低雷诺数和低马赫数下两平行板间微通道流动的可压缩性效应:数值分析

Q1 Chemical Engineering International Journal of Thermofluids Pub Date : 2024-10-20 DOI:10.1016/j.ijft.2024.100921
Mohammed E. Elgack , Khaled Al-Souqi , Mohammad O. Hamdan , Mohamed Abdelgawad
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引用次数: 0

摘要

在某些情况下,即使雷诺数(Re)在 2300 左右(低于 2300)和低马赫数(低于 0.3),微通道中的流动也会表现出可压缩性效应。对于气体来说尤其如此,特别是当微小通道内的流动经历了显著的压力变化或加速度时。本研究探讨了双平行板微通道在低雷诺数和低马赫数条件下遇到的可压缩性效应,这是由于微通道尺度较小而产生的高压降所致。这种不常见流动的特点是通道直径与长度的长宽比特别小(∼10-3),导致摩擦系数偏离平行板间层流的典型值(f = 96/Re)。在假设连续行为的情况下,研究了低 Re 亚音速流动对流场的稳定和瞬态影响。理想气体方程用于模拟气体密度,而等温 Tait-Murnaghan 方程则用于模拟液体密度。对于气体,主要在入口压力比超过 0.1 时观察到可压缩性效应。结果表明,即使在入口压力比升高的情况下,这些影响对于液体也不那么明显。此外,流经通道的流动延迟会产生一阶瞬态响应。对于液体流动,这种效应取决于通道阻力、通道内的总流体体积和液体的体积特性,而不是入口压力比。
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Compressibility effects in microchannel flows between two-parallel plates at low reynolds and mach numbers: Numerical analysis
Under certain circumstances, flow in microchannels can exhibit compressibility effects even at Reynolds numbers (Re) around (below 2,300) and low Mach numbers (below 0.3). This is particularly true for gases, especially when the flow undergoes significant pressure changes or acceleration within the microchannel. This study investigates the compressibility effects encountered in two-parallel plates microchannels at these low Reynolds and Mach numbers, due to the high-pressure drop associated with the small scale of the microchannels. This uncommon flow is characterized by an exceptionally small channel diameter-to-length aspect ratio (∼10–3), resulting in a friction coefficient that deviates from the typical value for laminar flow between parallel plates (f = 96/Re). Both steady and transient effects on the flow field are examined under low Re subsonic flow, assuming continuum behavior. The ideal gas equation is used to model gas density, while the isothermal Tait-Murnaghan equation models liquid density. For gases, compressibility effects are observed primarily when the inlet pressure ratio exceeds 0.1. The results show that these effects are less pronounced for liquids, even at elevated inlet pressure ratios. Additionally, a flow delay across the channel exhibits a first-order transient response. For liquid flow, this effect depends on the channel resistance, the total fluid volume within the channel, and the liquid's bulk properties, rather than the inlet pressure ratio.
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来源期刊
International Journal of Thermofluids
International Journal of Thermofluids Engineering-Mechanical Engineering
CiteScore
10.10
自引率
0.00%
发文量
111
审稿时长
66 days
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