极地螺旋桨空化引起的系柱推力下降问题研究

doi:10.19423/j.cnki.31-1561/u.2023.06.120

船舶 ›› 2023, Vol. 34 ›› Issue (06): 120-128.DOI: 10.19423/j.cnki.31-1561/u.2023.06.120

• • 上一篇

极地螺旋桨空化引起的系柱推力下降问题研究

文潇^1,2

1.中国船舶及海洋工程设计研究院上海 200011;
2.喷水推进技术国防科技重点实验室上海 200011

收稿日期:2023-10-08 修回日期:2023-10-26 出版日期:2023-12-25 发布日期:2023-12-28
作者简介:文潇（1990-）,男,博士,工程师。研究方向：船舶推进器设计研究。
基金资助:
国防科技重点实验室稳定支持科研计划（90015-6）

On Thrust Reduction Caused by Cavitation of Ice-Class Propeller Under Bollard Condition

WEN Xiao^1,2

1. Marine Design & Research Institute of China, Shanghai 200011, China;
2. Science and Technology on Water Jet Propulsion Laboratory, Shanghai 200011, China

Received:2023-10-08 Revised:2023-10-26 Online:2023-12-25 Published:2023-12-28

摘要/Abstract

摘要： 极地船舶破冰航行时,常处于系柱工况或低进速工况,此时易发生螺旋桨空化,引起推力下降,严重影响破冰能力。为有效指导极地螺旋桨水动力性能设计,该文从模型试验和数值模拟这2种方法入手,针对极地螺旋桨系柱工况下由空化引起的推力下降问题进行研究。首先,在空泡水筒设施中分别开展某自主设计极地螺旋桨的敞水性能试验和系柱工况推力下降试验。结果表明：受空泡水筒工作段空间限制与螺旋桨诱导速度影响,模型试验难以满足零进速条件,无法真实反映系柱工况的螺旋桨推力下降特征。为此,文中进一步开展基于Star-CCM+软件的数值模拟研究。通过对比敞水预报结果与模型试验结果,验证了数值计算精度,并开展系柱工况和低进速工况的推力下降数值模拟。结果表明：模型试验测得的系柱工况推力下降趋势与低进速工况数值结果相符,而在系柱工况模拟中,螺旋桨推力下降点与低进速工况相比出现更早,转速空化数σ_n=2.00时,推力即开始迅速下降;转速空化数σ_n=1.00时,该极地螺旋桨推力下降至敞水工况的43.9%,造成水动力性能显著恶化。分析系柱推力下降机理机制,发现其发生的主要原因是叶面平均压力在叶背空泡影响下大幅减小。

关键词: 极地螺旋桨, 系柱工况, 空化, 推力下降, 模型试验, 数值模拟

Abstract: The polar ships during ice-breaking operation are often in bollard conditions or low advance speed conditions, easily causing propeller cavitation with a decrease of thrust and a serious impact on the ice-breaking capability. The thrust reduction caused by the cavitation of the ice-class propeller under the bollard condition is studied using both the model test method and the numerical simulation method, in order to guide the hydrodynamic performance design of the ice-class propeller. Firstly, the open-water test and the thrust reduction test under the bollard condition are performed for a self-designed ice-class propeller in the cavitation tunnel. The results show that the model test cannot meet the zero-advance-speed condition, and thus cannot truly reflect the thrust reduction of the propeller under bollard condition due to the space limitation of the working section of the cavitation tunnel and the influence of the induced velocity of the propeller. Therefore, the numerical simulations based on the commercial CFD software Star-CCM+ are further carried out. The numerical accuracy is verified by comparing the results of the open-water simulation with those of the model test, and then the numerical simulations of the thrust reduction are performed under the bollard condition and the low advance speed condition. It shows that the thrust reduction measured by the model test under the bollard condition is consistent with the numerical results under the low-advance-speed condition. As for the simulation under the bollard condition, it is observed that the start point of the thrust reduction of the propeller appears earlier than that under the low-advance-speed condition. The thrust of the ice-class propeller begins to decline rapidly when the cavitation number equals to two (σ_n=2), and decreases to 43.9% of the thrust under open-water condition with a cavitation number of σ_n=1, resulting in a significant deterioration of hydrodynamic performance. By analyzing the mechanism of the thrust reduction under the bollard condition, it is found that the thrust reduction is mainly caused by the significant decrease in average pressure on the blade surface under the influence of the cavitation occurring on the back of the blade.

Key words: ice-class propeller, bollard condition, cavitation, thrust reduction, model test, numerical simulation

中图分类号:

U664.33

文潇. 极地螺旋桨空化引起的系柱推力下降问题研究[J]. 船舶, 2023, 34(06): 120-128.

WEN Xiao. On Thrust Reduction Caused by Cavitation of Ice-Class Propeller Under Bollard Condition[J]. Ship & Boat, 2023, 34(06): 120-128.

