Dynamic response analysis of drill pipe considering horizontal movement of platform during installation of subsea production tree

• Autorzy: Wang Fei , Chen Neng

Identyfikatory

DOI

10.2478/pomr-2020-0043

• Języki publikacji: EN

Abstrakty

EN

In order to study the dynamic response of a drill pipe under the motion of the float platform, current and waves during the installation of a subsea production tree (SPT), a numerical model was established to analyse the mechanical properties of the drill pipe. The effects of the float platform motion on the mechanical behaviours of the drill pipe are carried out as well as the operation depth, submerged weight of the SPT, current velocity and drill pipe specification. At the same time, the evolution mechanism of the dynamic response of the drill pipe was also explored. The results show that the bending stress of the drill pipe approaches the maximum value when the platform moves to about one fourth of its period. Based on the research, the deeper the operation depth, the smaller the range of motion of the bottom of the drill pipe; the current velocity and the size of drill pipe have the greatest influence on the lateral displacement and bending stress.

Słowa kluczowe

EN

SPT installation; drill pipe; dynamic response; vibration range; bending stress

• Wydawca: Gdańsk University of Technology, Faculty of Ocean Engineering & Ship Technology
• Czasopismo: Polish Maritime Research
• Rocznik: 2020
• Tom: nr 3
• Strony: 22--30
• Opis fizyczny: Bibliogr. 19 poz., rys., tab.

Twórcy

autor

Wang Fei

• Southwest Petroleum University Xindu, 610500 Chendu, China

autor

Chen Neng

• Southwest Petroleum University Xindu, 610500 Chendu, China

Bibliografia

• 1. Chakrabarti S. K., Frampton R. E. (1982): Review of riser analysis techniques. Applied Ocean Research, 4(2), 73‒90.
• 2. Safai Hachemi V. (1983): Nonlinear dynamic analysis of deep water risers. Applied Ocean Research, 5(4), 215‒225.
• 3. Ahmad S., Datta T. K. (1989): Dynamic analysis response of marine risers. Engineering Structures, 11, 179‒188.
• 4. Ahmad S., Datta T. K. (1992): Nonlinear response analysis of marine risers. Composite Structures, 43(2), 281‒295.
• 5. Wang D. D. (2006): Computational analysis on loads and motion of underwater risers. Master’s Thesis, Dalian University of Technology.
• 6. Khan R. A., et al. (2011): Nonlinear dynamic analysis of marine risers under random loads for deep water fields in Indian offshore. Procedia Engineering, 14, 1334‒1342.
• 7. Qi B. (2012): Global strength analysis of ultra deepwater drilling riser. Master’s Thesis, Harbin Engineering University.
• 8. Zhou S. W., Liu Q. Y., et al. (2013): The discovery of “One Third Effect” for deep water drilling riser: Based on the theoretical and experimental study of deformation characteristics of deep water drilling riser by ocean currents. China Offshore Oil and Gas, 25(06), 1‒7.
• 9. Guo H. Y., Zhang L., et al. (2013): Dynamic responses of top tensioned riser under combined excitation of internal solitary wave, surface wave and vessel motion. Journal of Ocean University of China, 12(1), 6‒12.
• 10. Wang Y. B., et al. (2015): Study on lateral nonlinear dynamic response of deepwater drilling riser with consideration of the vessel motions in its installation. Computers, Materials and Continua, 48(1), 57‒75.
• 11. Fan H. H., et al. (2017): Dynamic analysis of a hang off drilling riser considering internal solitary wave and vessel motion. Journal of Natural Gas Science and Engineering, 37, 512‒522.
• 12. Hu Y. L., et al. (2018): Dynamic behaviors of a marine riser with variable length during the installation of a subsea production tree. Journal of Marine Science and Technology (Japan), 23(2), 378‒388.
• 13. Olszewski A., et al. (2018): FEM analysis and experimental tests of rigid riser hanging system. Polish Maritime Research, 25(2), 108–115.
• 14. Wodtke M., et al. (2018): FEM calculations in analysis of steel subsea water injection flowlines designing process. Polish Maritime Research, 25(3), 84‒93.
• 15. Wang C., et al. (2019): Simulation of axial vibration characteristics of marine riser under suspension mode. Journal of System Simulation, 31(10), 2122‒2130.
• 16. Chen L. Y., et al. (2019): Dynamic characteristic study of riser with complex pre-stress distribution. Polish Maritime Research, 26(3), 87‒97.
• 17. Liu J., et al. (2018): Dynamic behavior of a deepwater hard suspension riser under emergency evacuation conditions. Ocean Engineering, 150, 138‒151.
• 18. Wilson J. F. (Ed). (1991): Dynamics of offshore structures. Beijing Petroleum Industry Press.
• 19. Sexton R. M., Agbezuge L. K. (1976): Random wave and vessel motion effects on drilling riser dynamics. In 8th Annual Offshore Technology Conference.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).