Motion Response of Cylindrical Floating Breakwater Based on AQWA

doi:10.3969/j.issn.1674-0696.2023.05.11

Journal of Chongqing Jiaotong University(Natural Science) ›› 2023, Vol. 42 ›› Issue (5): 85-91.DOI: 10.3969/j.issn.1674-0696.2023.05.11

• Transportation Infrastructure Engineering • Previous Articles

Motion Response of Cylindrical Floating Breakwater Based on AQWA

YUAN Peiyin, LI Yufeng, ZHANG Zhe

(College of Shipping and Marine Engineering, Chongqing Jiaotong University, Chongqing 400074, China)

Received:2021-10-13 Revised:2022-06-01 Published:2023-07-13

基于AQWA的圆筒型浮式防波堤波浪运动响应分析

袁培银，李渝锋，张哲

(重庆交通大学航运与船舶工程学院，重庆 400074)

作者简介:袁培银（1987—），男，黑龙江依安人，副教授，博士，主要从事船舶与海洋结构物方面的研究。E-mail:yuan_pei_yin@163.com
基金资助:
重庆市教委科学技术研究项目（KJZD-K202200703)

Abstract

Abstract: Based on the three-dimensional potential flow theory, the hydrodynamic research of the cylindrical floating breakwater was carried out by the method of numerical analysis, which was by use of the hydrodynamic analysis software AQWA. The amplitude response operators of the breakwater under different wave directions, the additional mass at different water depths, the motion response of the breakwater, and the cable tension were obtained by calculation. The research results show that the sway, surge and heave motions of the proposed floating breakwater are mainly caused by low-frequency motions. Since the mooring lines are mostly bow and stern lines, the amplitude of the surge motion of the floating body in the time domain is relatively small, which is one order of magnitude smaller than the amplitude of the sway and heave motions.

Key words: port engineering; three-dimensional potential flow theory; floating breakwater; amplitude response operator; additional mass

摘要： 利用水动力分析软件AQWA，基于三维势流理论，采用数值分析法对圆筒型浮式防波堤进行了水动力研究；计算得到了不同浪向下的防波堤幅值响应算子、不同水深下的附加质量、防波堤运动响应和缆索张力。研究结果表明：本浮式防波堤横荡、纵荡与垂荡运动主要由低频运动引起；由于系泊缆多为艏缆和艉缆，因而浮体纵荡运动时域幅值较小，相较横荡与垂荡的运动幅值小一个数量级。

关键词: 港口工程；三维势流理论；浮式防波堤；幅值响应算子；附加质量

CLC Number:

U653.4

YUAN Peiyin, LI Yufeng, ZHANG Zhe. Motion Response of Cylindrical Floating Breakwater Based on AQWA[J]. Journal of Chongqing Jiaotong University(Natural Science), 2023, 42(5): 85-91.

袁培银，李渝锋，张哲. 基于AQWA的圆筒型浮式防波堤波浪运动响应分析[J]. 重庆交通大学学报（自然科学版）, 2023, 42(5): 85-91.

