Numerical investigation of a single intermediate-sized bubble in horizontal turbulent channel flow

Sangwon Kim, N. Oshima, Y. Murai, H. Park
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引用次数: 3

Abstract

To address the increasing concern regarding global warming, the International Maritime Organization (IMO) regulated the requirements regarding greenhouse gas emissions from ships. To reduce these emissions, air lubrication systems are being used as this is an energy-saving technology developed to adhere to industry requirements (ABS, 2019). Air lubrication systems can be divided into two main categories based on the size of the bubbles. One category is the microbubble method developed by McCormick and Bhattacharyya (1973), and the other is the air film method, which has been found to be practically viable in the last two decades (e.g., Fukuda et al., 1999, 2000). Meanwhile, intermediate-sized bubbles have recently attracted significant research interest, as bubble deformation plays a key role in the process of drag reduction, as studied by Moriguchi and Kato (2002) and Kitagawa et al. (2005). The intermediate-sized bubbles negatively contribute to the drag reduction performance in the downstream region of the microbubble and air film methods. However, Murai et al. (2006) investigated the drag reduction mechanism for these bubbles (10–50 mm) and discovered that a calm region is generated behind the bubble. This feature is quite different from those of the microbubble and air film methods. This previous research has proven to be a turning point in studies related to intermediate-sized bubbles and is being considered as a new technique for improving drag reduction. An additional advantage is that supplying intermediatesized bubbles is much easier than generating a high flow rate of microbubbles or stabilizing an air film over a wide area. Murai et al. (2007) and Oishi and Murai (2014) rigorously investigated and described influential characteristics such as the velocity gradient and u'v' contours related to the drag reduction of a single intermediate-sized bubble. In numerical studies, Lu et al. (2005), Sugiyama et al. (2005), Kawamura (2005), and Spandan et al. (2017) also confirmed the positive *Department of Mechanical and Space Engineering, Hokkaido university Kita-13, Nishi-8, Kita-ku, Sapporo, Hokkaido 060-8628, Japan E-mail: swkim5834@eis.hokudai.ac.jp **Division of Energy and Environmental Systems, Hokkaido university Kita-13, Nishi-8, Kita-ku, Sapporo, Hokkaido 060-8628, Japan
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水平湍流通道中单个中等大小气泡的数值研究
为了应对日益增长的全球变暖问题,国际海事组织(IMO)对船舶温室气体排放的要求进行了规范。为了减少这些排放,正在使用空气润滑系统,因为这是一种符合行业要求的节能技术(ABS, 2019)。根据气泡的大小,空气润滑系统可分为两大类。一类是McCormick和Bhattacharyya(1973)开发的微泡法,另一类是空气膜法,在过去二十年中被发现实际上是可行的(例如,Fukuda et al., 1999, 2000)。与此同时,中等大小的气泡最近引起了很大的研究兴趣,因为正如Moriguchi和Kato(2002)以及Kitagawa等人(2005)所研究的那样,气泡变形在减阻过程中起着关键作用。在微气泡和气膜方法的下游区域,中等大小的气泡对减阻性能有负贡献。然而,Murai et al.(2006)研究了这些气泡(10-50 mm)的减阻机制,发现气泡后面产生了一个平静区域。这一特点与微泡法和气膜法有很大的不同。这项先前的研究已被证明是中型气泡研究的一个转折点,并被认为是一种改善减阻的新技术。另一个优点是,提供中等大小的气泡比产生高流速的微气泡或在大范围内稳定空气膜要容易得多。Murai等人(2007)和Oishi和Murai(2014)严格研究并描述了与单个中等大小气泡减阻相关的速度梯度和u'v'等高线等影响特性。陆在数值研究中,et al。(2005),Sugiyama et al。(2005),河村建夫(2005),和Spandan et al。(2017)也证实了积极*机械,航天工程,北海道大学Kita-13 Nishi-8, Kita-ku,札幌北海道060 - 8628,日本电子邮件:swkim5834@eis.hokudai.ac.jp * *部门的能源和环境系统中,北海道大学Kita-13 Nishi-8, Kita-ku,札幌北海道060 - 8628,日本
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自引率
12.50%
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2
期刊介绍: Journal of Fluid Science and Technology (JFST) is an international journal published by the Fluids Engineering Division in the Japan Society of Mechanical Engineers (JSME). JSME had been publishing Bulletin of the JSME (1958-1986) and JSME International Journal (1987-2006) by the continuous volume numbers. Considering the recent circumstances of the academic journals in the field of mechanical engineering, JSME reorganized the journal editorial system. Namely, JSME discontinued former International Journals and projected new publications from the divisions belonging to JSME. The Fluids Engineering Division acted quickly among all divisions and launched the premiere issue of JFST in January 2006. JFST aims at contributing to the development of fluid engineering by publishing superior papers of the scientific and technological studies in this field. The editorial committee will make all efforts for promoting strictly fair and speedy review for submitted articles. All JFST papers will be available for free at the website of J-STAGE (http://www.i-product.biz/jsme/eng/), which is hosted by Japan Science and Technology Agency (JST). Thus papers can be accessed worldwide by lead scientists and engineers. In addition, authors can express their results variedly by high-quality color drawings and pictures. JFST invites the submission of original papers on wide variety of fields related to fluid mechanics and fluid engineering. The topics to be treated should be corresponding to the following keywords of the Fluids Engineering Division of the JSME. Basic keywords include: turbulent flow; multiphase flow; non-Newtonian fluids; functional fluids; quantum and molecular dynamics; wave; acoustics; vibration; free surface flows; cavitation; fluid machinery; computational fluid dynamics (CFD); experimental fluid dynamics (EFD); Bio-fluid.
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