船-泵相互作用对喷水推进器推进性能的影响

摘要/Abstract

摘要： 摘要：为研究喷水推进船快速性预报中船体与喷水推进器相互作用机理，借助于计算流体力学（CFD）方法研究船泵相互作用对喷水推进器推进性能的影响.通过计算由kε湍流模型封闭的RANS方程，分别得到敞水条件下和考虑船体斜升角、纵倾等因素影响的装船后喷水推进器的三维黏性流场,敞水条件下计算结果与试验数据的良好吻合验证了数值模型和方法的可信性.不同斜升角和纵倾模型计算结果表明：船体斜升角和横倾对喷水推进器推进性能影响很小；船体尾升角和纵倾角的变化改变了船体边界层，对喷水推进器推进性能和作用因子影响很大；纵倾角由正变负，喷水推进器对船体边界层的利用增强，使流量变小，功率、推力和扬程变大；进流动量系数、进流能量系数、动量作用效率和能量作用效率均减小.喷水推进器也反作用于船体，产生使船体纵倾角减小的力矩.

关键词: 船舶, 喷水推进器, 相互作用, 作用因子, 计算流体力学

Abstract: Abstract： The computational fluid dynamics(CFD) method was used to study the influence of hullwaterjet interaction on propulsion performances of waterjet to research hullwaterjet interaction mechanism needed in speed and resistance prediction of waterjet propelled vessel. The threedimensional viscous flow fields of waterjets under openwater condition and mounted on hull with different deadrise angles and trim were obtained by calculating RANS equations closed by the kε turbulence model. The creditability of numerical model and method was validated by the good agreement between calculated results and test data. The results of different deadrise angle or list models showed that the deadrise angle or list had hardly any effect on the propulsion performance of waterjet. The results of different rocker angle or trim models showed that the rocker angle and trim made the hull boundary layer change, and had a notable influence on the propulsion performance and effect factors of the waterjet. With trim angle changing from positive to negative, the utilization of hull boundary layer by the waterjet increased, so the mass flow through waterjet decreased; however, the power, thrust and head increased. Besides, the momentum velocity coefficient, energy velocity coefficient, momentum interaction efficiency and energy interaction efficiency were decreased, too. However, the waterjet counteracted the hull by producing torque to whittle the trim angle.

Key words: ship, waterjet, interaction, effect factor, computational fluid dynamics

中图分类号:

U 664.3

刘承江1，王永生1，古成中2. 船-泵相互作用对喷水推进器推进性能的影响[J]. 上海交通大学学报（自然版）, 2016, 50(01): 91-97.

LIU Chengjiang1,WANG Yongsheng1,GU Chengzhong2. Influence of HullWaterjet Interaction on Propulsion Performances of Waterjet[J]. Journal of Shanghai Jiaotong University, 2016, 50(01): 91-97.

参考文献

［1］ALLISON J L. Marine waterjet propulsion ［J］. SNAME Transactions,1993,101:275335. ［2］van Terwisga Tom J C. Waterjethull interaction ［D］. Delft: Delft University of Technology, 1996. ［3］JOHN Purnell. Waterjet selfpropulsion model test for application to a highspeed sealift ship ［R］. Severna: CDI Marine Company, 2007. ［4］BULTEN N. Numerical analysis of a waterjet propulsion system［D］. Eindhoven, The Netherlans: The Eindhoven University of Technology, 2006. ［5］TAKANORI Hino, KUNIHIDE Ohashi. Numerical simulation of flow around a waterjet propelled ship ［C］∥First International Symposium on Marine Propulsors. Trondhein, Norway： MARINTEK, 2009: 416423. ［6］BONG Rhee, RODERICK Coleman. Computation of viscous flow for the Joint High Speed Sealift Ship with axialflow waterjet ［C］∥First International Symposium on Marine Propulsors. Trondhein, Norway： MARINTEK, 2009: 395407. ［7］KEEGAN Delaney, MARTIN Donnelly, MICHAEL Ebert, et al. Use of RANS for waterjet analysis of a highspeed sealift concept vessel ［C］∥First International Symposium on Marine Propulsors. Trondhein, Norway： MARINTEK, 2009: 408415. ［8］刘承江,王永生,张志宏,等. 流场控制体对喷水推进器性能预报影响的研究［J］. 船舶力学, 2010,14(10): 11171121. LIU Chengjiang, WANG Yongsheng, ZHANG Zhihong，et al. Research on effect of different flow control volume on waterjet performance prediction ［J］. Journal of Ship Mechanics, 2010,14(10):11171121. ［9］BULTEN N, ESCH B. Review of thrust prediction method based on momentum balance for ducted propellers and waterjets ［C］∥ Fluids Engineering Division Summer Meeting and Exhibition. Houston, TX,USA: ASME, 2005:19. ［10］刘承江,王永生.混流式喷水推进器空化性能数值分析［J］.机械工程学报, 2009,45(12): 7683. LIU Chengjiang，WANG Yongsheng. Numerical simulation of a mixedflow waterjet cavitating performance ［J］. Chinese Journal of Mechanical Engineering, 2009,45(12):7683. ［11］LIU Chengjiang,WANG Yongsheng,LI Xiang. Numerical simulation and analysis of cavitation performance of waterjet［C］∥Royal Institution of Naval Architects. International Conference of Waterjet Propulsion V. London, UK: RINA, 2008:5563. ［12］DING Jiangming, WANG Yongsheng. Research on flow loss of inlet duct of marine waterjets［J］. Journal of Shanghai Jiaotong University (Science),2010,15(2):158162. ［13］刘承江，王永生，张志宏，等. 喷水推进器推力的CFD计算方法研究［J］.计算力学学报, 2008，25(6): 927931. LIU Chengjiang, WANG Yongsheng, ZHANG Zhihong, et al. Research on computational methods of waterjet thrust using CFD［J］. Chinese Journal of Computational Mechanics,2008, 25(6): 927931. ［14］TERWISGA V. Report of the Specialist committee on validation of waterjet test procedures to the 24th ITTC［R］. Edinburgh, UK: ITTC, 2005: 471508. ［15］刘承江，王永生. 喷水推进器与螺旋桨工作特性的差异及分析［J］. 华中科技大学学报(自然科学版), 2012, 40(8): 4952. LIU Chengjiang, WANG Yongsheng. Differences and analysis of waterjet and propeller hydrodynamic characteristics［J］.Journal of Huazhong University of Science and Technology(Natural Science Edition), 2012, 40(8): 4952.

