Investigation of air and rice husk cold flow structures in the suspension furnace chamber through a simulation study

Q3 Engineering
S. Steven, Linda Windari, Novebriantika Novebriantika, Pasymi Pasymi, E. Restiawaty, Y. Bindar
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引用次数: 3

Abstract

Rice husk combustion in the suspension furnace is not an easy matter. Until now, there are still many obstacles faced in its process as characterized by low combustion conversion. The main cause is the poor air-particle contact as well as the probability of particle elutriation out of the furnace chamber before combustion completely occurs. Thus, in-depth and detailed understanding of air and rice husk cold flow structures in the furnace chamber, as proposed in this study, becomes necessary. The simulation study was conducted using Reynold stress model (RSM) for fluid flow quantification whereas discrete phase model was utilized for particle flow quantification. The simulation results reveal that cylindrical chamber gives a more significant particle residence time rather than rectangular chamber for every similar excess air amount. Besides, providing burner with a tangential air inlet of 90o results in high turbulence, intense swirl phenomenon, and long particle residence time. Moreover, the furnace chamber equipped with a smaller burner diameter and longer burner length together will augment the air-particle contact in the furnace chamber. Despite providing the best condition for the furnace, the design must not forget to consider the economical aspect.
通过对悬浮炉室内空气和稻壳冷流结构的模拟研究
稻壳在悬浮炉中的燃烧不是一件容易的事。到目前为止,在其发展过程中仍面临着许多障碍,其特点是燃烧转化率低。主要原因是空气颗粒接触不良以及颗粒在燃烧完全发生之前冲出炉膛的可能性。因此,深入细致地了解本研究中提出的炉膛内空气和稻壳冷流结构变得十分必要。模拟研究采用雷诺应力模型(RSM)进行流体流动量化,采用离散相模型进行颗粒流动量化。模拟结果表明,在相同的过量空气量下,圆柱形腔室比矩形腔室的颗粒停留时间更显著。另外,燃烧器切向进气口为90o,湍流度高,涡流现象强烈,颗粒停留时间长。此外,配备较小的燃烧器直径和较长的燃烧器长度将增加炉室内空气颗粒的接触。在为炉提供最佳条件的同时,设计也不能忘记考虑经济方面的因素。
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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