加热管组上热声振荡流的努塞尔特数和雷诺数相关性

Q1 Chemical Engineering
Aw Lin Chou , Fatimah Al Zahrah Mohd Saat , Fadhilah Shikh Anuar , Ahmed Hamood
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引用次数: 0

摘要

振荡流的来回运动特征给预测热声波条件下的传热性质带来了复杂性。研究这一点至关重要,因为流动构成了热力学运行循环的支柱。通常情况下,计算传热时采用的稳定近似方法会导致系统设计模糊不清。本文通过在热声框架内对振荡流的流体动力学行为和传热特性进行深入分析来解决这一问题,分析范围包括雷诺数从 300 到 24,000 的实验工作。研究的重点是一个管组热交换器,该热交换器由直列和交错配置的九根管子组成。实验分别在 40 °C 和 80 °C 的恒定管表面温度下进行。计算流体动力学(CFD)模型采用雷诺平均纳维-斯托克斯方程和 k-omega 湍流切应力传输模型,直观显示了振荡流传热行为的显著差异。气流从未离开过系统,它循环往复地穿过管道,其移动距离取决于气流的驱动比。流体的独特性质为实验结果奠定了基础,实验结果表明,无论管组配置和管组温度如何,努塞尔特数和雷诺数之间都存在线性关系。使用 Matlab R2022b 进行了皮尔逊尺回归分析,提出了努塞尔相关系数 Nu = 0.000853RePr⅓,置信度为 95%。值得注意的是,该相关性与称为 Colburn-j 因子的恒定值一致,其值为 0.00083。事实表明,Colburn-j 值较小是受振荡流的对数平均温差特性的影响。这表明加热管和周围流体之间的传热过程是一致的,这对维持系统的热声效应非常重要。在未来的热声设计中,应避免使用或至少谨慎使用稳定传热相关性,因为与已发表作品的对比分析得出结论,稳定流的努塞尔特和雷诺相关性往往会高估传热两到三倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nusselt and Reynolds numbers correlation for oscillatory flow of thermoacoustics over heated tube banks
The back-and-forth motion characteristic of the oscillatory flow brings complexity in predicting the heat transfer nature for thermoacoustic wave conditions. Investigating this is crucial as the flow forms the backbone for the thermodynamic cycles of its operation. Often, the steady approximation in calculating heat transfer leads to ambiguity in designing the system. This concern is addressed in this paper via an in-depth analysis of the fluid dynamic behavior and heat transfer characteristics of oscillatory flow within a thermoacoustic framework, spanning experimental works for Reynolds numbers ranging from 300 to 24,000. The investigation focused on a tube bank heat exchanger composed of nine tubes arranged in inline and staggered configurations. Experiments were conducted at constant tube surface temperatures treated at 40 °C and 80 °C, respectively. The distinguishing difference in heat transfer behaviors for oscillatory flow is visualized by the Computational Fluid Dynamics (CFD) models, employing the Reynolds-Averaged Navier Stokes equation with the k-omega turbulence shear stress transport model. The flow never leaves the system, and it cyclically crosses the tubes back and forth with a travel distance that depends on the drive ratio of the flow. The unique nature of the flow forms the foundation for the experimental findings that show a linear relationship between the Nusselt and Reynolds numbers regardless of the configuration of tube banks and tube bank temperature. The Pearson ruler regression analysis was conducted using Matlab R2022b and a Nusselt correlation, Nu = 0.000853RePr⅓, is proposed with a confidence level of 95 %. Notably, the correlation aligns with the constant value known as the Colburn-j factor, with a value of 0.00083. The small Colburn-j value is shown to be the influence of the log-mean temperature difference characteristic of oscillatory flow. It shows a consistent heat transfer process between the heated tubes and surrounding fluid, which is important to sustain the thermoacoustic effect in the system. For future thermoacoustic design, the use of steady heat transfer correlation should be avoided or at least used with caution as the comparative analysis with published works concluded that the Nusselt and Reynolds correlation for steady flow tends to overpredict the heat transfer by two to threefold.
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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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