海洋电缆中关键力学问题的研究进展与展望

阎军; 胡海涛; 苏琦; 尹原超; 吴尚华; 卢海龙; 卢青针

doi:10.6052/0459-1879-22-113

海洋电缆中关键力学问题的研究进展与展望

doi: 10.6052/0459-1879-22-113

阎军^{*, †},
胡海涛^{*, †},
苏琦^*,
尹原超^*,
吴尚华^**,
卢海龙^*,
卢青针^{†, **,}

*.
大连理工大学工程力学系, 工业装备结构分析国家重点实验室, 辽宁大连 116024
†.
大连理工大学宁波研究院, 浙江宁波 315016
**.
大连理工大学海洋科学与技术学院, 辽宁盘锦 124221

基金项目: 国家自然科学基金(U1906233)和山东省重点研发计划(2019JZZY010801)资助项目

详细信息

作者简介:
卢青针, 副教授, 主要研究方向: 海洋柔性管缆的结构测试. E-mail: luqingzhen@dlut.edu.cn

中图分类号: P756.1
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- 文章访问数: 769
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- 被引次数: 0
出版历程
- 收稿日期: 2022-03-21
- 录用日期: 2022-04-07
- 网络出版日期: 2022-04-08
- 刊出日期: 2022-04-18

PROSPECT AND PROGRESSION OF KEY MECHANICAL PROBLEMS IN MARINE CABLES

Yan Jun^{*, †},
Hu Haitao^{*, †},
Su Qi^*,
Yin Yuanchao^*,
Wu Shanghua^**,
Lu Hailong^*,
Lu Qingzhen^{†, **
,}

*.
State Key Laboratory of Structural Analysis for Industrial Equipment, Department of Engineering Mechanics, Dalian University of Technology, Dalian 116024, Liaoning, China
†.
Ningbo Research Institute of Dalian University of Technology, Ningbo 315016, Zhejiang, China
**.
School of Ocean Science and Technology, Dalian University of Technology, Panjin 124221, Liaoning, China

摘要

摘要: 海洋能源是当今世界各国竞相开发的关键领域. 海洋电缆是连接海洋能源生产系统各设施的能源传输、生产控制的关键装备之一, 被誉为海洋能源开发的“生命线”. 如何设计海洋电缆能够抵抗极端海洋灾害, 同时满足安装、服役中弯曲柔顺性的要求, 实现“刚柔并济”的结构性能, 是海洋能源开发领域亟待解决的核心难题. 本文围绕海洋电缆多构件、多层螺旋缠绕的结构特点, 全面总结了海洋电缆设计、分析及测试领域关键力学问题的研究进展. 首先, 针对海洋电缆结构的理论分析, 阐述了拉伸、扭转和弯曲刚度的基本理论以及拉扭耦合和非线性弯曲行为研究进展. 其次, 介绍了数值仿真方法在海洋电缆工程中的应用, 特别介绍了海洋电缆数值分析专业软件方面的研究成果. 再次, 探讨了海洋电缆多场耦合分析、结构优化设计和疲劳寿命的计算方法. 最后详细介绍了海洋电缆结构的实验测试技术和测试装备. 本文通过对海洋电缆研究方法和研究热点的详细综述, 揭示了该领域的主要研究方法和关键技术难点, 并展望了海洋电缆未来发展的主要技术需求和研究方向. 上述工作对海洋电缆在我国海洋油气能源开发中的高可靠性工程应用提供了基础理论和技术参考.
- 海洋电缆 /
- 理论方法 /
- 有限元仿真 /
- 优化设计 /
- 实验测试
Abstract: Marine energy is a key area that countries around the world are competing to develop today. Marine cable connecting various facilities of marine energy production system is one of the key equipment for energy transmission and production control and is known as the “lifeline” in marine energy development. Designing marine cables that can resist extreme marine environments, meet the requirements of bending flexibility in installation and service, and achieve structural performance with “rigid and flexible”, is the core challenge to be addressed in the field of marine energy development. This paper discusses the structural characteristics of multi-component and multi-layer spiral winding of marine cables, and comprehensively summarizes the research progress of key mechanical issues in the field of marine cable design, analysis and testing. Firstly, for the theoretical analysis method of marine cable, the general theories of tension, torsion and bending stiffness, and the research advances of the tension-torsion coupling mechanism and nonlinear bending behavior are described. Secondly, the application of numerical simulation methods in marine cable engineering is introduced, especially the research results of purpose-built simulation software for numerical analysis of marine cables. Thirdly, the multi-field coupling analysis, optimum structural design and fatigue life calculation method of marine cables are discussed. Finally, the test technology and test equipment for marine cables are introduced in detail. Through a detailed summary of research methods and hotspots of marine cables, this paper reveals the main research methods and key technical difficulties in this field, and looks forward to the main technical requirements and research directions of marine cables for future development. The above summary provides basic theory and technical reference for the high reliability engineering application of marine cables in China's offshore oil and gas energy development.
- marine cable /
- theoretical method /
- finite element simulation /
- optimization design /
- experimental test

HTML全文

图 1 海洋电缆的主要应用类型^[2]

Figure 1. Main application types of marine cables^[2]

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图 2 海洋电缆典型螺旋缠绕结构示意图^[4]

Figure 2. Illustration of a typical multilayer helically wound power cable^[4]

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图 3 海洋电缆专用设计软件UCD

Figure 3. Design software UCD for marine cables

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图 4 20 MPa外压下总变形分布图^[63]

Figure 4. Total deformation distribution at 20 MPa external pressure^[63]

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图 5 海洋电缆疲劳寿命预测流程图^[64]

Figure 5. Fatigue life calculation flow of marine cables^[64]

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图 6 海洋电缆的三种典型不确定性因素

Figure 6. Three uncertain factors for marine cables

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图 7 海洋电缆结构优化设计流程图

Figure 7. The flowchart of structure optimization design of marine cables

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图 8 Qualisys^®光学测试系统^[98]

Figure 8. Optical instrumentation using the Qualisys^® system^[98]

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图 9 径向位移测量系统^[99]

Figure 9. Radial displacement measure system^[99]

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图 10 折弯法测量弯曲刚度^[29,100]

Figure 10. Schematic of bending test^[29,100]

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图 11 四点弯法测量弯曲刚度^[97]

Figure 11. Schematic of four point bending test^[97]

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图 12 悬臂梁法测量弯曲刚度^[52,103]

Figure 12. Schematic of cantilever bending test^[52,103]

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图 13 螺旋缠绕结构外层钢丝应变测量^[97]

Figure 13. Strain measurement of outer tensile armor wires of multi-layer helical wound structure^[97]

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图 14 螺旋缠绕结构铠装钢丝光纤测量^[108]

Figure 14. Optical fiber measurement method of armored steel wire of multi-layer helical wound structure^[108]

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图 15 SINTEF疲劳试验机^[108]

Figure 15. SINTEF fatigue test rig arrangement^[108]

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图 16 大连理工大学疲劳试验机^[110]

Figure 16. DUT fatigue testing machine^[110]

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