粒度对炼铁高炉性能的数值研究

Lulu Jiao, Xinyang Zhang, Shibo Kuang, Aibing Yu
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摘要

在实际操作中,焦炭和矿石粒度对高炉(BF)运行的效率和稳定性非常重要。然而,它们的选择通常由经验决定,目前还没有关于矿石和焦炭尺寸对高炉运行影响的系统研究。本文对不同矿石和焦炭尺寸下高炉内的多相流和热化学行为进行了数值研究。该研究基于最近开发的三维多流体 BF 过程模型。首先通过各种应用对该模型进行了验证。然后用它来研究粒度对 BF 性能的影响。结果表明,随着焦炭和矿石粒度的减小,热化学利用效率得到提高,具体表现为低焦炭率、低顶部煤气温度、高顶部煤气利用系数和高生产率。然而,对于给定的 BF 来说,可能存在一个最小粒度。三个指标,即气体压降、滴落区的液体淹没和负载表面的颗粒流化,可用于确定该最小粒度。在当前条件下,建议的最小焦炭粒度不应小于 20 毫米,建议的矿石粒度不应小于 12.5 毫米。此外,矿石粒度对 BF 整体性能指标(如燃料率和生产率)的影响比焦炭粒度更为显著。就内部状态而言,随着矿石粒度的增加,BF 竖井内的固体温度下降,CZ 位置也相应下降。相反,随着焦炭粒度的增大,BF 竖井内的固体温度显著升高,CZ 位置也相应升高。同样,矿石和焦炭粒度的增加都会增加 CZ 厚度。此外,还研究了大矿石和焦炭颗粒局部充填的影响。结果表明,在预设模拟条件下,局部装入大颗粒矿石可显著降低煤气压降,但会增加燃料率;然而,局部装入大颗粒焦炭对 BF 全局性能指标的影响有限。这些结果为 BF 实践中焦炭和矿石粒度的选择提供了一些有价值的指导。
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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Numerical Investigation of Particle Size on the Performance of Ironmaking Blast Furnace

Coke and ore sizes are important to the efficiency and stability of blast furnace (BF) operation in practice. However, their selection is usually determined by experience and there is no systematic study on the effects of ore and coke sizes on BF operation. This paper presents a numerical study on the multiphase flow and thermochemical behaviors inside the BF with different ore and coke sizes. This is done based on a recently developed 3D multifluid BF process model. The validation of this model is first confirmed by various applications. It is then used to study the effect of particle size on BF performance. The results show that as coke and ore sizes decrease, the thermochemical utilization efficiency is improved, which is reflected in low coke rate, low top gas temperature, high top gas utilization factor, and high productivity. However, there may be a minimum particle size for a given BF. Three indicators, namely gas pressure drop, liquid flooding in the dripping zone, and particle fluidization at the burden surface are used to determine this minimum particle size. Under the present conditions considered, the suggested minimum coke size should not be less than 20 mm and the suggested ore size should not be less than 12.5 mm. In addition, the effect of ore size on BF global performance indicators, e.g., fuel rate and productivity, is more significant than coke size. In terms of inner states, as ore size increases, the solid temperature drops in the BF shaft and the CZ position drops accordingly. On the contrary, as coke size increases, the solid temperature increases significantly in the BF shaft and the CZ position increases accordingly. Consistently, the increase of ore and coke sizes both increases the CZ thickness. Furthermore, the effect of locally charging large ore and coke particles is also studied. The results show that under the preset simulation conditions, locally charging large ore particles significantly reduces the gas pressure drop, but increases the fuel rate; however, locally charging large coke particles has limited influence on BF global performance indicators. The results provide some valuable guidance for coke and ore size selection in BF practice.

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