基于筋腱失效分析TLP动态响应

PDF(2505 KB)

振动与冲击 ›› 2023, Vol. 42 ›› Issue (14) : 251-259.

论文

基于筋腱失效分析TLP动态响应

刘葳兴1，刘磊1，吴海涛2，崔琳3，王鑫1，张之阳1

作者信息 +

Analysis of TLP dynamic responses under tendon breakage

LIU Weixing1，LIU Lei1， WU Haitao2， CUI Lin3， WANG Xin1， ZHANG Zhiyang1

Author information +

文章历史 +

摘要

本文对张力腿平台(tension leg platform ，TLP)在不同系泊失效条件下的动态响应进行分析，采用全耦合数值工具ANSYS/AQWA建立非线性平台-筋腱模型，并提出一种模拟筋腱失效的方法。文中主要分析了筋腱失效时的瞬态响应，筋腱同时失效和渐进失效下的平台瞬态响应，以及筋腱失效后平台的性能变化。结果表明：首先，筋腱断裂失效会导致平台产生瞬时过冲；其次，筋腱同时失效下的瞬态响应比筋腱渐进失效的瞬态响应更显著；最后，筋腱失效后平台的性能会发生明显的变化。因此，需提前研究筋腱断裂对平台动态响应的影响，防止平台的安全性受到威胁。

Abstract

The dynamic behavior of a tension leg platform (TLP) under different damaged mooring conditions is studied. A fully-coupled numerical tool ANSYS/AQWA is used to develop a nonlinear hull-tendon model, and an effective method for simulating tendon failure is proposed. The transient effects of tendon breakage, the transient responses of the platform for simultaneous and progressive tendon failure, and the performance changes of the platform after tendon failure are studied. The results show that, first, tendon breakage can lead to transient overshoots of the platform; Second, the transient responses caused by simultaneous tendon failure are more significant than those for progressive tendon failure; Third, the performance of the platform has a significant change after tendon failure. Therefore, the effects of tendon breakage on the dynamic response of the platform should be examined in advance to prevent the safety of the platform from being threatened.

导出引用

刘葳兴1，刘磊1，吴海涛2，崔琳3，王鑫1，张之阳1. 基于筋腱失效分析TLP动态响应[J]. 振动与冲击, 2023, 42(14): 251-259

LIU Weixing1，LIU Lei1， WU Haitao2， CUI Lin3， WANG Xin1， ZHANG Zhiyang1. Analysis of TLP dynamic responses under tendon breakage[J]. Journal of Vibration and Shock, 2023, 42(14): 251-259

