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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 813-814Preheating Metal Scrap in Foundries Using Solar...

Preheating Metal Scrap in Foundries Using Solar Thermal Energy

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Abstract:

The present scenario of energy conservation has witnessed many innovative and eco-friendly techniques and one such area where there is a necessity to conserve energy is foundries. Foundries also pollute the atmosphere with greenhouse gases contributing to 296143037.6 metric tons annually. The proposed technique in this paper aims at reducing the energy utilized in melting the scrap material at foundries by solar thermal energy. In the methodology proposed, solar energy is concentrated onto the scrap placed on a receiving platform using a parabolic trough and heats it up so that the heated scrap takes lesser energy to melt. The experiments resulted in preheating temperature of 100 °C when placed on a receiving platform and 110°C when copper shots are used to conduct heat from receiver to the scrap. This translates to energy conservation of 6%. This eco-friendly technique when adopted can result in substantial savings in consumption and environmental protection.

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Advances in Mechanical Engineering

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Periodical:

Applied Mechanics and Materials (Volumes 813-814)

Pages:

760-767

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.813-814.760

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Cite this paper

Online since:

November 2015

Authors:

J. Selvaraj*, Chandra C. Jawahar, Khushal A. Bhatija, Saalai Thenagan

Keywords:

Copper Shots, Energy Conservation, Environment, Parabolic Trough, Preheat, Receiver, Scrap, Solar, Thermal

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© 2015 Trans Tech Publications Ltd. All Rights Reserved

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* - Corresponding Author

[1] Bill Nye The Science Guy, BNSG 133, Sun., PBS. 20 November (1998).

[2] Meijer, Fik (1986), A History of Seafaring in the Classical World, Routledge, ISBN 978-0-7099-3565-0.

[3] Cipollone R., Cinocca A. An innovative gas turbine plant for parabolic trough concentratedsolar power plants,. GSTF Journal of Engineering Technology, vol. 2, (2013).

DOI: 10.5176/2251-3701_2.1.30

[4] Renewable Energy in Industrial Applications, United Nations Industrial Development Organization.

[5] Info. on www. norstar. com. au/Recycling/Processing/Benefits. aspx.

[6] Egidio Fedele Dell'Oste, Procedure and means for preheating scrap to be charged into asmelting furnace, (1985).

[7] Ulrich FH Genge, Raymond J Burda, and John W Brandon, Apparatus and method ofpreheating steel scrap for a twin shell electric arc furnace, ed: Google Patents, (1996).

[8] Ulrich Pohl, Process and device for preheating scrap, ed: Google Patents, (1996).

[9] T. Wang, M. Kawakami, K. Mori, and S. H. Shahidan, Analysis of Waste Heat Recovery to Steel Scrap Preheating in an Enclosure Vessel, vol. 452, pp.329-332, (2004).

DOI: 10.4028/www.scientific.net/msf.449-452.329

[10] O Z Sharaf, M F Orhan, (2014, Sep 6) , Concentrated photovoltaic thermal (CPVT) solar collector systems: Part II – Implemented systems, performance assessment, and future directions, [Online]. Available: http: /www. sciencedirect. com/science/article/pii/S1364032114006753.

DOI: 10.1016/j.rser.2014.07.215

[11] T Sarver, A Al-Qaraghuli, L L Kazmerski, A comprehensive review of the impact of dust onthe use of solar energy: History, investigations, results, literature, and mitigation approaches, Renewable and Sustainable Energy Reviews, Volume 22, pp.698-733, June (2013).

DOI: 10.1016/j.rser.2012.12.065

[12] C.Y. Ho, R.W. Powell, P.E. Liley, Thermal Conductivity of Elements: A Comprehensive review, Journal of Physical and Chemical Reference Data, Volume 3, p.242, 366, (1974).

[13] Fabio Struckmann, Analysis of a Flat-plate Solar Collector, pp.3-4, (2008).

[14] Info. on https: /eosweb. larc. nasa. gov.

[15] Info. on http: /www. translatorscafe. com/cafe/units-converter/heat-flux-density/calculator.

[16] Info. on http: /www. freehotwater. com/solar-thermal-101-collector-efficiency.

[17] Top 10 Casting Producers, Modern Casting; vol. 98, issue 12, p.26, Dec2008.

[18] Info. on http: /www. engineeringtoolbox. com/specific-heat-metals-d_152. html.

[19] J.F. Schifo et al, Theoretical/ Best Practice Energy Use In Metalcasting Operation., KERAMIDA Environmental, Inc., Indianapolis, IN, p.4, May (2004).

[20] Info. on http: /www. ndpl. com.

[21] Info. on http: /carbon. ecoforests. org.

[22] YunusA. Cengel, Heat and Mass Transfer, Special Indian ed., Tata McGraw Hill, p.798, (2007).