In order to investigate the contact status between after stern tube bearing and propeller shaft of large merchant ships in static condition, the FE model of shaft alignment for propulsion shaft was built by beam element, where the stern tube bearing was divided into several sections. As non-linear support boundary condition of beam element, both Hertz and Winkler elastic contact model were used to simulate contact status between each shaft bearing and shaft. The FE model was solved by iterative method. In accordance with the calculation results, it was revealed that two methods had similar outcomes in the contact area of after stern tube bearing, but the contact stiffness of Winkler contact model, with smaller contact area and more concentrative force, was higher than Hertz contact model. And the contact area of Hertz contact model was larger, and could not fulfil the prerequisite of Hertz contact model, so it might result in limitation in after stern tube bearing contact calculation.
YANG Hongjun1,LU Fei1,CHE Chidong2
. Alignment Calculation for Ship Propulsion Shaft Based on
Segmentation Elastic Contact Theory of After Stern Tube Bearing[J]. Journal of Shanghai Jiaotong University, 2018
, 52(6)
: 681
-686
.
DOI: 10.16183/j.cnki.jsjtu.2018.06.008
[1]国防科学技术工业委员会.CB/Z 338-2005 船舶推进轴系校中[S].北京:中国标准出版社,2005.
Commission of Science, Technology and Industry for National Defense. CB/I338-2005 Propulsion shaft alignment of ship[S]. Beijing: Standards Press of China, 2005.
[2]DNV GL AS. Rules for classification ships[M]. Oslo, Norway: DNV GL AS, 2016: 29-37.
[3]NIPPON KAIJI KYOKAI. Shaft alignment guidelines[M].Tokyo, Japan: NIPPON KAIJI KYOKAI, 2006.
[4]张敏, 张广辉, 刘占生.大型船舶推进轴系校中多点非线性弹性支承模型研究[J].船舶力学, 2016, 20(1/2): 176-183.
ZHANG Min, ZHANG Guanghui, LIU Zhansheng. Research on large ship propulsion shafting alignment multi-nonlinear-elastic support model[J]. Journal of Ship Mechanics, 2016, 20(1/2): 176-183.
[5]BUREAU VERITAS. Elastic Shaft Alignment[M]. France: BUREAU VERITAS, 2015: 7-15.
[6]STACHOWIAK G W, BATCHELOR A W. Engineering Tribology[M]. 2nd ed. Boston, USA: Butterworth Heinemann, 2000: 294-296.
[7]李潇, 王宏志, 李世萍, 等. 解析型Winkler弹性地基梁单元构造[J]. 工程力学, 2015, 12(3): 66-72.
LI Xiao, WANG Hongzhi, LI Shiping, et al. Element for beam on winkler elastic foundation based on analytical trial functions[J]. Engineering Mechanics, 2015, 12(3): 66-72.
[8]李顺群, 郑刚.复杂条件下Winkler地基梁的解析解[J].岩土工程学报, 2008, 30(6): 873-879.
LI Shunqun, ZHENG Gang. Analytic solution of beams on winkler foundation under complex conditions[J]. Chinese Journal of Geotechnical Engineering, 2008, 30(6): 873-879.
[9]宿月文, 陈渭, 郭彩霞.应用Winkler弹性基础模型的间隙铰接副磨损预测[J].摩擦学报, 2012, 32(4): 320-324.
SU Yuewen, CHEN Wei, GUO Caixia. Wear prediction of clearance revolute joints using winkler surface model[J]. Tribology, 2012, 32(4): 320-324.
