集中冰载工况下的桨叶边缘强度校核方法

doi:10.16183/j.cnki.jsjtu.2020.01.002

上海交通大学学报 ›› 2020, Vol. 54 ›› Issue (1): 10-19.doi: 10.16183/j.cnki.jsjtu.2020.01.002

集中冰载工况下的桨叶边缘强度校核方法

叶礼裕，王超，郭春雨，常欣

哈尔滨工程大学船舶工程学院，哈尔滨 150001

出版日期:2020-01-28 发布日期:2020-01-16
通讯作者: 王超，副教授，博士生导师，电话(Tel.): 0451-82568486；E-mail:wangchao806@hrbeu.edu.cn.
作者简介:叶礼裕(1989-)，男，福建省尤溪县人，讲师，现主要从事极地船舶推进器设计及性能评估研究.
基金资助:
国防基础科研计划（JCKY2016604B001），国家自然科学基金（51809055, 51679052, 51639004），中国博士后科学基金（2019M651266），黑龙江省博士后科学基金（LBH-Z18051）资助项目

Strength Check Method of Blade Edge Under Concentrated Ice Load Condition

YE Liyu,WANG Chao,GUO Chunyu,CHANG Xin

College of Shipbuilding Engineering, Harbin Engineering University, Harbin 150001, China

Online:2020-01-28 Published:2020-01-16

摘要/Abstract

摘要： 在冰区桨设计过程中，往往需要对其桨叶边缘区域进行强度校核，防止与冰块接触过程中桨叶边缘出现缺口，对螺旋桨的水动力、空泡、噪声等性能产生影响.为了能够快速实现桨叶边缘强度校核，基于IACS URI3规范和有限元法(FEM)，建立了集中冰载工况下的桨叶边缘强度校核方法.针对螺旋桨几何结构特殊性，将桨叶沿径向、弦向以及厚度方向划分成一系列八节点六面体单元，发展了螺旋桨有限元网格自动剖分方法，可以根据加载位置合理地进行网格划分，以FEM计算集中冰载作用下的桨叶应力和变形分布.以PC3级冰区桨为例，开展了桨叶边缘强度的分析和校核.计算结果表明：在集中冰载作用下桨叶边缘区域有较大应力集中，容易造成桨叶边缘区域的损坏.

关键词: 强度校核, 桨叶边缘, 集中冰载, 有限元法(FEM), 应力分布

Abstract: During the design process of ice-class propellers, it is necessary to check the blade edge strength to avoid the gap on the blade under ice contact, which may affect the propeller performance of hydrodynamic force, cavitation, noise, etc. To quickly check the blade edge strength, based on the rules in IACS URI3 and the finite element method (FEM), the strength check method of blade edges is established under the concentrated ice load conditions. Considering the particularity of the propeller, an automatic meshing method has been developed by dividing the propeller into many 8-node hexahedron elements along radial, chordwise and thickness directions, which can help to mesh the propeller blades reasonably according to the loading position. The FEM is applied to calculate the stress and deformation distributions of the propeller blade under the concentrated ice load. Taking the PC3 ice-class propeller as an example, the blade edge strength is analyzed and checked. The results show that large stress is concentrated on the blade edge which is prone to cause the damage.

Key words: strength check, blade edge, concentrated ice load, finite element method (FEM), stress distribution

中图分类号:

U 661.31

叶礼裕, 王超, 郭春雨, 常欣. 集中冰载工况下的桨叶边缘强度校核方法[J]. 上海交通大学学报, 2020, 54(1): 10-19.

YE Liyu, WANG Chao, GUO Chunyu, CHANG Xin. Strength Check Method of Blade Edge Under Concentrated Ice Load Condition[J]. Journal of Shanghai Jiaotong University, 2020, 54(1): 10-19.

参考文献

［1］BROUWER J, HAGESTEIJN G, BOSMAN R. Propeller-ice impacts measurements with a six-component blade load sensor［C］//Third International Symposium on Marine Propulsors. Launceston, Tasmania, Australia: VTT, 2013: 47-54. ［2］DNV. Ice strengthening of propulsion machinery: No. 51.1 ［S］. Hvik, Norway: DNV, 2010. ［3］华汉金. 冰区加强型新叶型剖面螺旋桨开发研究［J］. 船舶, 1996(1): 17-20. HUA Hanjin. Development and study for propeller with new profile and ice strengthening［J］. Ship & Boat, 1996(1): 17-20. ［4］NORHAMO L, BAKKEN G M, DEINBOLL O, et al. Challenges related to propulsor: Ice interaction in arctic waters ［C］//First International Symposium on Marine Propulsors. Trondheim, Norway: VTT, 2009: 1-9. ［5］LEE S K. Ice controllable pitch propeller: Strength check based on IACS polar class rule［C］//IceTech Conference. Banff, Alberta, Canada: ABS, 2008: 119-127. ［6］LEE S K. Engineering practice on ice propeller strength assessment based on IACS polar ice rule: UR13［C］//10th International Symposium on Practical Design of Ships and Other Floating Structures. Houston, TX, USA: ABS, 2007: 219-228. ［7］孙自力. 船舶用螺旋桨原理及修理［M］. 哈尔滨: 哈尔滨工程大学出版社, 2010. SUN Zili. Principle and repair for ship propeller［M］. Harbin, Harbin Engineering University Press, 2010. ［8］叶礼裕, 王超, 李鹏, 等. BEM/FEM耦合螺旋桨静强度计算方法［J］. 中国舰船研究, 2017, 12(5): 64-74. YE Liyu, WANG Chao, LI Peng, et al. Calculation of marine propeller static strength based on coupled BEM/FEM［J］. Chinese Journal of Ship Research, 2017, 12(5): 64-74. ［9］赵均海, 汪梦甫. 弹性力学及有限元［M］. 武汉: 武汉理工大学出版社, 2003. ZHAO Junhai, WANG Mengfu. Elasticity and finite element［M］. Wuhan: Wuhan University of Technology Press, 2003. ［10］WALKER D L N. The influence of blockage and cavitation on the hydrodynamic performance of ice class propellers in blocked flow［D］. St. John’s, Newfoundland, Canada: Memorial University of Newfoundland, 1996. ［11］YE L Y, WANG C, CHANG X, et al. Propeller-ice contact modeling with peridynamics［J］. Ocean Engineering, 2017, 139: 54-64. ［12］王锡栋. 极地船舶与推进装置的冰载荷数值预报分析［D］. 哈尔滨: 哈尔滨工程大学, 2017. WANG Xidong. Numerical analysis of ice load on polar ship and propulsion device［D］. Harbin: Harbin Engineering University, 2017. ［13］常欣, 李鹏, 王超, 等. 冰载荷和纵倾角对螺旋桨强度的影响［J］. 中国舰船研究, 2018, 13(4): 7-15. CHANG Xin, LI Peng, WANG Chao, et al. Effect of ice-load and trim angle on the strength of propeller［J］. Chinese Journal of Ship Research, 2018, 13(4): 7-15. ［14］肖翀, 覃文洁, 左正兴. 曲轴应力场有限元计算单元类型和尺寸对计算精度和规模的影响［J］. 柴油机, 2004, 26(Sup.): 176-178. XIAO Chong, QIN Wenjie, ZUO Zhengxing. Influence of element-form and element-size on FE calculation of crankshaft stress field［J］. Diesel Engine, 2004, 26(Sup.): 176-178.

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集中冰载工况下的桨叶边缘强度校核方法

Strength Check Method of Blade Edge Under Concentrated Ice Load Condition

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