References

［1］何梦程，白兴兰.新型箱—板组合浮式防波堤的水动力分析［J］.浙江海洋大学学报(自然科学版)，2018，37(2)：158-164.
HE Mengcheng, BAI Xinglan. Hydrodynamic analysis of the new composite pontoon-plate floating breakwater ［J］. Journal of Zhejiang Ocean University (Natural Science), 2018, 37(2): 158-164.
［2］ JI Chunyan, GUO Yuchan, CUI Jie, et al. 3D experimental study on a cylindrical floating breakwater system ［J］. Ocean Engineering, 2016, 125: 38-50.
［3］任慧龙，杜娟，马山，等.浅水单模块浮式防波堤锚泊系统分析研究［J］.船舶工程，2015，37(12)：87-91.
REN Huilong, DU Juan, MA Shan, et al. Analysis and study of single-module floating breakwater mooring system in shallow water ［J］. Ship Engineering, 2015, 37(12): 87-91.
［4］ PAPATHANASIOU T K, KARPERAKI A, BELIBASSAKIS K A. Finite element simulation of long wave impact on floating breakwaters with variable stiffness ［J］. IOP Conference Series: Materials Science and Engineering, 2017, 276: 1-13.
［5］ TABATABAEI S M R, ZERAATGAR H. Parametric comparison of rectangular and circular pontoons performance as floating breakwater numerically ［J］. Polish Maritime Research, 2018, 25(Sup1): 94-103.
［6］陈城，陈新权，杨启，等.翼板浮式防波堤消波性能［J］.水运工程，2022(9)：8-14.
CHEN Cheng, CHEN Xinquan, YANG Qi, et al. Wave suppression-performance of wing-plate floating breakwater ［J］. Port and Waterway Engineering, 2022(9): 8-14.
［7］葛江涛，嵇春艳，郭建廷，等.弧型布置的浮式防波堤水动力响应分析［J］.船舶工程，2021，43(9)：152-157.
GE Jiangtao, JI Chunyan, GUO Jianting, et al. Hydrodynamic response analysis of floating breakwater with arc arrangement ［J］. Ship Engineering, 2021, 43(9): 152-157.
［8］桂劲松，张可新，夏曦.透空式开孔防波堤水动力特性的数值研究［J］.水动力学研究与进展(A辑)，2020，35(5)：584-591.
GUI Jinsong, ZHANG Kexin, XIA Xi. Numerical study on hydrody-namic characteristics of perforated Pile-supported vertical wall break-water［J］. Chinese Journal of Hydrodynamics, 2020, 35(5): 584-591.
［9］ LOUKOGEORGAKI E, YAGCI O, KABDASLI M. 3D experimental investigation of the structural response and the effectiveness of a moored floating breakwater with flexibly connected modules ［J］. Coastal Engineering, 2014, 91: 164-180.
［10］刘心媚，郑艳娜，姜云鹏，等.锚泊方式对开孔浮式防波堤消浪性能和锚链力影响的试验研究［C］∥第29届全国水动力学研讨会论文集.北京：海洋出版社，2018.
LIU Xinmei, ZHENG Yanna, JIANG Yunpeng, et al. Experimental study on the wave dissipation performance and mooring force of opening floating breakwater ［C］∥Proceeding of the 29th National Congress on Hydrodynamics. Beijing: China Ocean Press, 2018.
［11］田永进.柔性多浮筒防波堤水动力特性试验研究［D］.大连：大连理工大学，2016.
TIAN Yongjin. Experimental Investigation on the Hydrodynamic Characteristics of Flexible Multi-buoy Breakwater ［D］. Dalian: Dalian University of Technology, 2016.
［12］程俊峰.双挡板桩基透空式防波堤水动力特性研究［D］.大连：大连理工大学，2022.
CHENG Junfeng. Study on Hydrodynamic Characteristics of Double Baffle Pile Foundation Open-type Breakwater ［D］. Dalian: Dalian University of Technology, 2022.
［13］张万威，陈国平，严士常，等.单挡板桩基透空堤的透浪系数物理模型试验［J］.水运工程，2022(6)：9-16.
ZHANG Wanwei, CHEN Guoping, YAN Shichang, et al. Physical model test of wave transmission coefficient of permeable dike with single-baffle pile foundation ［J］. Port and Waterway Engineering, 2022(6): 9-16.
［14］马泽坤.基于AQWA的FPSO拖航安全研究［D］.大连：大连海事大学，2018.
MA Zekun. Research on the Towing System Safety of FPSO Based on AQWA ［D］. Dalian: Dalian Maritime University, 2018.
［15］方昭昭.数值波浪水池中船舶辐射绕射的数值模拟［D］.上海：上海交通大学，2011.
FANG Zhaozhao. Numerical Simulation on Radiation and Diffraction of Ships in Numerical Wave Tank ［D］. Shanghai: Shanghai Jiaotong University, 2011.
［16］段若衡.基于AQWA模拟软件的港内渔船系泊可靠性研究［D］.北京：北京工业大学，2019.
DUAN Ruoheng. Research on Mooring Reliability of Fishing Vessels in Ports Based on AQWA Simulation Software ［D］. Beijing: Beijing University of Technology, 2019.

Motion Response of Cylindrical Floating Breakwater Based on AQWA

基于AQWA的圆筒型浮式防波堤波浪运动响应分析

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics