Design and Strength Evaluation of Gantry-Type Marine Lashing Structure for Offshore Wind Power Foundations

doi:10.19423/j.cnki.31-1561/u.2025.148

Ship & Boat ›› 2026, Vol. 37 ›› Issue (02): 110-119.DOI: 10.19423/j.cnki.31-1561/u.2025.148

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Design and Strength Evaluation of Gantry-Type Marine Lashing Structure for Offshore Wind Power Foundations

ZHANG Lei^1,2, YANG Yan¹, ZENG Tao², REN Weizhe³, LIU Hongbing^2,*, ZHAO Li¹

1. Shandong Electric Power Engineering Consulting Institute Co., Ltd., Ji'nan 250013, China;
2. Yantai Research Institute, Harbin Engineering University, Yantai 264000, China;
3. College of Shipbuilding Engineering, Harbin Engineering University, Harbin 150001, China

Received:2025-10-01 Revised:2025-11-06 Published:2026-04-28

海上风电基础门架式海运绑扎结构设计与强度评估

张磊^1,2, 杨艳¹, 曾韬², 任维哲³, 刘红兵^2,*, 赵丽¹

1.山东电力工程咨询院有限公司济南 250013;
2.哈尔滨工程大学烟台研究院烟台 264000;
3.哈尔滨工程大学船舶工程学院哈尔滨 150001

通讯作者: 刘红兵（1988—）,男,博士,副教授/硕士生导师。研究方向：船舶与海洋工程结构健康监测与智能运维等。赵丽（1994—）,女,硕士,工程师。研究方向：海上换流站基础结构设计。
作者简介:张磊（1985—）,男,硕士,高级工程师。研究方向：海上风力发电机基础结构设计。杨艳（1995—）,女,硕士,工程师。研究方向：海上风电结构安全监测设计。曾韬（2001—）,男,硕士研究生。研究方向：海上风电装备动力学与安全控制。任维哲（1998—）,男,博士研究生。研究方向：结构健康监测。
基金资助:
山东省自然科学基金（ZR2022QE091）

Abstract

Abstract: Economic globalization has driven the development of China’s manufacturing industry. The rise of major clean energy projects such as offshore wind power has increased the demand for maritime transportation of super-large structures. In view of the problems of poor universality, cumbersome procedures, and high cost faced by the current lashing tools for super-heavy marine modules such as offshore wind power jackets during sea transport, this paper designs a new gantry-type lashing tooling and systematically evaluates its strength and deformation through finite element analysis. The results show that when transporting a typical wind power jacket module, the maximum stress and deformation of the tooling are 236.62 MPa and 2.15 mm, respectively; when transporting an offshore pile module, the values are 110.85 MPa and 1.80 mm, respectively. Both are below the allowable stress of Q355B steel (273.08 MPa). The tooling has reliable strength, strong versatility, and high reusability. It can significantly shorten the lashing preparation cycle for major components such as wind power jackets, reduce the comprehensive transportation cost, and provide a feasible solution for cost reduction and efficiency improvement in the maritime transport of major components within the offshore wind power industry chain.

Key words: offshore wind power jacket, super-heavy marine module, gantry-type tooling, lashing scheme, strength assessment

摘要： 经济全球化推动了我国制造业发展,海上风电等清洁能源重大工程的兴起,带动了超大型结构物海上运输的需求。针对当前海上风电导管架等超重型海工模块在海运绑扎作业中,所用工装通用性差、流程繁琐、成本高昂等难题,该文设计了一种新型门架式绑扎工装,并通过有限元分析系统评估了其强度和变形。研究结果表明：运送典型风电导管架模块时,工装最大应力及变形分别为236.62 MPa、2.15 mm;运送海桩模块时,工装最大应力及变形分别为110.85 MPa、1.80 mm,均低于Q355B钢材许用应力（273.08 MPa）。该工装强度可靠、通用性强、重复利用率高,可显著缩短风电导管架等重大件的绑扎准备周期,降低综合运输成本,为海上风电产业链重大件的海运降本增效提供了可行方案。

关键词: 海上风电导管架, 超重型海工模块, 门架式工装, 绑扎方案, 强度评估

CLC Number:

ZHANG Lei, YANG Yan, ZENG Tao, REN Weizhe, LIU Hongbing, ZHAO Li. Design and Strength Evaluation of Gantry-Type Marine Lashing Structure for Offshore Wind Power Foundations[J]. Ship & Boat, 2026, 37(02): 110-119.

张磊, 杨艳, 曾韬, 任维哲, 刘红兵, 赵丽. 海上风电基础门架式海运绑扎结构设计与强度评估[J]. 船舶, 2026, 37(02): 110-119.

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Design and Strength Evaluation of Gantry-Type Marine Lashing Structure for Offshore Wind Power Foundations

海上风电基础门架式海运绑扎结构设计与强度评估

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