Numerical Simulation of Influence of Intermediate Radiator on Heat Transfer Process in Heating Furnace

doi:10.12068/j.issn.1005-3026.2021.07.006

Journal of Northeastern University(Natural Science) ›› 2021, Vol. 42 ›› Issue (7): 947-952.DOI: 10.12068/j.issn.1005-3026.2021.07.006

• Materials & Metallurgy • Previous Articles Next Articles

Numerical Simulation of Influence of Intermediate Radiator on Heat Transfer Process in Heating Furnace

JIANG Tian-chi， ZHANG Wei-jun， LIU Shi， WANG Xin

School of Metallurgy， Northeastern University， Shenyang 110819， China.

Revised:2020-11-14 Accepted:2020-11-14 Published:2021-07-16
Contact: ZHANG Wei-jun
About author:-
Supported by:
-

Abstract

Abstract: The energy-saving mechanism of blackbody directional radiation technology was investigated. Based on a chamber heating furnace with an intermediate radiator in a steel plant， a physical model with intermediate radiators was established. A transient 3-D mathematical combustion model coupled with heat transfer and fluid flow in the furnace was developed based on the CFD commercial software Fluent to simulate the combustion and temperature distribution in the furnace. The model was verified according to experimental results. The research results show that the installation of the intermediate radiators changes the flow pattern in the combustion chamber of the furnace and the view factor of the furnace wall to the slab for solid radiation， and enhances the radiant heat transfer intensity of the slab surface for both gas radiation and solid radiation. The combustion temperature is reduced by about 20K， the slab heating speed is increased by 16.7%， and the highest temperature of the slab surface is increased by 40K. The improvement of heating efficiency brings a better energy-saving effect.

Key words: heating furnace; directional radiation; numerical simulation; multi-physics field; energy-saving

CLC Number:

TK175

JIANG Tian-chi， ZHANG Wei-jun， LIU Shi， WANG Xin. Numerical Simulation of Influence of Intermediate Radiator on Heat Transfer Process in Heating Furnace[J]. Journal of Northeastern University(Natural Science), 2021, 42(7): 947-952.

References

[1]蔡九菊，叶竹，孙文强.1995—2010年中国钢铁工业能源消耗影响因素分析［J］.东北大学学报(自然科学版)，2013(10):1438-1441.(Cai Jiu-ju，Ye Zhu，Sun Wen-qiang.Analysis of influencing factors of energy consumption in China’s iron and steel industry from 1995 to 2010［J］.Journal of Northeastern University(Natural Science)，2013，34(10):1438-1441.)
[2]Yi Z，Su Z，Li G，et al.Development of a double model slab tracking control system for the continuous reheating furnace［J］. International Journal of Heat and Mass Transfer，2017，113(10):861-874.
[3]张卫军，王芳，齐凤升，et al.推钢式板坯加热炉流场，温度场和浓度场的模拟研究［J］.东北大学学报(自然科学版)，2011，32(2):266-269.(Zhang Wei-jun，Wang Fang，Qi Feng-sheng，et al.Simulation study on flow field，temperature field and concentration field of push-steel slab heating furnace［J］.Journal of Northeastern University(Natural Science)，2011，32(2):266-269.)
[4]李治岷，魏玉文.工业加热炉窑节能的新途径——黑体强化辐射传热节能的机理［J］.热处理技术与装备，2008，29(2); 36-40.(Li Zhi-min，Wei Yu-wen.A new energy-saving approach for industrial heating furnaces-the mechanism of black body enhanced radiation heat transfer and energy-saving ［J］.Heat Treatment Technology and Equipment，2008，29(2):36-40.)
[5]Meier T，Gandt K，Hay T，et al.Process Modeling and Simulation of the Radiation in the Electric Arc Furnace［J］. Steel Research International，2018，89(1)(2018.10.12)［2020-12-26］.https://doi.org/10.1002/srin.201700487
[6]Qi F S，Wang Z S，Li B K，et al.Numerical study on characteristics of combustion and pollutant formation in a reheating furnace［J］.Thermal Science，2018; 22(5):2103-2112.
[7]Han S H，Baek S W，Kim M Y.Transient radiative heating characteristics of slabs in a walking beam type reheating furnace［J］.International Journal of Heat & Mass Transfer，2009，52(3/4):1005-1011
[8]Khlevnoy B B，Samoylov M L，Grigoryeva I A，et al.Development of high-temperature blackbodies and furnaces for radiation thermometry［J］. International Journal of Thermophysics， 2011，32(7/8):1686-1696.
[9]Jung J H，Lee D E，Kim M Y，et al.Investigation of the slab heating characteristics in a reheating furnace with the formation and growth of scale on the slab surface［J］.International Journal of Heat & Mass Transfer，2010，53(19/20):4326-4332.
[10]Sadiq H，Wong M B，Al-Mahaidi R，et al.Modeling of heat transfer in gas-filled furnace for steel members［J/OL］.Journal of Structural Engineering，2014，140(2)(2013-10-23)［2020-12-27］.https://doi.org/10.1061/(ASCE)ST.1943-541X.0000834.
[11]Liu X，Worl B，Tang G W，et al.Numerical simulation of heat transfer and scale formation in a reheat furnace［J/OL］.Steel Research International，2019，90(4)(2018-10-15)［2020-12-27］.https://doi.org/10.1002/srin.201800385.
[12]Elmabrouk E M.Enhancing the heat transfer in a heat treatment furnace through improving the combustion process in the radiation tubes［J］.IMA Journal of Applied Mathematics，2012，77(1):59-71.
[13]Qi C，Zheng S，Zhou H.Calculations of thermal radiation transfer of C₂H₂ and C₂H₄ together with H₂O，CO₂，and CO in a one-dimensional enclosure using LBL and SNB models［J］.Journal of Quantitative Spectroscopy and Radiative Transfer，2017，197:45-50.

Numerical Simulation of Influence of Intermediate Radiator on Heat Transfer Process in Heating Furnace

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments