Application of a Non-Contact Integrated Salvage Technology in Integral Salvage of Ancient Vessels

doi:10.16183/j.cnki.jsjtu.2023.S1.21

Abstract

Abstract:

In response to the operational requirement of salvage of wreck and cargo without damage during the salvage process, a new non-contact large tonnage integral salvage technology and equipment, i.e., the curved beam system, has been designed and developed, which uses the hydraulic drive technology to achieve automatic installation of beam under the wreck without contact with the wreck during the installation procession, greatly improves the wreck removal efficiency, the operational safety, and the protection of the wreck itself. This technology is suitable for non-contact integral salvage of large tonnage objects of different scales and shapes underwater, including wrecks, aircraft, cargo, etc. It has been successfully applied to the integral salvage of “Yangtze River Estuary II” ancient ship, a major underwater archaeological project in China, providing a technical support for breakthroughs in the underwater salvage technology at home and abroad.

Key words: curved beam, longitudinal beam, launcher, salvage frame, non-contact integral salvage

CLC Number:

U615.9

ZHOU Dongrong, CHEN Shihai, ZHU Xiaodong, HU Jian, WANG Jian, LIU Yu, JIANG Zhe, DAI Qing. Application of a Non-Contact Integrated Salvage Technology in Integral Salvage of Ancient Vessels[J]. Journal of Shanghai Jiao Tong University, 2023, 57(S1): 159-169.

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工况	单元	应力类别	应力最大值/MPa	应力许用值/MPa	最大变形/mm	屈曲特征值/MPa	评估结果
1	壳单元	等效应力	55	295	6	46.19	OK
1	壳单元	剪应力	22	170	6	46.19	OK
2	壳单元	等效应力	199	295	6	11.25	OK
2	壳单元	剪应力	57	170	6	11.25	OK
3	壳单元	等效应力	199.5	295	9.6	10.45	OK
3	壳单元	剪应力	65	170	9.6	10.45	OK
4	壳单元	等效应力	183	295	12	8.32	OK
4	壳单元	剪应力	40	170	12	8.32	OK
5	壳单元	等效应力	250	295	14.5	2.04	OK
5	壳单元	剪应力	115	170	14.5	2.04	OK