With the increasing importance of the function of the shipboard pipelines, anti-shock resistance has been paid more and more attention.In order to understand the dynamic response characteristics of typical components in pipelines, a space pipelines for TA2 materials was designed and established.Under four identical standard checking conditions which contain different pipe clamp type and position were tested on an impact tester.The test results show that the flange has great influence on the impact response of pipelines.The vibration and shock resistance of pipelines can be reduced by using elastic pipe clamps and arranging position.The conclusion provides the basis for optimal design of the shock resistance of the pipelines.
冯麟涵1,韩璐1,2,闫明2,张磊1,张驰1,2. 典型部件对舰船管路系统抗冲击性能影响研究[J]. 振动与冲击, 2020, 39(4): 261-265.
FENG Linhan1, HAN Lu1,2, YAN Ming2, ZHANG Lei1, ZHANG Chi1,2. A study on the impact of typical components on the anti-shock resistance of shipboard pipelines. JOURNAL OF VIBRATION AND SHOCK, 2020, 39(4): 261-265.
[1] 陈刚, 汪玉 李兆俊. 国内外舰船管路系统抗冲击技术工作述评[J]. 振动与冲击,2007,4(26):58-63.
CHEN Gang, WANG Yu, LI Zhao-le. Commentary on anti-shock technology of naval vessl piping system at home and abroad[J]. Journal of vibration and shock, 2007,4(26):58-63.
[2]Gaberson H A. Classification of violent environments that cause equipment failure[J]. Sound and Vibration, 2000, 34(5): 16-23.
[3] MIL-S-901D, Shock Test, H.I.(High Impact) Shipboard Machinery Equipment and Systems, Requirement for[S.]. United States Department of Defense,1989.
[4] Dennis Harold Peters. Shock loads on piping systems[D]. Monterey: Naval postgraduate School, 1972: 43-44.
[5] Sbingen Bjomar Fluid structure interaction in piping systems. Norges teknisk-naturviten universite(Norway),1996.
[6] 沈中祥, 刘寅东, 郑婷婷. 舰船管路系统抗冲击设计及性能分析[J]. 舰船科学技术, 2017, 5(39): 109-115.
SHEN Zhong-xiang, LIU Yin-dong, ZHENG Ting-ting. Design for shock resistance of piping system of naval and performance analysis[J]. Ship science and technology. 2017, 5(39): 109-115.
[7] 王朝. 典型管路系统抗冲击性能分析方法新型抗冲击元器件设计研究[D]. 江苏: 江苏科技大学. 2013年.
WANG CHAO. Research on the anslysis of the impact resistance of typical pipe system design of a new type of anti-shock device[D]. Jiangsu: Jiangsu university of Science and Technology.
[8] 冯麟涵, 王路, 计晨. 舰船管路抗冲击设计与评估方法[J].兵工学报. 2015, 1(36): 54-60.
FENG Lin-han, WANG LU, JI Chen. Method for shock resistance design and assessment of shipboard pipelines[J]. Acta armamentaria, 2015, 1(36): 54-60.
[9] 杜鑫, 杜俭业, 汪玉. 船舶管道抗冲减振优化[J].哈尔滨工程大学学报.2011,32(6):697-701.
DU XIN, DU Jian-ye, WANGYU. A study of anti-shock waves and decreasing vibration on the pipes of a ship[J]. Journal of Harbin Engineering University. .2011,32(6):697-701.
[10] 汪玉, 华宏星. 舰船现代冲击理论及应用[M]. 北京: 科学出版社, 2005: 1-16,66-68.WANG YU, HUA Hong-xing. Modern ship impact theory and application[M]. Beijing: Science press, 2005: 1-16,66-68.
[11] 郭君, 郭俊辰, 赵勋, 王美婷. 舰船大规模管系抗冲击评估方法研究[D]. 第十二届全国振动理论及应用学术会议. 南宁: 中国振动工程学会,2017.
GUO Jun, GUO Jun-chen, ZHAO Xun, WANG Mei-ting. Impact resistance study of ship’s large scale pipe system[D]. China conference, 2017.
[12] 宋敬利, 焦安龙, 沈晓乐. 浮动冲击平台海上爆炸试验实施方法[J]. 爆破,2014,31(4):103-106.
SONG Jing-li, JIAO An-long, SHEN Xiao-le. Implementation of floating platform explosion test[J].Blasting, 2014,31(4):103-106.
[13] Okeil Ayman Mohamed. Nonlinear Inelastic Seismic Behavior of Piping Systems[D].North Carolina State University,1995.
14] 张海丽. TA2工业纯钛在海水管系中的应用研究[D]. 南京: 南京航空航天大学, 2010.
ZHANG Hai-li. Study on application of TA2 industrial Pure titanium on seawater piping system[D].Nanjing: Nanjing University of aeronautics and astronautics,2010.
[15] 舰船管路抗冲击设计及评估方法[S].2013.
Methods of shock resistance design and assessment of shup pipe system[S].2013.
[16] BV043, Shock Resistance Specification for Bundeswehr Ships[S]. German Federal Office For Military Technology and Procurement,1985.
