Effect of Impingement Surface Velocity on Slot Jet and Slot Jet Reattachment Nozzles’ Flow Field

Volume 7: Fluids Engineering Pub Date : 2019-11-11 DOI:10.1115/imece2019-11404

M. Farzad, J. Yagoobi

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引用次数: 3

Abstract

Slot jet reattachment (SJR) nozzle is developed in an attempt to enhance heat and mass transfer characteristics while effectively controlling the impingement surface force exerted by the jet flow. In the SJR nozzle, the jet is directed outward from the nozzle exit and it then reattaches on an adjacent surface in its vicinity. The turbulent mixing occurs at the boundaries of the free stream induces secondary flow by mass entrainment and causes the flow to reattach the surface in the form of an oval reattachment at close nozzle to surface spacing [1]. All the previous studies had considered a stationary reattachment surface. This paper, for the first time, investigates the impact of reattachment surface movement on the flow structure of SJR nozzle with three different exit angles of +45°, +20°, and +10°. Specifically, this numerical study is carried out by varying the surface-to-jet velocity ratio (u* = up/ue) from 0 to 1.5 and comparing of flow reattachment flow fields to those of a regular slot jet (SJ) nozzle, where up is the speed of reattachment surface (moving plate) and ue is the jet exit velocity. In this study, jet exit temperature is kept constant at the room temperature of 20°C and all comparisons were performed at the same Reynolds number of 7,900. Additionally, the effect of SJR air exit angle on the peak surface pressure is investigated.

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撞击面速度对槽式射流及槽式射流再附着喷嘴流场的影响

为了在有效控制射流冲击面力的同时提高传热传质性能，研制了狭缝射流再附着(SJR)喷嘴。在SJR喷嘴中，射流从喷嘴出口向外定向，然后重新附着在其附近的相邻表面上。湍流混合发生在自由流的边界处，通过质量夹带引起二次流动，并使流动在靠近喷嘴处以椭圆形的形式重新附着在表面，表面间距为[1]。以往的研究都考虑了固定的再附着面。本文首次研究了+45°、+20°和+10°三种不同出口角下，再附着面运动对SJR喷管流动结构的影响。具体而言，将面喷速度比(u* = up/ue)从0变化到1.5，并将流动再附着流场与常规槽式射流(SJ)喷嘴的流场进行比较，其中up为再附着面(动板)速度，ue为射流出口速度。在本研究中，射流出口温度保持恒定，室温为20℃，所有比较均在相同雷诺数7,900下进行。此外，还研究了SJR气流出口角对峰值表面压力的影响。

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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来源期刊

Volume 7: Fluids Engineering

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