Welcome to Francis Academic Press

International Journal of Frontiers in Engineering Technology, 2022, 4(3); doi: 10.25236/IJFET.2022.040308.

Design of Offshore Oil and Gas Platform Based on Tidal Energy Turbine Power Generation


Chuangen Zheng1, Haiquan Zhong1, Kai Zhang1, Li Lin2, Tongjun He3

Corresponding Author:
Haiquan Zhong

1State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, Sichuan, China

2Yunnan University of Finance and Economics, Kunming 650000, Yunnan, China

3Shu'nan Gas Mine, Southwest Oil & Gas Field Branch Company, CNPC, Luzhou 646000, Sichuan, China


The development of offshore oil and gas energy has become the focus of production breakthrough in the oil and gas industry. Due to the rich oil and gas resources in the offshore coast, aiming at the problem of maximization the commissioning of offshore operations in shallow, we can learn from the conventional jacket platform and make full use of the rich tidal energy resources in the marine resources and their strong regularity and predictability. A set of offshore oil and gas platform based on tidal current turbine power generation is designed. The reasonable reliability of the platform is verified by simulating the load stress under four typical simulated environments with two working conditions under current load, sea breeze load and sea ice load. The results show that under extreme conditions, the UC value of the jacket platform is between 0.34 and 0.43, far less than 1. It has good stability and bearing capacity.


Exploitative of Offshore Petroleum-Gas Reservoir, Tidal Energy, Jacket Platform, Uc Values, Simulation

Cite This Paper

Chuangen Zheng, Haiquan Zhong, Kai Zhang, Li Lin, Tongjun He. Design of Offshore Oil and Gas Platform Based on Tidal Energy Turbine Power Generation. International Journal of Frontiers in Engineering Technology (2022), Vol. 4, Issue 3: 60-65. https://doi.org/10.25236/IJFET.2022.040308.


[1] Xie Peiyong. Marine shallow giant gas field-DF1-1 gas field. Natural Gas Industry, 1999,19(1): 43-46.

[2] Wu Yi. Design of conductor support scheme for offshore jack-up wellhead support platform. Journal of Chongqing Institute of Science and Technology (Natural Science Edition), 2020,22(6): 38-41.

[3] Guo Yuli, Wang Zuoqiang, Zhang Liang, et al. Applicability analysis of different jacket demolition equipment. Petroleum Engineering Construction, 2021,47(3): 6-12.

[4] Yan Tianhong, Zhou Guoqiang, Wu Zemin, et al. Research on structural damage identification of the offshore platform based on modal flexibility and FEM updating. Journal of Machine Design, 2021,47(3): 6-12.

[5] Yan Tianhong, Wang Weigang, Zhao Haifeng, et al. Development of structure monitoring systems and digital twin technologyof active jacket platforms. China Mechanical Engineering, 2021,32(20): 2508-2513.

[6] Wang Shujie, Wang jutian, Liu Jinkun, et al. Investigation and discussion of marine structures integrated with ocean energy devices. The Ocean Engineering, 2015,33(4): 115-120.

[7] Han Duanfeng, Zhang Yuan, Gao Liangtian, et al. The numerical simulation of the influence domain of turbine. Ship Science and Technology, 2015,(10): 21-25.

[8] Liu Huaxiang, Yuan Yujie, Zeng Jingbo, et al. Application state and prospect of steels for jacket platform. China Offshore Oil and Gas, 2020,32(04): 164-170.

[9] Hou Jinlin, Yu Chunjie, Shen Xiaopeng. Study on jacket design and installation in deep water: a case of LW 3-1 CEP jacket. China Offshore Oil and Gas, 2013,25(6): 93-97.

[10] Zhang Qiang, Zheng Yuan, Chen Huixiang. Numerical simulation of tidal current energy turbine based on CFD. South-to-North Water Transfers and Water Science & Technology, 2015,13(3): 518-521.

[11] Rao Xiang, Lu Kuan, Wang Huamei. Research on the influence of wave-current coupling on the array of floating tidal current turbine. Renewable Energy Resources, 2021,39(5): 705-710.

[12] Li Qingyang, Chen Guoming, Lu Tao, et al. Bearing capacity of jacket platforms based on wind scale incremental analysis. China Offshore Platform, 2019,34(04): 37-44.

[13] Kang Haigui, Mo Renjie, Long Liji, et al. Simplification and load response analysis of offshore wind turbine tripile foundation. Renewable Energy Resources, 2014,32(5): 609-618.

[14] Qiu Shaohua. Response analysis on overall structure of the jacket platform under environment sea ice load. Ship & Ocean Engineering, 2020,49(04): 30-33.