摩擦减阻:通道流动中微泡减阻的回顾与数值研究

IF 0.6 4区工程技术 Q4 ENGINEERING, MARINE

International Journal of Maritime Engineering Pub Date : 2021-12-13 DOI:10.5750/ijme.v160ia2.1052

S. Sindagi, R. Vijayakumar, B. K. Saxena

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引用次数: 3

摘要

降低船舶阻力是降低排放、降低运营成本和提高能效指数的最有效方法之一。据报道，对于慢速移动的船舶，摩擦阻力占总阻力的80%之多，因此对降低摩擦阻力的需求很大。使用空气作为润滑剂，即微气泡减阻，来减少摩擦阻力是一个活跃的研究课题。作者的主要关注点是介绍目前世界范围内进行的研究情况，以及矩形通道中空气喷射的数值模拟。该领域的最新发展表明，在平板和船舶的情况下，摩擦阻力可能分别减少80%和30%。综述表明，MBDR取决于气体或空气的扩散，这取决于气泡的大小分布、聚结和液体的表面张力，而这又取决于水的盐度、空隙率、注入点的位置、注入气泡的水的深度。作者认为，微气泡影响螺旋桨的性能，而螺旋桨的性能又决定了注入微气泡所需功率的净功率节省。此外，在Star CCM+中，在不同流速、不同空隙率和注射点不同横截面的通道上，对微气泡减阻进行了三维数值研究。这项研究是同类研究中的第一项，研究了摩擦系数在纵向和翼展方向上的变化，以及这些点处空隙率的实际局部变化。根据研究得出的结论是，由于这是一种通道流，并且由于流动被限制在有限区域，空气喷射的影响在翼展方向上被限制在较小的区域，因为气泡没有在翼展上逸出。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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FRICTIONAL DRAG REDUCTION: REVIEW AND NUMERICAL INVESTIGATION OF MICROBUBBLE DRAG REDUCTION IN A CHANNEL FLOW

The reduction of ship’s resistance is one of the most effective way to reduce emissions, operating costs and to improve EEDI. It is reported that, for slow moving vessels, the frictional drag accounts for as much as 80% of the total drag, thus there is a strong demand for the reduction in the frictional drag. The use of air as a lubricant, known as Micro Bubble Drag Reduction, to reduce that frictional drag is an active research topic. The main focus of authors is to present the current scenario of research carried out worldwide along with numerical simulation of air injection in a rectangular channel. Latest developments in this field suggests that, there is a potential reduction of 80% & 30% reduction in frictional drag in case of flat plates and ships respectively. Review suggests that, MBDR depends on Gas or Air Diffusion which depends on, Bubble size distributions and coalescence and surface tension of liquid, which in turn depends on salinity of water, void fraction, location of injection points, depth of water in which bubbles are injected. Authors are of opinion that, Microbubbles affect the performance of Propeller, which in turn decides net savings in power considering power required to inject Microbubbles. Moreover, 3D numerical investigations into frictional drag reduction by microbubbles were carried out in Star CCM+ on a channel for different flow velocities, different void fraction and for different cross sections of flow at the injection point. This study is the first of its kind in which, variation of coefficient of friction both in longitudinal as well as spanwise direction were studied along with actual localised variation of void fraction at these points. From the study, it is concluded that, since it is a channel flow and as the flow is restricted in confined region, effect of air injection is limited to smaller area in spanwise direction as bubbles were not escaping in spanwise direction.

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来源期刊

International Journal of Maritime Engineering ENGINEERING, MARINE-

CiteScore

1.20

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The International Journal of Maritime Engineering (IJME) provides a forum for the reporting and discussion on technical and scientific issues associated with the design and construction of commercial marine vessels . Contributions in the form of papers and notes, together with discussion on published papers are welcomed.