冰区航行中船舶结构冰载荷的现场测量与反演方法研究进展

王键伟; 段庆林; 季顺迎

doi:10.6052/1000-0992-20-007

冰区航行中船舶结构冰载荷的现场测量与反演方法研究进展

doi: 10.6052/1000-0992-20-007

大连理工大学工业装备结构分析国家重点实验室, 辽宁大连 116023

基金项目:

国家重点研发计划重点专项 (2017YFE0111400, 2016YFC1401505, 2016YFC1402706)、装备预研联合基金 (6141B03070108) 和国家自然科学基金 (51639004, 41576179) 资助项目.

详细信息

作者简介:
季顺迎, 大连理工大学工程力学系教授, 博士生导师.现任辽宁省极地海洋工程研究中心主任、国际离散元方法学术委员会委员、美国ASCE工程力学专业委员会颗粒材料分委员会委员、中国力学学会环境力学专业委员会委员、计算力学专业委员会颗粒材料计算力学专业组成员.主要从事计算颗粒力学、极地海洋工程、有砟铁路轨道动力特性、航空航天着陆冲击过程等方面的研究工作.近年来主持国家自然科学基金项目、国家海洋领域公益性项目、国家重点研发计划项目、工信部高技术船舶科研项目等科研课题30余项,出版学术著作2部, 发表期刊学术论文150余篇, 获国家发明专利8项,计算机软件著作权20余项, 省部级奖励5项.

通讯作者:
季顺迎

中图分类号: U663.2
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出版历程
- 收稿日期: 2020-04-17
- 刊出日期: 2020-10-08

Research progress of field measurements and inversion methods of ice loads on ship structure during ice navigation

State Key Laboratory of Structural Analysis for Industrial Equipment, Dalian University of Technology, Dalian 116023, Liaoning, China

More Information

Corresponding author: JI Shunying

摘要

摘要: 冰载荷是影响极地船舶航行安全的重要环境因素,而对船舶结构的现场监测是获取冰载荷的可靠途径.鉴于船-冰相互作用的复杂性, 目前还难以直接测量冰载荷,一般通过结构应变、六自由度运动参数等船舶结构局部或总体响应的测量数据间接反演冰载荷.根据冰载荷的作用范围,本文将船舶结构冰载荷现场监测划分为局部冰载荷现场监测与总体冰载荷现场监测两大类.对国内外18艘极地船舶冰载荷现场测量试验的开展时间、试验海域、测量方案等信息进行了系统的总结和分析.从基本原理、适用范围、应用现状和发展前景等方面全面地介绍了船舶结构冰载荷反演的影响系数矩阵法、支持向量机法、格林函数法、运动参数法和功能关系法,并重点分析了"MV Timofey Guzhenko"极地穿梭油轮与"IBRV Araon"破冰考察船的冰载荷测量结果.在此基础上对船体局部冰压、冰力峰值、冰载荷概率分布和冰激振动加速度等相关研究进展进行了深入的讨论.最后从测量技术、反演方法、冰载荷特性等方面剖析了当前船舶结构冰载荷现场监测中存在的问题,并探讨了相应的研究方向.本文对国内外极地船舶冰载荷现场测量与反演方法的论述可为后续研究与工程应用提供科学参考,从而更好地促进我国极地船舶的抗冰结构设计与冰区航行技术的发展.
- 极地船舶结构 /
- 冰载荷 /
- 现场测量 /
- 反演方法 /
- 冰区航行
Abstract: The ice load is an important environmental factor affecting the navigation safety of polar ships. The field monitoring of ship structure is a reliable approach to obtain the ice load. In view of the complexity of the ship-ice interaction, it is currently difficult to measure the ice load directly. Generally, the ice load is inverted indirectly through the measured data of the local or global response of ship structure, such as structural strains and six-degrees-of-freedom motion parameters. Firstly, according to the action scope of the ice load, the monitoring methods of the ice load on ship structure are divided into two categories in this paper, i.e., those for local ice loads and those for global ice loads. The information such as the date, the area, and the measurement scheme of ice load field measurements for 18 polar ships is systematically summarized and analyzed. Then, five ice load inversion methods for ship structure such as Influence Coefficient Matrix Method, Support Vector Machine Method, Green's Function Method, Motion Parameter Method, and Work-energy Relationship Method are comprehensively introduced from the aspects of fundamental principles, application scope, strengths and weaknesses, application status, and development prospects. The field measurement results of the Arctic shuttle tanker, MV Timofey Guzhenko, and the icebreaking research vessel, IBRV Araon, are emphatically analyzed. On this basis, the related research progress of the local ice pressure, the peak ice force, the probability distribution of ice loads, and the ice-induced vibration acceleration are discussed in depth. Finally, the problems existing in the ice load field monitoring for ship structure are dissected from three aspects, including measurement technology, inversion methods, and ice load characteristics. Moreover, the corresponding research directions are discussed. The review of field measurements and inversion methods of ice loads on ship structure in this paper can provide scientific reference for subsequent research and engineering applications, so as to better promote the development of ice-resistant structure design and ice navigation technology of polar ships in our country.
- polar ship structure /
- ice load /
- field measurement /
- inversion method /
- ice navigation

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参考文献(97)

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