Computational Modeling of Walking Beam Type Reheat Furnace for the Prediction of Slab Heating and Scale Formation

IF 2.8 4区工程技术 Q2 ENGINEERING, MECHANICAL Journal of Heat Transfer-transactions of The Asme Pub Date : 2023-11-06 DOI:10.1115/1.4063643

Saurabh Singh, Vineet Kumar, Prakash Ghose

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引用次数: 1

Abstract

Abstract Computational modeling using the high-viscosity laminar flow approach was applied to study the effect of slab crossing time on slab heating and scale growth. Simulation of an existing industrial walking beam reheating furnace with four zones, outer refractory body, skid, slab, and fluid zone is considered. The fuel used was a mixture of coke oven and blast furnace gas. Preheated air is supplied co-axially with the fuel mixture. The combustion simulation is performed using the constrained equilibrium mixture fraction model. From the results, it has been observed that with an increase in slab residence time, the slab temperature and scale growth increase across the slab. For the system considered, with a fuel mass flowrate of 70,000 kg/h, 150–180 min of slab crossing time is appropriate to obtain desired slab temperature at the discharge end. The overall equivalence ratio is taken as Φ = 1 (fuel/air ratio is the same as stoichiometric ratio). The maximum slab scale thickness is evaluated as 2.4 mm at the discharged end for 180 min of slab crossing time.

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步进梁式加热炉板坯加热及结垢预测的计算建模

摘要采用高黏度层流方法建立计算模型，研究了板坯穿越时间对板坯加热和结垢生长的影响。对现有工业步进梁式加热炉进行了四区模拟，即外耐火体、滑块、板坯和流体区。使用的燃料是焦炉煤气和高炉煤气的混合物。预热空气与混合燃料同轴供给。燃烧模拟采用约束平衡混合分数模型。结果表明，随着板坯停留时间的延长，板坯温度和板坯上的水垢生长均增大。对于所考虑的系统，在燃料质量流量为70000 kg/h的情况下，要在排出端获得理想的板坯温度，需要150-180 min的板坯穿越时间。总当量比取Φ = 1(燃料/空气比与化学计量比相同)。在180分钟的跨板时间内，卸料端最大板垢厚度为2.4 mm。

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来源期刊

Journal of Heat Transfer-transactions of The Asme 工程技术-工程：机械

自引率

0.00%

发文量

182

审稿时长

4.7 months

期刊介绍： Topical areas including, but not limited to: Biological heat and mass transfer; Combustion and reactive flows; Conduction; Electronic and photonic cooling; Evaporation, boiling, and condensation; Experimental techniques; Forced convection; Heat exchanger fundamentals; Heat transfer enhancement; Combined heat and mass transfer; Heat transfer in manufacturing; Jets, wakes, and impingement cooling; Melting and solidification; Microscale and nanoscale heat and mass transfer; Natural and mixed convection; Porous media; Radiative heat transfer; Thermal systems; Two-phase flow and heat transfer. Such topical areas may be seen in: Aerospace; The environment; Gas turbines; Biotechnology; Electronic and photonic processes and equipment; Energy systems, Fire and combustion, heat pipes, manufacturing and materials processing, low temperature and arctic region heat transfer; Refrigeration and air conditioning; Homeland security systems; Multi-phase processes; Microscale and nanoscale devices and processes.