Internal Solitary Wave Loadsand and Its Theoretical Model for a Tension Leg Platform

Abstract

Abstract:

A series experiments were conducted to investigate interaction characteristics of internal solitary waves with a tension leg platform in a large-scale gravity type density stratified tank. Based on KdV(Korteweg-de Vries), eKdV(extended KdV) and MCC(Miyata-Choi-Camassa) theories for internal solitary waves in a two-layer fluid, a theoretical model was established for predicting the internal solitary wave loads on a tension leg platform, Besides the applicability conditions for these internal solitary wave theories were presented in order to apply such a load model. It is shown that the horizontal load on the tension leg platform due to the internal solitary wave consists of two parts which are the drag and inertial forces on the vertical column and caisson, and these two forces can be calculated by the Morison formula, while the vertical load is mainly the vertical Froude-Krylov force which can be calculated by integrating the dynamic pressure along with the bottom of the columns, as well as the upper and lower surfaces of all caissons. A series experimental results show that the drag coefficient in the Morison formula follows some exponential function relationships with the Reynolds, while the inertial force coefficient follows power function relationships with KC(Keulegan-Carpenter) numbers. Moreover, the numerical results based on the theoretical predicting model have good agreement with the experimental ones. This research provides a practical theoretical model based on the series of experimental results for predicting internal solitary wave loads on tension leg platforms.

Key words: tension leg platform, internal solitary wave, twolayer fluid; Morison formula, Froude-Krylov force

CLC Number:

O 352

HUANG Wenhao,YOU Yunxiang,WANG Jingyu,HU Tianqun. Internal Solitary Wave Loadsand and Its Theoretical Model for a Tension Leg Platform[J]. Journal of Shanghai Jiaotong University, 2013, 47(10): 1494-1502.

References

［1］董艳秋.深海采油平台波浪载荷及响应［M］.天津:天津大学出版社,2005.

［2］方欣华,杜涛.海洋内波基础和中国海内波［M］.青岛:中国海洋大学出版社,2005.

［3］Liu A K, Chang Y S, Hsu M K, et al. Evolution of nonlinear internal waves in the East and South China Seas［J］. J Geophys Res, 1998,103(C4): 79958008.

［4］蔡树群,甘子均,龙小敏.南海北部孤立子内波的一些特征和演变［J］.科学通报.2001, 46(15): 12451250.

CAI Shuqun, GAN Zijun, Long Xiaomin. Some characteristics and evolution of internal solitary waves in the northern south China sea［J］. Chinese Science Bulletin, 2001, 46(15): 12451250.

［5］陈景辉.南海流花111深海油田开发工程［J］. 中国海洋平台，1996,11(1):4345.

CHEN Jinghui. Liuhua 111 deep sea oilfield development project in south China sea［J］. China Offshore Platform, 1996, 11(1):4345.

［6］Bole J B, Ebbesmeyer C C, Romea R D. Soliton currents in the South China sea: Measurements and theoretical modeling［C］//The 16th Offshore Technology Cofference. Houston Texas, USA: Offshore Technology Cofference,1994：367376.

［7］Faltinsen O M.Sea loads on ships and offshore structures［M］. London:Cambridge University Press,1993.

［8］Cheng Y L, Li J C, An L S, et al. The induced flow field by internal solitary wave and its action on cylindrical piles in the stratified ocean［C］//The 4th International Conference on Fluid Mechanics. Dalian, China: Tsinghua University Press & SpringerVerlag, 2004: 296299.

［9］Cai S Q, Long X M, Gan Z J. A method to estimate the forces exerted by internal solitons on cylindrical piles［J］. Ocean Eng, 2003,30(5):673689.

［10］Cai S Q, Long X M, Wang S G. Forces and torques exerted by internal solitons in shear flows on cylindrical piles［J］. Appl Ocean Res, 2008(1),30:7277.

［11］Xie J S，Jiang Y J, Yang L G. Strongly nonlinear internal soliton load on a small vertical circular cylinder in twolayer fluids［J］. Appl Math Model, 2010, 34(8):20892101.

［12］尤云祥,李巍,何景异,等.海洋内孤立波中张力腿平台的水动力特性［J］. 上海交通大学学报, 2010,44(1):1217.

YOU Yunxiang, LI Wei, HE Jingyi, et al. Hydrodynamic characteristics of tension leg platforms in ocean internal solitary waves［J］. J Shanghai Jiaotong Univ, 2010, 44(1):1217.

［13］尤云祥,李巍,胡天群,等.内孤立波中半潜平台动力响应特性［J］.海洋工程, 2012,30(2)：17.

YOU Yunxiang, LI Wei, HU Tianqun, et al. Dynamic responses of a semisubmersible platform in internal solitary waves［J］. The Ocean Eng, 2012,30(2)：17.

［14］宋志军,勾莹,滕斌,等.内孤立波作用下Spar平台的运动响应［J］.海洋学报,2010,32(2):1219.

SONG Zhijun, GOU Ying, TENG Bin, et al. The motion responses of a Spar platform under internal solitary wave［J］. Acta Oceanologica Sinica, 2010,32(2):1219.

［15］Camassa R,Choi W, Michallet H, et al. On the realm of validity of strongly nonlinear asymptotic approximations for internal waves［J］. J Fluid Mech, 2006,549:123.

［16］黄文昊,尤云祥,王旭,等.有限深两层流体中内孤立波造波实验及其理论模型［J］.物理学报,2013,62(8):084705.

HUANG Wenhao, YOU Yunxiang, WANG Xu, et al.Wavemaking experiments and theoretical models for internal solitary waves in a twolayer fluid of finite depth［J］. Acta Physica Sinica, 2013,62(8):084705.

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