编辑推荐 0

Metrics

阅读次数

全文

168

HTML			PDF

最新录用	在线预览	正式出版	最新录用	在线预览	正式出版
0	0	0	0	0	168

来源	本网站	其他网站

次数	28	140
比例	17%	83%

摘要

1171

最新录用	在线预览	正式出版

0	0	1171

来源	本网站	其他网站

次数	435	736
比例	37%	63%

[1]	张澳圆, 胡小锋, 张亚辉. 多场景多目标动态变化下船舶小组立装焊重调度[J]. 上海交通大学学报, 2025, 59(4): 476-488.
[2]	甄春博, 刘世豪, 张爱锋, 邢世柱, 张润泽. 基于缺口应力法的船舶焊接结构疲劳强度分析[J]. 上海交通大学学报, 2025, 59(4): 458-465.
[3]	. 用时间卷积网络预测关键蛋白质的深度学习框架[J]. J Shanghai Jiaotong Univ Sci, 2025, 30(3): 510-520.
[4]	林焰, 张乔宇, 楼建迪. 基于网格归一化Astar算法的船舶管路布置[J]. 上海交通大学学报, 2025, 59(1): 79-88.
[5]	许童杰, 刘振华, 金怀宇, 刘结, 蒋秀丽, 李哲, 刘永生. 室温磁致冷材料Mn₅Ge_2.7Zn_0.3的相变、磁热效应和临界行为[J]. 上海交通大学学报, 2025, 59(1): 131-138.
[6]	张磊, 封少雄, 谭昆, 郭涛, 宋成果, 初秀民, 苗洋. 基于船舶-流场运动耦合的内河航道设计方法[J]. 上海交通大学学报, 2025, 59(1): 89-98.
[7]	谢一凡, 张舒天, 郭思行, 梁镇杰, 张一宁, 张大朋. 舰船模型制作介绍——以903A型综合补给舰为例[J]. 海洋工程装备与技术, 2025, 12(1): 19-27.
[8]	张舒天, 谢一凡, 郭思行, 梁镇杰, 张一宁, 张大朋. 基于福建舰的航空母舰教学实验平台的设计与制作[J]. 海洋工程装备与技术, 2025, 12(1): 9-18.
[9]	赵管益煊, 张舒天, 谢可欣, 李钰婷, 李家强, 黎成伟, 张大朋. 舰船模型制作介绍——以爱达魔都号为例[J]. 海洋工程装备与技术, 2025, 12(1): 1-8.
[10]	胡安峰, 陈奕扬, 肖志荣, 陈正. 考虑竖向荷载作用时液化土中群桩基础水平动力响应[J]. 上海交通大学学报, 2024, 58(7): 1075-1085.
[11]	田野, 余墨多, 黄文焘, 邰能灵, 牛璐. 基于倾斜关联筛选的船舶分区消磁绕组部署及消磁电流优化策略[J]. 上海交通大学学报, 2024, 58(7): 1018-1026.
[12]	刘怡伶1, 张经纬1, 刘学文1, 王岩松1, 周跃亭2. 考虑轮轨接触损失的动态列车垂向Sperling指标评价模型[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(6): 1103-1115.
[13]	林焰1, 2, 卞璇屹1, 董宗然3. 基于改进粒子群算法的船舶管路布局优化[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(5): 737-746.
[14]	蒋祖华1, 周宏明2, 陶宁蓉3, 李柏鹤1. 基于知识的船舶曲面分段建造调度及应用[J]. J Shanghai Jiaotong Univ Sci, 2024, 29(5): 759-765.
[15]	喻西崇1, 刘超1, 刘小燕1, 李志川2, 吴雨霏1, 李欧萍1. 海上风电运维技术和运维策略特点分析[J]. 海洋工程装备与技术, 2024, 11(3): 18-21.