THERMAL SCIENCE

International Scientific Journal

Authors of this Paper

External Links

Demin Chen

,

Zihuai He

,

Yibo Zhao

,

Biao Lu

A NOVEL ACQUISITION APPROACH FOR HEAT TRANSFER COEFFICIENT DURING PERIODIC COOLING PROCESS

ABSTRACT
Temperature is an important parameter affecting the micro-structure of slab and an important guarantee to improve the performance index of metallurgical products. However, the temperature level is affected by the heat transfer coefficient. Taking laminar cooling as an example, a method for calculating the heat transfer coefficient of a system with periodic characteristics is proposed in this study. Firstly, it was assumed that the distribution of heat transfer coefficient is a piecewise function composed of positive half wave of sine function and line function. The calculation methods of characteristic parameters, through structural parameters and operating parameters, in three cases of “separation”, “adjacent” and “intersection” are given. Secondly, heat transfer model of slab was established. Surface temperature and center temperature distribution of slab were compared with the test results. The relative errors of surface and center temperature were 2.46% and 1.33%, respectively, which verified the accuracy of this method. Finally, the coupling relationship between the characteristic parameters in the heat transfer coeficient distribution function is obtained by calculation. Compared with the methods presented in the literature, this method reduces the number of unknown parameters while ensuring the accuracy of the model, and gives guidance on how to change the slab temperature and improve product performance by adjusting the structure and operating parameters.
KEYWORDS
heat transfer coefficient, Periodic Cooling, Positive Half Wave, characteristic parameters, Coupling Relationships
PAPER SUBMITTED: 2021-12-11
PAPER REVISED: 2022-01-22
PAPER ACCEPTED: 2022-01-24
PUBLISHED ONLINE: 2022-03-05
DOI REFERENCE: https://doi.org/10.2298/TSCI211211035C
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2022, VOLUME 26, ISSUE Issue 4, PAGES [3097 - 3106]
REFERENCES
  1. Xuying Wang, et al., A unit-based emission inventory of SO2, NOx and PM for the Chinese iron and steel industry from 2010 to 2015, SCIENCE OF THE TOTAL ENVIRONMENT, 676(2019), pp.18-30.
  2. Chengkang Gao, et al., Comprehensive evaluation on energy-water saving effects in iron and steel industry, Science of the Total Environment, 670(2019), pp.346-360.
  3. Kazuaki Y, et al., Optimization of thermoelectric topping combined steam turbine cycles for energy economy, Applied Energy, 109(2013), pp.1-9.
  4. Bing Xiong, et al., Modeling and performance analysis of a two-stage thermoelectric energy harvesting system from blast furnace slag water waste heat, Energy, 77(2014), pp. 562-569.
  5. Changxin Liu, et al., System dynamics analysis on characteristics of iron-flow in sintering process, Applied Thermal Engineering, 82(2015), pp.206-211.
  6. Lu B., et al., An All-Factors Analysis Approach on Energy Consumption for the Blast Furnace Iron Making Process in Iron and Steel industry, Processes, 607(2019), 7, pp.607.
  7. Lu B., et al., An energy intensity optimization model for production system in iron and steel industry, Applied Thermal Engineering, 100(2016), pp.285-295.
  8. Jia Jia, et al., Emission characteristics and chemical components of size-segregated particulate matter in iron and steel industry, Atmospheric Environment, 182(2018), pp.115-127.
  9. Haozhe Yang, et al., The contribution of the Beijing, Tianjin and Hebei region's iron and steel industry to local air pollution in winter, Environmental Pollution, 245(2019), pp.1095-1106.
  10. Qi Zhang, et al., Optimization of energy use with CO2 emission reducing in an integrated iron and steel plant, Applied Thermal Engineering, 157(2019), pp.113635.
  11. Chen L. G., et al., Thermodynamic optimization opportunities for the recovery and utilization of residual energy and heat in China's iron and steel industry: A case study, Applied Thermal Engineering, 86(2015), pp.151-160.
  12. Zhaoling Li, et al., Assessment of the carbon emissions reduction potential of China's iron and steel industry based on a simulation analysis, Energy, 183(2019), pp. 279-290.
  13. Lu B., et al., A novel approach for lean energy operation based on energy apportionment model in reheating furnace, Energy, 182(2019), pp.1239-1249.
  14. China Iron and Steel Association, China Steel Annual Development Report(in Chinese), Beijing:China Iron and Steel Association, pp.2017:29-30.
  15. Zongguo Wen, et al., Quantitative analysis of the precise energy conservation and emission reduction path in China's iron and steel industry, Journal of Environmental Management, 246(2019), pp.717-729.
