圆形90度弯曲喷嘴内部流动特征分解模态对油射流界面行为的影响

IF 0.7 Q4 MECHANICS

Journal of Fluid Science and Technology Pub Date : 2021-01-01 DOI:10.1299/jfst.2021jfst0023

Mikimasa Kawaguchi, Ryoutaro Nakayama, Li-Jia Ma, K. Nishida, H. Yokohata, Masanobu Koutoku, J. Nishikawa, A. Nakashima, Y. Ogata

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引用次数: 1

摘要

提出了减少内燃机二氧化碳排放的方法。例如，发动机可以设计成高压缩比和/或小型涡轮增压器。然而，这些方法产生高燃烧温度，增加热负荷。提出了活塞冷却廊道作为一种冷却发动机活塞的系统。活塞冷却廊是一个油流路径，设置在活塞内部。从活塞下方的喷嘴喷射的油通过入口大厅流入活塞冷却廊。因此，可能需要控制油射流的形状，使其稳定和直。然而，由于开尔文-亥姆霍兹不稳定性和/或瑞利-泰勒不稳定性，周围空气和油射流的界面可能具有不稳定的波浪。此外，我们对流动进行了研究，在之前的研究中发现，喷嘴内部流动流速波动的传播导致了油射流的波纹。为了进一步阐明喷油嘴出口后射流界面不稳定性与喷油嘴内流动之间的关系，本文报道了两种粒子图像测速方法(PIV)，即二维两速度分量PIV和二维三速度分量PIV，并对两分量和三分量快照进行适当的正交分解，采用互相关方法对湍流传播进行分析。在油射流与空气界面具有强波浪形的条件下，找到了一个能量较大的特征基向量，将波动向下传播。

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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Effects of characteristic decomposed modes of the internal flow of a circular 90-degree bent nozzle on the behavior of the oil jet interface

Methods of decreasing the CO2 emissions of the internal combustion engine have been suggested. For example, an engine can be designed with a high compression ratio and/or a downsizing turbocharger. However, these methods generate high combustion temperatures that increase the heat load. The piston cooling gallery has been proposed as a system for cooling the engine piston. The piston cooling gallery is an oil flow path that is set internal to the piston. An oil jet injected from a nozzle placed under the piston flows into the piston cooling gallery through an entrance hall. It may thus be desirable to control the shape of the oil jet such that it is stable and straight. However, the interface of the ambient air and oil jet may have unstable waviness because of Kelvin– Helmholtz instability and/or Rayleigh–Taylor instability. In addition, we investigated the flow and found that the propagation of the flow speed fluctuation of the nozzle internal flow results in the waviness of the oil jet in a previous study. To further clarify the relationship between oil jet interface instability immediately after nozzle exit and flow in nozzle, this paper reports on two types of particle image velocimetry (PIV), namely twodimensional two-velocity-component PIV and two-dimensional three-velocity-component PIV, in addition to two-component and three-component snapshot proper orthogonal decompositions, and analyzes turbulence propagation adopting a cross-correlation method. We find a characteristic basis vector with large energy that propagates the fluctuation downstream under the condition that the interface between the oil jet and air has strong waviness.

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来源期刊

Journal of Fluid Science and Technology MECHANICS-

CiteScore

1.00

自引率

12.50%

发文量

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.