CaO-FeO-SiO2粉末分数对火炬传热影响的物理模型

IF 0.6 Q3 MULTIDISCIPLINARY SCIENCES

Science and innovation Pub Date : 2022-08-14 DOI:10.15407/scine18.04.064

L. Molchanov, T. Golub, Y. Synehin, S. Semykin

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引用次数: 0

摘要

介绍冶金装置中的主要传热方式之一是装药与燃烧气体炬的相互作用。火炬的热量主要通过辐射传递。特别地，氧气转换器过程在其氧化过程的典型温度和化学条件下伴随着燃烧反应，由于离开该单元的废气的部分后燃烧，在转换器的空腔中（在所谓的反应区中）和转换器颈部上方都形成了火炬。问题陈述。冶金装置中的工艺伴随着大量的烟尘，这影响了从燃烧后的废气火炬到金属浴的热传递效率，金属浴是转炉工艺中的额外热源。意图本研究的目的是研究将固体粉末成分引入火炬周围环境对其传热的影响。材料和方法。研究了CaO-FeO-SiO2系粉末在气流中加入火炬时的物理模型。热流密度的大小是根据模型不同部分的记录温差估计的。后果已经证实，在远低于焊炬温度的温度下供给空气或任何固体材料对通过辐射从焊炬的热传递具有负面影响。然而，由于加热的固体可能参与其他传热方法，总热流密度并没有显著降低。对于CaO-FeO-SiO2系统，二氧化硅粉末作为具有最高热容的组分的份额对火炬的热传递具有最大的负面影响。结论。基于物理模型的研究使我们能够定性地评估燃烧火炬环境中CaO-FeO-SiO2系统各成分的含尘量对其传热的影响，以及在给定条件下火炬不同传热方法对总热流密度的贡献。

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Physical Model of Influence of CaO–FeO–SiO2 Powder Fraction on the Heat Transfer from Torch

Introduction. One of the main ways of heat transfer in metallurgical units is the interaction of the charge with a burning gas torch. The heat is transferred from the torch mainly by radiation. In particular, oxygen converter process under its typical temperature and chemical conditions of oxidation processes is accompanied by combustion reactions with the formation of a torch both in the cavity of the converter (in the so called reaction zone) and above the converter neck as a result of partial post-combustion of exhaust gases leaving the unit.Problem Statement. The processes in metallurgical units are accompanied by significant smoke and dust, which affect the efficiency of heat transfer from the torch of exhaust gases post-combustion to the metal bath that is an additional source of heat in the converter process.Purpose. The purpose of this research is to study the influence of the introduction of solid powder components into the environment around the torch on its heat transfer.Materials and Methods. The research has been carried out on the physical model of a burning torch when CaO-FeO-SiO2 system powders are fed into the torch in air flow. The magnitude of the heat flow density has been estimated on the basis of the registered temperature difference in different parts of the model.Results. It has been established that the feed of air or any solid material at a temperature much lower than the torch temperature has a negative effect on heat transfer from the torch by radiation. However, the total heat flow density is not significantly reduced due to the possible involvement of heated solids in other heat transfer methods. For the CaO-FeO-SiO2 system, the share of silicon dioxide powder as a component with the highest heat capacity has the greatest negative effect on the heat transfer from the torch.Conclusions. The studies based on the physical model have allowed us to qualitatively assess the effect of dustiness of the components of CaO-FeO-SiO2 system of the burning torch environment on its heat transfer and on the contribution of different heat transfer methods from the torch to the total heat flow density in given conditions.

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Science and innovation MULTIDISCIPLINARY SCIENCES-

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1.10

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