夹层板具有优越的力学性能,能够迎合未来海军舰船结构发展的需求,但夹层板连接结构成为限制其在舰船设计中应用的重要因素。本文基于折叠式夹层板系统地研究了夹层板面内连接结构优化设计方法,提出了夹层板连接结构设计原则,在此基础上提出了4种折叠式夹层板面内连接结构概念设计方案,并基于折叠式夹层板结构尺寸提出了面内连接结构初步设计方案,并基于此分别开展了面内连接结构尺寸优化设计和形式优化设计,最终基于综合评分法确定了最优的面内连接结构设计方案,并提出了用于指导夹层板面内连接结构设计的优化设计方法。
Sandwich panels with superior mechanical properties can meet the needs of future warship structure development. But sandwich panel connections always restrict the application of sandwich panels in ship structure. In this paper, the structure optimize design methods of sandwich panels in-plane connections were studied and proposed based on folded core sandwich pannels. The design principles of new sandwich panels in-plane connections were raised. And four sandwich panels in-plane connections concept design schemes were raised, and the preliminary dimension schemes of them were designed based sandwich pannels dimensions. Then optimize design of connections dimensions and types were studied and the optimal scheme was determined. Finally, the optimize design methods of new sandwich panels in-plane connections were raised.
2019,41(11): 27-36 收稿日期:2018-10-22
DOI:10.3404/j.issn.1672-7649.2019.11.006
分类号:U661
基金项目:海装“十三五”预研资助项目
作者简介:王果(1988-),男,硕士,工程师,从事舰船设计工作
参考文献:
[1] 岳灿甫, 吴始栋. 国外船用激光焊接波纹夹芯板的开发与应用[J]. 鱼雷技术, 2007, 15(4):1-5
[2] NOURY P., HAYMAN B., McGEORGE D., et al. Lightweight construction for advanced shipbuilding-recent development[R]. The BONDSHIP and the SANDWICH European co-operative research projects, part of the 5th Framework, GROWTH, and the EUCLID RTP3.21 project, a European military research project.
[3] STEFANICK K. M. Laser welded lightweight sandwich panel and fabrication and shipyard application[R]. Concurrent Technologies Corporation.
[4] GALANIS K. Hull construction with composite materials for ships over 100m in length[D]. Massachusetts Institute of Technology, 2002–07.
[5] CACCESE V, YORULMAZ S. Laser welded steel sandwich panel bridge deck development:finite element analysis and stake weld strength tests[R]. C2006-014-RPT-01, University of Maine, Department of Mechanical Engineering, 5711 Boardman Hall 212, Orono, ME, 04469–5711.
[6] LR. Sandwich panel fabrication technology[S]. Lloyd's Register Quality Company. 2001.
[7] JUKKA, TERO, OUTOKUMPU. A review in design and manufacturing of stainless steel sandwich panels[J]. Automotive, 2004(9):21–24.
[8] 张延昌, 王自力, 张世联. 折叠式夹芯层结构耐撞性能研究[J]. 船舶力学, 2010, 14(1-2):114-120
[9] 王果, 张延昌. Y型激光焊接夹层板抗爆性能分析[J]. 舰船科学技术, 2012, 34(2):68-75
[10] TILBROOK M.T., RADFORD D.D., DESHPANDE V.S. Dynamic crushing of sandwich panels with prismatic lattice cores[J]. International Journal of Solids and Structures, 2007, 44:6101-6123
[11] COTé F., DESHPANDE V.S., FLECK N.A., et al. The out-of-plane compressive behavior of metallic honeycombs[J]. Materials Science and Engineering A, 2004, 380:272-280
[12] ZHANG Yanchang, ZHANG Shilian, WANG Zili, et al. Quasi-static compressive behavior of U-type corrugated cores sandwich panels[J]. Journal of Ship Mechanics, (in press)
[13] 梁军, 刘均, 程远胜. 冲击载荷作用下方形蜂窝夹层板塑性动力响应分析[J]. 船舶力学, 2010, 14(10):1165-1172
[14] ROLAND F, REINERT T, MEYER GMBH J. L., et al. Laser welded sandwich panels for the shipbuilding industry[R]. RINA-Bericht-ENDV-24-7-00.
[15] 王自力, 张延昌. 基于夹层板单壳船体结构耐撞性设计[J]. 中国造船, 2008, 49(1):60-65
[16] 张延昌, 王自力, 顾金兰, 等. 夹层板在舰船舷侧防护结构中的应用[J]. 中国造船, 2009, 50(4):36-44
[17] 王自力, 张延昌, 顾金兰. 基于夹层板抗水下爆炸舰船底部结构设计[J]. 舰船科学技术, 2010, 32(1):22-27
[18] 王果, 胡宗文, 王自力, 等. 夹层板面内连接结构力学性能数值仿真分析[J]. 舰船科学技术, 2014, 36(6):54-59
[19] 吴贵生. 试验设计与数据处理[M]. 北京:冶金工业出版社, 1997.
