of this method is verified. Finally, the vibration characteristics of the pipeline at different angles are calculated by this method. The results show that with the increase of θ value of radian angle in the pipes conveying fluid, both the frequency and critical velocity of in-plane and out-of-plane of the corresponding order decrease, and the natural frequency decreases greatly when θ is small, while the natural frequency decreases little when θ is large.

Yang Hu, Sheng Wang, Longzhou Xiao. Research on Vibration Characteristics of the Curved Pipes Conveying Fluid Based on Dynamic Stiffness Method. International Journal of Frontiers in Engineering Technology (2022), Vol. 4, Issue 6: 62-69. https://doi.org/10.25236/IJFET.2022.040610.

[1] Wang Ya-feng, Zhou Su-feng. Theoretical Analysis and Experimental Verification of Fluid-solid Coupling Vibration Characteristics of Transfusion Pipeline [J]. Equipment Manufacturing Technology, 2020,(8):125-127,139.

[2] Fu Yong-ling, Jing Hui-qiang. Elbow angle effect on hydraulic pipeline vibration characteristics [J]. Journal of Vibration and Shock,2013,32 (13):165-169.

[3] Liao Ju, Zhao Zi-hao, Zhu Lin-feng, et al. Random Vibration Analysis and Design Optimization of Aircraft Fuel Pipeline[J]. Pipeline Technology and Equipment, 2021,(05):1-6.

[4] Zhuo Hai-sen. Simulation Study of Natural Gas Bent Pipe Buckling Deformation [J]. Pipeline Technology and Equipment, 2022,(01):26-29.

[5] Zhang Le-di, Zhang Xian-yu. Aircraft Hydraulic Piping Vibration Characteristics of Fluid-structure Coupling and Dynamic Response Analysis [J]. Science, Technology and Engineering, 2014,14(28): 153-158.

[6] Xu Y, Johnston D N, Jiao Z, et al. Frequency modelling and solution of fluid–structure interaction in complex pipelines. Journal of Sound and Vibration. 2014, 333(10): 2800-2822.

[7] Ma Teng, Du Jing-tao, Xu De-shui, et al. Vibration characteristics analysis of fluid-conveying pipe system with general elastic boundary supports[J]. Journal of Vibration Engineering, 2018,31(3):441-449.

[8] Misra A K, Païdoussis M P, Van K S. On the dynamics of curved pipes transporting fluid. Part I: Inextensible theory. Journal of Fluids and Structures. 1988, 2(3): 221-244.

[9] Misra A K, Païdoussis M P, Van K S. On the dynamics of curved pipes transporting fluid Part II: Extensible theory. Journal of Fluids and Structures. 1988, 2(3): 245-261.

[10] Han Tao, Liu Wei, Zhang Zijun, et al. Natural frequency analysis of complex hydraulic pipelines based on straight-curved pipeline assembly algorithm[J]. Journal of Sound and Vibration, 2018,37(7): 13-22,61.

[11] Wang Sheng. Analysis of linear and nonlinear dynamics of pipes conveying fluid [D]. Huazhong University of Science and Technology, 2015.