On New Method of Anti-Sloshing Using Corrugated Bulkhead

doi:10.19423/j.cnki.31-1561/u.2022.05.073

Ship & Boat ›› 2022, Vol. 33 ›› Issue (05): 73-81.DOI: 10.19423/j.cnki.31-1561/u.2022.05.073

Previous Articles Next Articles

On New Method of Anti-Sloshing Using Corrugated Bulkhead

TANG Zhongshi, ZOU Changfang

School of Ocean Engineering, Jiangsu Ocean University, Lianyungang 222000, China

Received:2022-04-19 Revised:2022-06-06 Online:2022-10-25 Published:2022-10-27

波纹板舱壁制荡方法研究

唐忠时, 邹昶方

江苏海洋大学海洋工程学院连云港 222000

作者简介:唐忠时（1998-）,男,硕士研究生。研究方向：流固耦合动力学。邹昶方（1982-）,男,博士,讲师。研究方向：流固耦合动力学。
基金资助:
江苏省海洋资源开发研究院开放基金项目（JSIMR202009）; 江苏海洋大学科研启动基金项目（KQ19045）

Abstract

Abstract: The study of new methods of sloshing control is one of the key issues in the development of large liquid cargo ships. The sloshing of the vertical corrugated bulkhead in low liquid depth under resonance has been numerically simulated based on commercial code FLUENT to study the effect of the corrugated parameters on the sloshing behavior. The anti-sloshing mechanism of the vertical corrugated bulkhead is explored by analyzing the pressure at key locations and the evolution of the free-surface wave height. The results of the corrugated bulkhead are compared with those of the vertical flat bulkhead. It shows that the anti-sloshing effect of the vertical corrugated plate is better than that of the vertical flat plate.

Key words: sloshing, corrugated bulkhead, free surface, impact pressure

摘要： 制荡新方法的研究是大型液货船开发的一个关键问题。该文基于商业代码FLUENT对竖直波纹板舱壁在低液深共振状态下液舱晃荡进行模拟,研究了波纹板参数对晃荡行为的影响,通过分析关键位置的晃荡压力及自由液面波高演化,探究竖直波纹板的制荡机理,并将其结果与竖直平板舱壁的结果进行对比分析。结果表明：竖直波纹板的制荡效果优于竖直平板。

关键词: 晃荡, 波纹板舱壁, 自由液面, 冲击压力

CLC Number:

U661.1

TANG Zhongshi, ZOU Changfang. On New Method of Anti-Sloshing Using Corrugated Bulkhead[J]. Ship & Boat, 2022, 33(05): 73-81.

唐忠时, 邹昶方. 波纹板舱壁制荡方法研究[J]. 船舶, 2022, 33(05): 73-81.

References

[1] ABRAMSON H N.Dynamic behavior of liquids in moving containers[M]. NASA REPORT, 1966:106.
[2] SHINKAI A, TAMIA S.Sloshing impact pressure induced on cargo oil tank walls of the middle-sized double hull tanker[J]. Transactions of the West Japan Society of Naval Architect, 1995,90:91-102.
[3] 管延敏,叶恒奎,陈庆任,等. 三维带挡板箱体液体晃荡数值模拟[J]. 华中科技大学学报(自然科学版),2010(4):102-104,112.
[4] 卫志军,申利敏,关晖,等. 拓扑优化技术在抑制流体晃荡中的数值模拟研究[J]. 应用数学和力学, 2021 (1):49-57.
[5] KANG H S, ARIF U, KIM K S, et al.Sloshing suppression by floating baffle[J]. Ocean Systems Engineering, 2019 (4):409-422.
[6] 王子豪,姜胜超,徐博,等. 隔板对液舱晃荡影响的数值研究[C]//第十六届全国水动力学学术会议暨第三十二届全国水动力学研讨会论文集 (下册). 无锡,2021.
[7] 于曰旻. 带新型浮式制荡装置的液舱晃荡和制荡效果研究[D]. 上海:上海交通大学,2017.
[8] ZHANG C, SU P, NING D.Hydrodynamic study of an anti-sloshing technique using floating foams[J]. Ocean Engineering, 2019,175: 62-70.
[9] IRANMANESH A, NIKBAKHTI R.Numerical study on suppressing liquid sloshing of a rectangular tank using moving baffles linked to a spring system[J]. Ocean Engineering, 2021,229: 109002.
[10] ZOU C F, WANG D Y, CAI Z H, et al.The effect of liquid viscosity on sloshing characteristics[J]. Journal of Marine Science and Technology,2015(4): 765-775.
[11] ZOU C F, WANG D Y, CAI Z H.Effects of boundary layer and liquid viscosity and compressible air on sloshing characteristics[J]. International Journal of Naval Architecture and Ocean Engineering,2015(4): 670-690.
[12] 蔡忠华. 液货船液舱晃荡问题研究[D]. 上海:上海交通大学,2012.

On New Method of Anti-Sloshing Using Corrugated Bulkhead

波纹板舱壁制荡方法研究

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 1

Recommended Articles

Metrics