参考文献

[1] 丁举, 王建强, 刘正浩, 等. 极地破冰船螺旋桨设计探讨[J]. 船舶, 2023(1): 175-184.
[2] 孙文林, 王超, 康瑞, 等. 冰区航行船舶推进系统设计的若干考虑[J]. 船舶工程, 2015(9): 31-36.
[3] PUSTOSHNY А V, DARCHIEV G K, FROLOVA I G.The problem of propeller design for high ice class transportation ships[C]//Proceeding of 5th international symposium on marine propulsors(SMP’17), Espoo, Finland, 2017.
[4] 吴利红, 刘铭, 张文灿, 等. 不同工况下螺旋桨空泡的水动力性能研究[J]. 哈尔滨工程大学学报, 2022(43): 593-599.
[5] 朱成华, 齐江辉, 郭健. 不同螺旋桨配置对重型破冰船推力的影响分析[J]. 哈尔滨工程大学学报, 2022(43): 69-75.
[6] MINTCHEV D, BOSE N, VEITCH B, et al.Propeller ice milling tests in the emerson cavitation tunnel[C]//In International Conternational on Propeller Caritaion, Newcastle, 2000.
[7] ATLAR M, PRASETYAWAN I, ARYAWAN W D, et al.Ice milling tests with a model odded propulsor[R]. 2002.
[8] 吴家鸣, 张恩伟, 钟乐. 导管螺旋桨在空泡影响下的推力特性[J]. 华南理工大学学报(自然科学版), 2018(46): 41-49.
[9] 王建强, 万初瑞, 孔为平, 等. 高负荷大侧斜螺旋桨推力下降性能试验和数值研究[C]//第三十一届全国水动力学研讨会论文集(上册), 厦门, 2020: 588-595.
[10] 刘谦, 李子如, 何朋朋, 等. 定常空化下船用螺旋桨推力损失机理数值分析[J]. 武汉理工大学学报(交通科学与工程版), 2022(46): 1013-1019.
[11] 杨琼方, 王永生, 张志宏. 非均匀进流对螺旋桨空化水动力性能的影响[J]. 水动力学研究与进展, 2011(26): 538-550.
[12] 赵旻晟, 万德成. E7779A螺旋桨斜流工况下的空泡数值模拟[C]//第三十届全国水动力学研讨会暨第十五届全国水动力学学术会议文集(下册), 合肥, 2019: 421-429.
[13] 李善成, 熊鹰, 王展智. 偏转工况下吊舱推进器的水动力和空泡性能[J]. 中国舰船研究, 2019(14): 33-42.
[14] 齐江辉, 郭健, 郑亚雄, 等. 七叶侧斜螺旋桨设计参数对空泡性能的影响研究[J]. 推进技术, 2019(40): 2366-2372.
[15] 吴思源, 张怀新, 姚慧岚. 基于CFD软件的均流中空化螺旋桨的水动力性能预报[J]. 船舶与海洋工程, 2022(38): 17-24.

编辑推荐

Metrics

联系电话：（021）63161688-105006
传真：（021）63151255
E-mail：chuanbo@maric.com.cn

极地螺旋桨空化引起的系柱推力下降问题研究

On Thrust Reduction Caused by Cavitation of Ice-Class Propeller Under Bollard Condition

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

[1]	董小倩, 杨晨俊. 空泡对喷水推进器流道脉动压力影响的试验研究[J]. 船舶, 2023, 34(06): 35-42.
[2]	李晗, 黄桥高, 潘光, 李福正, 何幸. 导管对泵喷推进器艇后推进特性的影响[J]. 船舶, 2023, 34(06): 73-84.
[3]	冯树才, 曲东旭, 陈彦臻, 李智. 基于CFD的直接进气系统在船舶上的研究与应用[J]. 船舶, 2023, 34(04): 97-104.
[4]	刘昕, 傅昱晓, 蒋武杰, 倪宝玉. 极地某构型船首与浮冰碰撞的数值模拟研究[J]. 船舶, 2023, 34(03): 115-122.
[5]	刘小健, 刘义, 魏跃峰. 极地破冰船操纵设计需求分析及研究方法综述[J]. 船舶, 2023, 34(03): 123-134.
[6]	胡扬帆, 丁仕风, 刘志兵, 周利, 吴刚, 曹晶. 极地船液舱温度场分析与冻结过程模拟[J]. 船舶, 2023, 34(01): 110-118.
[7]	丁举, 王建强, 刘正浩, 周旻, 孔为平. 极地破冰船螺旋桨设计探讨[J]. 船舶, 2023, 34(01): 175-184.
[8]	胡方珍. 船舶进出三峡升船机时下沉量模型试验研究[J]. 船舶, 2022, 33(06): 30-36.
[9]	周睿, 岳桢, 陈顺华, 孙鹏楠. 船用风帆流固耦合研究进展[J]. 船舶, 2022, 33(05): 38-47.
[10]	李兆辉, 胡帆, 吴琼, 冯毅, 孙群. 9 400 TEU集装箱船实尺度自航性能数值模拟[J]. 船舶, 2022, 33(05): 59-72.
[11]	胡开业, 赵宾, 周辉, 毛丽君. 迎浪中ONR内倾船参数横摇抑制措施研究[J]. 船舶, 2022, 33(04): 116-123.
[12]	张恒, 王仁智, 蔡佑林, 于存银. 喷射流浸没深度对喷水推进尾迹场的影响分析[J]. 船舶, 2022, 33(03): 20-27.
[13]	孟庆元, 王长军, 罗立臣. 新型气体驱动搅拌器的数值模拟和实验研究[J]. 船舶, 2022, 33(03): 126-131.
[14]	纪世君, 倪其军, 蒋一. 断阶对超高速气动增升船水气动力特性影响的数值研究[J]. 船舶, 2022, 33(01): 39-47.
[15]	孟庆元, 韩鹏, 刘江歌. 海洋修井机泥浆搅拌器设计优化[J]. 船舶, 2022, 33(01): 117-121.