Enhancing Heat Transfer Performance in Simulated Fischer–Tropsch Fluidized Bed Reactor through Tubes Ends Modifications

IF 2.8 Q2 ENGINEERING, CHEMICAL

ChemEngineering Pub Date : 2023-09-14 DOI:10.3390/chemengineering7050085

Laith S. Sabri, Abbas J. Sultan, Jamal M. Ali, Hasan Shakir Majdi, Muthanna H. Al-Dahhan

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Abstract

Fluidized bed reactors are essential in a wide range of industrial applications, encompassing processes such as Fischer–Tropsch synthesis and catalytic cracking. The optimization of performance and reduction in energy consumption in these reactors necessitate the use of efficient heat transfer mechanisms. The present work examines the considerable impact of tube end geometries, superficial gas velocity, and radial position on heat transfer coefficients within fluidized bed reactors. It was found that the tapered tube end configurations have been empirically proven to improve energy efficiency in fluidized bed reactors significantly. For example, at a superficial gas velocity of 0.4 m/s, the tapered end form’s local heat transfer coefficient (LHTC) demonstrated a significant 20% enhancement compared to the flat end shape. The results and findings of this work make a valuable contribution to the advancement of complex models, enhance the efficiency of fluidized bed reactor processes, and encourage further investigation into novel tube geometries.

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通过管端改造提高模拟费托流化床反应器的传热性能

流化床反应器在广泛的工业应用中是必不可少的，包括费托合成和催化裂化等过程。这些反应器的性能优化和能耗降低需要使用高效的传热机制。本文研究了管端几何形状、表面气速和径向位置对流化床反应器内传热系数的影响。实验证明，锥形管端部结构能显著提高流化床反应器的能量效率。例如，在表面气体速度为0.4 m/s时，锥形端部形式的局部传热系数(LHTC)比扁平端部形式显著提高了20%。本工作的结果和发现对复杂模型的发展，提高流化床反应器过程的效率，并鼓励对新型管几何形状的进一步研究做出了宝贵的贡献。

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