  16. Hai-ling Li, et al., Environmental regulations, environmental governance efficiency and the green transformation of China's iron and steel enterprises, Ecological Economics, 165(2019), pp.106397.
  17. Shu-hua Ma, et al., Mode of circular economy in China's iron and steel industry: a case study in Wu'an city, Journal of Cleaner Production, 64(2014), pp.505-512.
  18. Gong Dian-yao, et al., Self-Learning and Its Application to Laminar Cooling Model of Hot Rolled Strip, Journal of Iron and Steel Research, International, 14(2007),4, pp.11-14.
  19. H.B. Xie, et al., Application of fuzzy control of laminar cooling for hot rolled strip, Journal of Materials Processing Technology, 2007,187-188 :715-719.
  20. Jinxiang Pian, et al., A hybrid soft sensor for measuring hot-rolled strip temperature in the laminar cooling process, Neurocomputing, 169(2015), pp.457-465.
  21. Peng Lianggui, et al., Mathematic modeling on flexible cooling system in hot strip mill, Journal of Central South University, 21(2014), pp.43-49.
  22. Han B., Research on modeling and control for laminar cooling in hot strip mill. Shenyang: Norteasterm University, 2005, pp.11,19.
  23. Jinxiang Pian, et al., A hybrid soft sensor for measuring hot-rolled strip temperature in the laminar cooling process, Neurocomputing, 169(2015), pp.457-465.
  24. Yi Zheng, et al., Distributed model predictive control for plant-wide hot-rolled, Journal of Process Control, 19(2009), pp.1427-1437.
  25. Zhang Dian-hua, et al., Cooling Efficiency of Laminar Cooling System for Plate Mill. Journal of Iron and Steel Research, International, 15(2008),5, pp.24-28.
  26. Liu En-yang, et al., Algorithm Design and Application of Laminar Cooling Feedback Control in Hot Strip Mill, Journal of Iron and Steel Research, International, 19(2012),4, pp.39-42.
  27. Wang M T, et al., Experimental Study on the Laminar Cooling Process of the Middle and Heavy Plate, Applied Mechanics and Materials, 232(2012), pp.808-811.
  28. Wen-hong LIU, et al., Mathematical Modeling and Experimental Study of Inverse Heat Conduction Problems of Heavy Plate Laminar Cooling Process, Advances in Computer Science Research, 54(2016), pp.408-412.
  29. Wen-Hong Liu, et al., Experimental Study and Application of Process Control on Hot Strip Mill's aminar Cooling System, Advances in Computer Science Research, 52(2016), pp.513-516.
  30. Yipeng Liu., Laminar Cooling Experiment of Moving Plate at High Temperature and Study on Calculation Based on Inverse Heat. Master of Engineering, Shanghai Jiao Tong University. Shanghai, China, 5(2009),pp.11-26.
  31. Han Bin, et al., Flow Field Simulation in Header Pipe of Laminar Cooling System for Hot Rolling and Theoretical Calculation of Impact Pressure, Journal of Iron and Steel Research. 16(2004), 5,pp.42-46.
  32. Zhu Qijian, et al., Numerical Simulation of Transient Temperature Field of Steel Plate Cooled with Circular Laminar Jets after Rolling, Transactions of Materials and Heat Treatment. 25(2004), 2, pp.72-75.
  33. A.H. Nobari, et al., Modeling of heat transfer during controlled cooling in hot rod rolling of carbon steels, Applied Thermal Engineering. 31(2011), pp.487-492.
  34. Sheila Edalatpour, et al., Effect of phase transformation latent heat on prediction accuracy of strip laminar cooling, Journal of Materials Processing Technology, 211(2011), pp.1776-1782.
  35. Yi Zheng, et al., Distributed model predictive control for plant-wide hot-rolled strip laminar cooling process, Journal of Process Control, 19(2009), pp.1427-1437.
  36. Lian-yun Jiang, et al., Hot Rolled Strip Re-reddening Temperature Changing Law during Ultra-fast Cooling, Journal of Iron and Steel Research, International, 22(2015),8, pp. 694-702.
  37. Yu Qing-bo, et al., Solving Heat-Transfer Coefficient of Laminar Cooling by Neutral Networks(in Chinese), Journal of Northeastern University(Natural Science), 23(2002), pp.573-576.
  38. Xie Hai-bo, et al., Optimization and Model of Laminar Cooling Control Thickness measurement System for Hot Strip Mills, Journal of Iron and Steel Research, International, 13(2006),1, pp.18-22.
  39. Sang Heon Han, et al., Efficiency analysis of radiative slab heating in a walking-beam-type reheating furnace, Energy, 36(2011), pp.1265-1272.
  40. Li hao, Study on Structural Parameters of Walking-beam Reheating Furnace Based on Zonal Method, Wuhan: Wuhan University of Science and Technology, 2018, pp.37.
PDF VERSION [DOWNLOAD]
A novel acquisition approach for heat transfer coefficient during periodic cooling process

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence