Effect of Upward Internal Flow on Dynamics of Riser Model Subject to Shear Current 被引量：3

Effect of Upward Internal Flow on Dynamics of Riser Model Subject to Shear Current

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摘要 Numerical study about vortex-induced vibration （V/V） related to a flexible riser model in consideration of internal flow progressing inside has been performed. The main objective of this work is to investigate the coupled fluid-structure interaction （FSI） taking place between tensioned riser model, external shear current and upward-progressing internal flow （from ocean bottom to surface）. A CAE technology behind the current research which combines structural software with the CFD technology has been proposed. According to the result from dynamic analysis, it has been found that the existence of upward-progressing internal flow does play an important role in determining the vibration mode （/dominant frequency）, vibration intensity and the magnitude of instantaneous vibration amplitude, when the velocity ratio of internal flow against external current is relatively high. As a rule, the larger the velocity of intemal flow is, the more it contributes to the dynamic vibration response of the flexible riser model. In addition, multi-modal vibration phenomenon has been widely observed, for asymmetric curvature along the riser span emerges in the case of external shear current being imposed. Numerical study about vortex-induced vibration （V/V） related to a flexible riser model in consideration of internal flow progressing inside has been performed. The main objective of this work is to investigate the coupled fluid-structure interaction （FSI） taking place between tensioned riser model, external shear current and upward-progressing internal flow （from ocean bottom to surface）. A CAE technology behind the current research which combines structural software with the CFD technology has been proposed. According to the result from dynamic analysis, it has been found that the existence of upward-progressing internal flow does play an important role in determining the vibration mode （/dominant frequency）, vibration intensity and the magnitude of instantaneous vibration amplitude, when the velocity ratio of internal flow against external current is relatively high. As a rule, the larger the velocity of intemal flow is, the more it contributes to the dynamic vibration response of the flexible riser model. In addition, multi-modal vibration phenomenon has been widely observed, for asymmetric curvature along the riser span emerges in the case of external shear current being imposed.

作者陈正寿 KIM Wu-joan 熊丛博

机构地区 School of Naval Architecture and Civil Engineering Department of Ocean Engineering The First Institute of Oceanography

出处《China Ocean Engineering》 SCIE EI 2012年第1期95-108,共14页 中国海洋工程（英文版）

基金 supported by the National Natural Science Foundation of China (Grant Nos. 41106077, 51109185 and 51109186) Zhejiang Provincial Natural Science Foundation of China (Grant Nos. R5110036 and Y5110071) Science Research Program of Science Technology Department of Zhejiang Province (Grant No. 2011C24005) Korea Research Foundation (Grant No. KRF-2008-D00556) Scientific Research Foundation of Zhejiang Ocean University

关键词 internal flow upward-progressing fluid-structure interaction velocity ratio internal flow upward-progressing fluid-structure interaction velocity ratio

分类号 U661.44 [交通运输工程—船舶及航道工程]

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参考文献2

1杨和振,李华军.Instability Assessment of Deep-Sea Risers Under Parametric Excitation[J].China Ocean Engineering,2009,23(4):603-612. 被引量：10
2CHEN Zhengshou,KIM Wu-joan,CHOI Yoon-rak.Numerical simulation of a short flexible pipe subject to forced motion and vortex-induced vibration[J].Acta Oceanologica Sinica,2009,28(6):70-83. 被引量：3