参考文献

[1] LIU W, LIU L, WU H, et al. Performance analysis and offshore applications of the diffuser augmented tidal turbines[J]. 2022,https://doi.org/10.1080/17445302.2022.2027691.
[2] 王世圣,谢彬,李新仲.在南海环境条件下深水典型TLP的运动响应分析[J].中国造船,2011,52(增刊1):94-101.
WANG Shengxian, XIE Bin, LI Xinzhong. the motion response analysis of deep water typical TLP in environment conditions of South China Sea[J]. Shipbuilding of China. ,2011,52(Suppl.1):94-101.
[3] 张慎颜,刘秀全,畅元江,等.筋腱断裂后张力腿平台-筋腱-立管耦合系统响应分析[J].中国海上油气,2021,33(2):187-193.
ZHANG Shenyan, LIU Xiuquan, CHANG Yuanjiang, et al. Response analysis of TLP/tendon/riser coupling system under tendon broken[J]. China Offshore Oil and GAS. ,2021,33(2):187-193.
[4] MA K T. Historical review on integrity issues
of permanent mooring systems[C]// Offshore Technology Conference. Texas, USA，2013.
[5] 闫功伟,欧进萍.基于AQWA的张力腿平台动力响应分析[J].东南大学学报(自然科学版),2009,39(增刊2):304-310.
YAN Gongwei, OU Jinping. Dynamic response analysis of TLP based on AQWA[J]. 2009,39(Suppl.2):304-310.
[6] YANG C K, KIM M H. Transient effects of tendon disconnection of a TLP by hull–tendon–riser coupled dynamic analysis[J]. Ocean Engineering, 2010, 37(8/9):667-677.
[7] 谷家扬,陈宇,耿培腾,等.筋腱断裂下深水张力腿平台非线性动力响应及系泊特性研究[J].船舶力学,2015,19(12):1488-1497.
Gu Jiayang, Chen Yu, GE Peiteng, et al. Study on the dynamic response and tension characteristics of a tlp with one tendon broken[J]. Journal of Ship Mechanics, 2015,19(12):1488-1497.
[8] 成司元,余杨,余建星,等.张力腿平台局部系泊失效下复杂运动响应机理研究[J].振动与冲击,2021,40(10):187-195.
CHEN Siyuan, YU Yang, YU Jianxing, et al. Mechanism of the complex motion response of a TLP under tendon failure[J]. Journal of Vibration and Shock, 2021,40(10):187-195.
[9] AHMED M O, YENDURI A, KURIAN V J. Evaluation of the dynamic responses of truss spar platforms for various mooring configurations with damaged lines[J]. Ocean Engineering,2016,123:411-421.
[10] BAE Y H, KIM M H, KIM H C. Performance changes of a floating offshore wind turbine with broken mooring line[J]. Renewable Energy,2017,101:364-375.
[11] Mohammad Reza Tabeshpour,Ali Ahmadi,Ebrahim Malayjerdi. Investigation of TLP behavior under tendon damage[J]. Ocean Engineering,2018,156:580-595.
[12] 吴浩宇,赵永生,何炎平,等.张力腿浮式风机筋腱失效模式下瞬态响应分析[J].浙江大学学报(工学版),2020,54(11):2196-2203.
WU Haoyu, Zhao Yongsheng, HE Yanping, MAO Wengang,YANG Jie,Gu Xiaoli,Huang Chao. Transient response analysis of tension-leg-platformfloating offshore wind turbine under tendon failure conditions[J]. Journal of Zhejiang University (Engineering Science), 2020,54(11):2196-2203.
[13] Yang Yang,Bashir Musa,Michailides Constantine,et al. Coupled analysis of a 10 MW multi-body floating offshore wind turbine subjected to tendon failures[J]. Renewable Energy,2021,176:89-105.
[14] 常爽,黄维平,魏东泽,等.二阶波浪力和聚焦位置对畸形波作用下张力腿平台动力响应的影响研究[J].振动与冲击,2020,39(17):254-260. CANG Shuang,HUANG Weiping,WEI Dongzei,et al. Effects of second-order wave force and focusing location on dynamic response of a tension leg platform under freak wave[J].JOURNAL OF VIBRATION AND SHOCK.2020,39(17):254260.
[15] WU H T, CUI L, LIU W X, Et al. Performance changes of an engineering ship with one mooring line failure[J]. Engineering Failure Analysis, 2022, 137: 106233.
[16] Chuang Zhen ju,Liu She wen,Li Chun zheng,et al. Dynamic analysis of semi-submersible production platform under the failure of mooring lines[J]. China Ocean Engineering,2021,35(1)：84-95.
[17] CAO Q, XIAO L F, GUO X X,et al. Second-order responses of a conceptual semi-submersible 10 MW wind turbine using full quadratic transfer functions[J]. Renewable Energy,2020,153(C)：653-668.
[18] ZHAO Z X,WANG W H,SHI W,et al. Effects of second-order hydrodynamics on an ultra-large semi-submersible floating offshore wind turbine[J]. Structures,2020,28:2260-2275.
[19] PINKSTER J A . Mean and low frequency wave drifting forces on floating structures[J]. Ocean Engineering, 1979, 6(6):593-615.
[20] Carlos Barrera,Iñigo J. Losada,Raúl Guanche,et al. The influence of wave parameter definition over floating wind platform mooring systems under severe sea states[J]. Ocean Engineering,2019,172:105-126.
[21] 余建星，高晓东，余杨，等. 张力腿平台局部系泊失效模式下动力响应分析[J]. 天津大学学报（自然科学与工程技术版），2019，52(1)：40-51.
YU Jianxing, GAO Xiaodong, YU Yang, et al. Dynamic response analysis of a tension leg platform with multiple broken tendons[J]. Journal of Tianjin University (Science and Technology), 2019,52(1)：40-51.
[22] 高巍，张继春，朱为全. 南海“浅深水”海域经典 TLP 平台整体运动性能分析[J]. 船舶工程，2017,39(6): 67-72.
GAO Wei, ZHANG Jichun, ZHU Weiquan. Global motion analysis of conventional TLP in relative shallow water region of South China Sea[J]. Ship Engineering, 2017,39(6): 67-72.
[23] ARC Girón, Kim B W, JAM Farfán, et al. Transient effects of an FPSO with a broken mooring line[C]// ISOPE, Hawaii, USA,2015.