CFP last date
20 June 2024
Reseach Article

Mathematical Modeling & Simulation of Effective Heat Energy Loss in Steel Industry

Published on April 2012 by Mahendra S. Dhande, S.S. Khandare
International Conference on Emerging Frontiers in Technology for Rural Area (EFITRA-2012)
Foundation of Computer Science USA
EFITRA - Number 2
April 2012
Authors: Mahendra S. Dhande, S.S. Khandare
511cdf09-54b0-4315-a4d3-0f843c2a78a6

Mahendra S. Dhande, S.S. Khandare . Mathematical Modeling & Simulation of Effective Heat Energy Loss in Steel Industry. International Conference on Emerging Frontiers in Technology for Rural Area (EFITRA-2012). EFITRA, 2 (April 2012), 21-25.

@article{
author = { Mahendra S. Dhande, S.S. Khandare },
title = { Mathematical Modeling & Simulation of Effective Heat Energy Loss in Steel Industry },
journal = { International Conference on Emerging Frontiers in Technology for Rural Area (EFITRA-2012) },
issue_date = { April 2012 },
volume = { EFITRA },
number = { 2 },
month = { April },
year = { 2012 },
issn = 0975-8887,
pages = { 21-25 },
numpages = 5,
url = { /proceedings/efitra/number2/5940-1012/ },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Proceeding Article
%1 International Conference on Emerging Frontiers in Technology for Rural Area (EFITRA-2012)
%A Mahendra S. Dhande
%A S.S. Khandare
%T Mathematical Modeling & Simulation of Effective Heat Energy Loss in Steel Industry
%J International Conference on Emerging Frontiers in Technology for Rural Area (EFITRA-2012)
%@ 0975-8887
%V EFITRA
%N 2
%P 21-25
%D 2012
%I International Journal of Computer Applications
Abstract

In research paper, the potential to use waste energies from the steel production at B.S.P. Bhilai C.G. investigated. B.S.P is a leading producer of high strength steel, such as slab, bloom, billets, wire, ingots, other steel products every year. The study is based on energy balances in the different production lines. The energy balance are investigated with applying three dimensional mathematical model at different energy flows. The work concludes that there is a great potential for increasing the use of waste energy at steel plant. Today many of these flows are pure losses that are cooled away or burnt. The total heat input for the steel production in one year is approximately 38640 MW & output 37128MW from energy calculations it can be shown that the upper theoretical limit when converting the energy into high quality energy such as electricity is produce. The conclusion is that it is possible to recycle an impressive amount of energy. The technologies for these are briefly are to use duck system over the continuous casting long slab. Flow fluid through it and transfer liquid to vapour. Same vapour strike on turbine and electric energy generate, which is helpful to steel plant, extra facility and comfort purpose or by doing so making it possible for the local power company to produce more electricity.

References
  1. Ya Meng and Brian G. Thomas, Heat Transfer and Solidification Model of Continuous Slab Casting : Con1D, Metallurgical and Materials Transactions B. Vlo.34B, No.5. Oct.2003, pp.685-705
  2. C. Beckermann, R. Viskanta, Mathematical modeling of Transport phenomena during alloy solidification, Appl. Mech Rev. Vol 46, no., January 1993, pp. 1 to 27
  3. Mahendra S. Dhande, S.S. Khandare; IJERIA; ISSN, 0974-1518,Vol.4, No.1 (Feb.2011); pp.197 to 208
  4. Mahendra S. Dhande, S.S. Khandare; IJEST, Vol.2, Issue 11, Nov.2010; pp.1 to 5
  5. Mahendra S. Dhande, S.S. Khandare; IJMRAE; ISSN, 0975-7074, Vol.3, No.1, Jan.2011; pp.165-177
  6. B.G. Thomas& I.V. Samarasekera and J. Brimacombe; Application of Mathematical hat Flow and Stress Models of Steel Ingot Casting to Investigate Panel Crack Formation; Modeling and Control of Casting and Welding Processes TMS American Institute of Mining, Metallurgical and Petroleum Enginners Conference Proceedings, Santa Barbara, CA, Jan. 12-17, S.Kou, R. Mehrabian, Eds, 1986, pp. 479 to 495
  7. Bruce Kozak SMS & Joseph Dzierzawsk S., Continuous Casting of Steel : Basic Principles, The Steel Network |Media|, 2011, pp. 1 to 9
  8. Johan Isaksson1,*, Simon Harvey1, Carl-Erik Grip2, Jonny Karlsson3, Possibilities to implement pinch analysis in the steel industry –a case study at SSAB EMEA in Lulea, World Renewable Energy Congress 2011, Sweden, Industrial Energy Efficiency (IEE), 2011, pp. 1660 to 1667
  9. Aravind Sundararajan and Brian G. Thomas; "Heat Transfer During Melt Spinning of AL-7% SI Alloy on a CU-BE Wheel"; Light Metals, 2008 Edited by : david H. Deong TMS (The minerals, Metals & Materials Society), 2008.pp.1-7.
Index Terms

Computer Science
Information Sciences

Keywords

Steel Industry Heat Energy Efficiency Percentage Error