二级参考文献28

1Al-Jamal H, Dalton C. 2004. Vortex induced vibrations using large eddy simulation at a moderate Reynolds number. Journal of Fluids and Structure, 19(1):73-92.
2ANSYS. 2007. ANSYS CFX-Solver Modeling Guide (Vll SP1).
3Bearman P W. 1984. Vortex shedding from oscillating bluff bodies. Annual Review of Fluid Mechanics,16:195-222.
4Chen Z S, Kim W J, Yu D Y. 2008. Numerical simulation of a large-scale riser with vortex-induced vibration,ISOPE PACOMS, Bangkok: King Mongkut's University of Technology Thonburi.
5Choi Y L, Hong S. 2000. Study about structural deformation estimation about flexible pipe in the engineering basin model test, Korea Ocean Research & Development Institute (KORDI), research report.
6Dong S, Karniadakis G. E. 2005. DNS of flow past a stationary and oscillating cylinder at Re=10000.Journal of Fluids and Structure, 20(4): 19-31.
7Evangelinos C. 1999. Parallel Simulations of VortexInduced Vibrations in Turbulent Flow: Linear and Non-Linear Models, Ph. D. Thesis, Brown University.
8Feng C C. 1968. The measurement of vortex induced effects in flow past stationary and oscillating circular and d-section cylinders, Department of Mechanical Engineering, The University of British Columbia,Canada. Master's Thesis.
9Fujisawa N, Asano Y. 2005. Computational and experimental study on flow around a rotationally oscillating circular cylinder in a uniform flow. J Wind Eng Ind Aerodyn, 93(2): 37-53.
10Gabbal R D, Benaroya H. 2005. An overview of modeling and experiments of vortex-induced. Journal of Sound and Vibration, 282:575-616.

共引文献11

1YANG HeZhen,LI HuaJun.Sensitivity analysis of fatigue life prediction for deepwater steel lazy wave catenary risers[J].Science China(Technological Sciences),2011,54(7):1881-1887. 被引量：22
2卢其进,杨和振.母船垂荡导致ROV脐带缆参量共振的研究[J].海洋技术,2011,30(3):77-82. 被引量：6
3杨林,李华军.不同节点布置下二维涡激振动的无单元法参数化分析[J].中国海洋大学学报（自然科学版）,2012,42(5):105-110.
4姜豪,杨和振,刘昊.深海非粘结柔性立管简化模型数值分析及实验研究[J].中国舰船研究,2013,8(1):64-72. 被引量：15
5肖飞,杨和振,卢其进,张黎邦.涡激致顶张力立管双频参量共振研究[J].海洋工程,2013,31(2):28-34. 被引量：5
6郑辉,金鑫,李成钢,韦卓.深水立管顶端柔性节点疲劳寿命预测[J].海洋技术,2013,32(4):99-103. 被引量：2
7刘羽,陈正寿,赵陈,黄聪汉.潮流能水轮机导流罩的水动力性能研究[J].浙江海洋学院学报（自然科学版）,2014,33(3):199-208. 被引量：14
8肖飞,杨和振.深海钢悬链立管Hill不稳定性预测[J].上海交通大学学报,2014,48(4):583-588. 被引量：5
9孙丽萍,王建伟,戴绍仕.计及平台运动响应谱的顶部张紧立管稳定性曲线研究[J].哈尔滨工程大学学报,2016,37(3):326-331. 被引量：1
10李效民,张林,牛建杰,韩永庆,郭海燕.基于向量式有限元的深水顶张力立管动力响应分析[J].振动与冲击,2016,35(11):218-223. 被引量：6

同被引文献21

1汪建文,孙科,贾瑞博.风力机扩散放大器流场的数值仿真[J].能源技术,2004,25(5):185-187. 被引量：5
2刘文广,陆启生,袁保伦,刘泽金.收缩段线型对超音速喷管氟原子气相复合的影响[J].力学学报,2006,38(3):392-397. 被引量：3
3张亮,孙科,罗庆杰.潮流水轮机导流罩的水动力设计[J].哈尔滨工程大学学报,2007,28(7):734-737. 被引量：26
4PONTA F L, JACOVKIS P M. Marine-current powergeneration by diffuser-augmented floating hydro-turbines[J]. Renewable Energy,2008,33(20):665-673.
5陈正寿,孙孟. 自适应悬浮型潮流能水轮机:中国,ZL201120112764郾1[P]. 2011-09-07.
6陈正寿,孙孟. 悬浮发电水轮机:中国,ZL2011205189505[P].2012-08-01.
7陈正寿,段自豪,王晋宝,等. -种抗倾覆水轮机装置:中国,ZL201220674648郾3[P]. 2013-06-12.
8MATSUSHIMA T, TAKAGI S, MUROYAMA S.Characteristics of a highly efficient propeller type smallwind turbine with a diffuser [J]. Renewable Energy,2006, 31(9):1343-1354.
9中国人民解放军总装备部军事训练教材编辑工作委员会. 高低速风洞气动与结构设计[M]. 北京: 国防工业出版社, 2003.
10CHEN Zhengshou, KIM W. Effect of bidirectionalinternal flow on fluid-structure interaction dynamics ofconveying marine riser model subject to shear current[J].International Journal of Naval Architecture and OceanEngineering, 2012, 4(1):57-70.

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1陈正寿,赵陈,刘羽,赵春慧,王莉萍.折线型悬浮导流罩的水动力设计[J].水利水电科技进展,2015,35(4):49-54. 被引量：3
2LOU Min,ZHANG Yuansheng,WU Wugang.Static Optimization of a Compliant Vertical Access Riser[J].Journal of Ocean University of China,2019,18(5):1070-1078.
3柳博瀚,陈正寿,鲍健,崔振东.管道内流对海洋弹性管振动影响的数值仿真研究[J].振动与冲击,2020,39(17):177-185. 被引量：14

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3刘松,吴先梅,彭修乾,陈家熠,王聪.基于双向流固耦合的输流圆管应力应变响应分析[J].振动与冲击,2021,40(20):73-79. 被引量：7
4李效民,李胜,顾洪禄,郭海燕.段塞流作用下海底悬跨管道涡激振动特性分析[J].振动与冲击,2022,41(6):37-43. 被引量：3
5鲍健,陈正寿.细长输流管内外流耦合振动特性研究[J].海洋工程,2022,40(2):78-87. 被引量：9
6王浩杰,陈正寿,鲍健,杜炳鑫,屈绍金.串列弹性双管涡激振动干涉的仿真研究[J].振动与冲击,2022,41(18):210-218.
7张鑫,李国富.双向导流装置水轮机叶片半径和安装位置研究[J].机械强度,2022,44(5):1049-1056.
8李星辉,袁昱超,薛鸿祥,唐文勇.不同流场下含内流立管涡激振动响应特性及Coriolis力效应研究[J].振动与冲击,2023,42(3):165-173.
9李牧皛,刘畅,张平,王福川,刘星,许栋.飞机某种管道随机振动及设计改进研究[J].现代工业经济和信息化,2023,13(1):87-89.
10赵桂欣,孟帅,车驰东,陈俐.解释自由端含集中质量悬臂输流管固有频率计算悖论[J].振动与冲击,2023,42(7):18-24. 被引量：2

1徐建军.道岔控制继电器颤动原因分析及处理[J].科技风,2014(10):49-49.
2袁安存.内河航道跟踪与显迹国际标准[J].船用导航雷达,2010,0(4):25-28.
3郭涛,刘怀汉,万大斌,初秀民,雷国平.长江“智能航道”系统架构与关键技术[J].水运工程,2012(6):140-145. 被引量：18
4杨坚.试验机常见故障及其排除方法[J].标准化报道,2001,22(2):15-16.
5李文辉.EC-120温拌改性沥青高温与疲劳性能试验评价[J].交通科学与工程,2013,29(1):12-16. 被引量：5
6皮映星.桥梁桥面下缺陷检测中RIS地质雷达技术的应用[J].山东工业技术,2015(19):78-78.
7张宇翔,丛军.计中计[J].车主之友,2016,0(5):180-183.
8周宇鹏.沥青老化对TLA改性沥青胶浆高低温性能的影响[J].福建交通科技,2011(3):17-21.
9余波,施晓强,陈钒,计月华.废旧橡胶粉掺量对橡胶沥青高低温及疲劳性能影响研究[J].石油沥青,2015,29(2):30-33. 被引量：9
10张兢,范军.欧盟RIS对我国内河航运信息化建设的启示[J].船海工程,2010,39(5):148-150. 被引量：13

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