Jet injection and spout formation in a fluidized bed

IF 3.6 2区 工程技术 Q1 MECHANICS
Hamidreza Khakpour, Navid Mostoufi, Rahmat Sotudeh-Gharebagh, Reza Zarghami
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Abstract

A single jet was studied in a rectangular fluidized bed by analyzing the pressure fluctuations data to characterize the jet hydrodynamics. The bed contained with glass beads of different mean sizes (450, 650, and 920 µm) as well as pharmaceutical pellets (920 µm). The analysis of the pressure fluctuation data was performed using the power spectral density function (PSDF) and discrete wavelet transforms technique. This study investigated how the flow regime changed from a jet in a fluidized bed to a spouted regime as the gas injection velocity was increased. Increasing the mean particle size led to an increase in the minimum spouting velocity. The minimum spouting velocity for 450, 650, and 920 μm glass bead particles and for 920 μm pharmaceutical pellets were determined to be 32.47 m s-1, 38.66 m s-1, 44.78 m s-1, and 44.47 m s-1, respectively. The study also examined how the dominant frequency of the various particles and the energy percentage of scales changed with increasing injection velocities. The ratio of energy percentages of meso-scale changes as the injection velocity increases and these changes were used to estimate the minimum spouting velocity. Wavelet sub-signals analysis revealed that the Daubechies 2 (DB2) wavelet was the most effective at capturing the characteristics of the jet. Based on the Shannon entropy of the approximate coefficients, the wavelet analysis showed that 11 levels of decomposition were required. By combining the wavelet analysis and PSDF, a more detailed analysis of the meso-scale was achieved. This study provided valuable insights into the behavior of jets and spouts in fluidized beds, which can greatly contribute to the optimization of a jet in fluidized beds and spout-fluidized beds by enhancing our understanding of jet behavior in such environments.

Abstract Image

流化床中的喷射和喷口形成
通过分析压力波动数据,对矩形流化床中的单一射流进行了研究,以确定射流流体力学的特征。床中装有不同平均尺寸(450、650 和 920 微米)的玻璃珠以及药物颗粒(920 微米)。使用功率谱密度函数 (PSDF) 和离散小波变换技术对压力波动数据进行了分析。这项研究探讨了随着气体注入速度的增加,流化床中的流动状态如何从喷射状态转变为喷出状态。平均粒径的增加导致最小喷出速度的增加。经测定,450、650 和 920 μm 玻璃珠颗粒以及 920 μm 药丸的最小喷出速度分别为 32.47 m s-1、38.66 m s-1、44.78 m s-1 和 44.47 m s-1。研究还考察了各种颗粒的主频和鳞片的能量百分比如何随注射速度的增加而变化。随着注入速度的增加,中尺度的能量百分比比也发生了变化,这些变化被用来估算最小喷出速度。小波子信号分析表明,Daubechies 2(DB2)小波能最有效地捕捉射流特征。根据近似系数的香农熵,小波分析表明需要进行 11 级分解。通过结合小波分析和 PSDF,可以对中尺度进行更详细的分析。这项研究为流化床中的射流和喷嘴行为提供了宝贵的见解,通过加强我们对流化床和喷嘴流化床中射流行为的理解,可极大地促进流化床和喷嘴流化床中射流的优化。
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来源期刊
CiteScore
7.30
自引率
10.50%
发文量
244
审稿时长
4 months
期刊介绍: The International Journal of Multiphase Flow publishes analytical, numerical and experimental articles of lasting interest. The scope of the journal includes all aspects of mass, momentum and energy exchange phenomena among different phases such as occur in disperse flows, gas–liquid and liquid–liquid flows, flows in porous media, boiling, granular flows and others. The journal publishes full papers, brief communications and conference announcements.
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