Model analysis of flow-induced vibration (LIV) in submarine oil and gas pipeline

[1] Bordalo, S. N., & Morooka, C. K. (2018). Slug flow induced oscillations on subsea petroleum pipelines. Journal of petroleum science and engineering, 165, 535-549. Search in Google Scholar

[2] Cabrera-Miranda, J. M., & Paik, J. K. (2019). Two-phase flow induced vibrations in a marine riser conveying a fluid with rectangular pulse train mass. Ocean Engineering, 174, 71-83. Search in Google Scholar

[3] Zhu, H., Gao, Y., & Zhao, H. (2019). Experimental investigation of slug flow-induced vibration of a flexible riser. Ocean Engineering, 189, 106370. Search in Google Scholar

[4] Yan, S., Jia, K., Xu, W., & Ma, Y. (2023). An experimental study on vortex-induced vibration suppression for submarine multispan pipelines. Ocean Engineering, 271, 113678. Search in Google Scholar

[5] Zhu, H., Hu, J., Gao, Y., Ji, C., & Zhou, T. (2022). Experimental investigation on flow-induced vibration of a flexible catenary riser conveying severe slugging with variable gas superficial velocity. Journal of Fluids and Structures, 113, 103650. Search in Google Scholar

[6] Fan, D., Wu, B., Bachina, D., & Triantafyllou, M. S. (2019). Vortex-induced vibration of a piggyback pipeline half buried in the seabed. Journal of Sound and Vibration, 449, 182-195. Search in Google Scholar

[7] Mohammed, A. A., Salman, A. M., & Ayoub, M. S. (2023). Flow Induced Vibration for Different Support Pipe and Liquids: A review. Al-Nahrain Journal for Engineering Sciences, 26(2), 83-95. Search in Google Scholar

[8] Chunsheng, W., Zejun, L., Yan, Z., & Qiji, S. (2020). Research on Flow-induced Vibration Characteristics of Conveying Pipes Under Bidirectional Tidal Flow. The International Journal of Multiphysics, 14(3), 237-247. Search in Google Scholar

[9] Tu, Z., Wang, Q., Rasmussen, S. L., Nystrøm, P. R., & Gade, A. (2021, June). Flow Induced Vibration Assessment of Subsea Spools Using Power Spectrum Density Analysis. In ISOPE International Ocean and Polar Engineering Conference (pp. ISOPE-I). ISOPE. Search in Google Scholar

[10] Zhu, H., Zhao, H., & Srinil, N. (2021). Experimental investigation on vortex-induced vibration and solid-structure impact of a near-bottom horizontal flexible pipeline in oblique shear flow. Journal of Fluids and Structures, 106, 103356. Search in Google Scholar

[11] Zhu, H., Hu, Y., Tang, T., Ji, C., & Zhou, T. (2022). Evolution of gas-liquid two-phase flow in an M-shaped jumper and the resultant flow-induced vibration response. Processes, 10(10), 2133. Search in Google Scholar

[12] Haile, S. G., Woschke, E., Tibba, G. S., & Pandey, V. (2022). Internal two-phase flow induced vibrations: A review. Cogent Engineering, 9(1), 2083472. Search in Google Scholar

[13] Macchion, O., Emmerson, P., Lewis, M., Stachyra, L., & Orre, S. (2022, June). Two-Phase Flow Induced Vibrations: Methodology Validation–Part 2. In International Conference on Offshore Mechanics and Arctic Engineering (Vol. 85925, p. V007T08A015). American Society of Mechanical Engineers. Search in Google Scholar

[14] Pickles, D. J., Hunt, G., Elliott, A. J., Cammarano, A., & Falcone, G. (2024). An experimental investigation into the effect two-phase flow induced vibrations have on a J-shaped flexible pipe. Journal of Fluids and Structures, 125, 104057. Search in Google Scholar

[15] Song, W., Li, W., Lin, S., Zhou, X., & Han, F. (2024). Flow pattern evolution and flow-induced vibration response in multiphase flow within an M-shaped subsea jumper. Ocean Engineering, 298, 117213. Search in Google Scholar

[16] Chen, Y., Wu, Z., Hou, F., Wang, Z., & Liu, Y. (2023). Analysis of Flow-induced Vibration Based on Discharge Pipeline on Offshore Platform. Mod Subsea Eng Technol, 1(2). Search in Google Scholar

[17] Li, W., Zhou, Q., Yin, G., Ong, M. C., Li, G., & Han, F. (2022). Experimental investigation and numerical modeling of two-phase flow development and flow-induced vibration of a multi-plane subsea jumper. Journal of Marine Science and Engineering, 10(10), 1334. Search in Google Scholar

[18] Jujuly, M. M., Rahman, M. A., Maynard, A., & Adey, M. (2020). Hydrate-induced vibration in an offshore pipeline. SPE Journal, 25(02), 732-743. Search in Google Scholar

[19] Zhu, H., Tang, T., & Li, Q. (2023). Flow-Induced Vibration of a Reversed U-Shaped Jumper Conveying Oil-Gas Two-Phase Flow. Processes, 11(4), 1134. Search in Google Scholar

[20] Li, W., Li, J., Yin, G., & Ong, M. C. (2023). Experimental and Numerical Study on the Slug Characteristics and Flow-Induced Vibration of a Subsea Rigid M-Shaped Jumper. Applied Sciences, 13(13), 7504. Search in Google Scholar

[21] Yang Wenwu,Li Xin,Tao Yuhan,Cen Kang & Wen Yunqiao.(2022).Causal analysis of natural gas station pipelines vibration and reduction measures.Journal of Mechanical Science and Technology(9),4409-4418. Search in Google Scholar

[22] Mingkang Ni,Xinming Qian,Yuanzhi Li & Mengqi Yuan.(2024).Research on the vibration response characteristics of PE gas pipeline aimed for third-party damage monitoring.Process Safety and Environmental Protection820-832. Search in Google Scholar

[23] Baoyong Yan,Jialin Tian,Xianghui Meng & Zhe Zhang.(2023).Vibration Characteristics and Location of Buried Gas Pipeline under the Action of Pulse Excitation.Processes(10). Search in Google Scholar