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Material Protection: A Challenge in Waste to Energy Plants

Sukhminderbir Singh Kalsi*
*Professor, Department of Mechanical Engineering, Amritsar College of Engineering and Technology, Amritsar, Punjab, India.
Periodicity:April - June'2016
DOI : https://doi.org/10.26634/jms.4.1.5981

Abstract

The management of municipal waste is a big challenge all over the world. Although, it can be reduced to a large extent by incineration process, a large amount of thermal energy can be generated. But, Waste to Energy (WTE) plants all over the world are running at very low efficiency due to the problem of hot corrosion of boiler tubes. It is required to understand the phenomena of hot corrosion in waste to energy plants in depth, in order to develop the new techniques for the protection of boiler tubes from hot corrosion. The presence of chloride salts in waste to energy plants give rise to active oxidation, resulting in rapid rate of materials degradation. The aim of this paper is to explore the mechanism of hot corrosion in waste to energy plant with support of present literature.

Keywords

 Waste to Energy Plants, Hot Corrosion, Active Oxidation, Chlorine.

How to Cite this Article?

 Kalsi, S. S. (2016). Material Protection: A Challenge in Waste to Energy Plants. i-manager’s Journal on Material Science, 4(1), 1-5. https://doi.org/10.26634/jms.4.1.5981

References
[1]. Albina, D.O., (2005). “Theory and Experience on Corrosion of Water wall and Super heater Tubes of Waste-To- Energy Facilities”. (Master Thesis), Columbia University.
[2]. Deuerling, C., Maguhn, J., Nordsieck, H., Benker, B., Zimmermann, R., and Warnecke, R., (2009). “Investigation of the Mechanisms of Heat Exchanger Corrosion in a Municipal Waste Incineration Plant by Analysis of the Raw Gas and Variation of Operating Parameters”. Heat Transf. Eng., Vol. 30(10-11), pp.822-831.
[3]. Eliaz, N., Shemesh, G., and Latanision, R. M., (2002). “Hot Corrosion in Gas Turbine Components”. Eng. Fail. Anal., Vol. 9, pp. 31-43.
[4]. Hancock, P., (1987). “Vanadic and Chloride Attack of Super alloys”. Mater. Sci. Technol., Vol. 3, pp. 536-544.
[5]. Kalsi, S. S., Sidhu, T. S., and Singh, H., (2013A). “Characterization of NiCrAlY Coatings on Ni- And Fe- based Superalloys by the Cold Spray Process”. i-manager's Journal on Material Science. Vol. 1(2), Jul-Sep 2013, Print ISSN 2347–2235, E-ISSN 2347–615X, pp. 20-26.
[6]. Kalsi, S.S., Sidhu, T.S., and Singh, H., (2013B). “Characterization of Cold-Sprayed NiCoCrAlY Coatings on Fe-Based Superalloy and Hot Corrosion Behavior in Na SO - 2 4 NaCl Environment”. i-manager's Journal on Future Engineering and Technology, Vol. 9(1), Aug-Oct 2013, Print ISSN 0973-2632, E-ISSN 2230-7184, pp. 15-26.
[7]. Kalsi, S. S., Sidhu, T. S., and Singh, H., (2013C). “Hot Corrosion in Bio Medical Waste Incinerator and Cold Spray Coatings - A Review”. i-manager's Journal on Material Science. Vol. 1(2), Jul-Sep 2013, Print ISSN 2347–2235, EISSN 2347–615X, pp. 1-12.
[8]. Kalsi, S. B. S., Sidhu T. S., and Singh H., (2013D). “Chlorine Based Hot Corrosion Study of Cold Sprayed NiCrAlY Coating”. Surf. Eng., Vol. 30(6), pp.422- 431.
[9]. Kalsi, S. B. S., Sidhu T. S., and Singh H., (2014A). “Performance of Cold Spray Coating in Industrial Medical Waste Incinerator”. Surf. Eng., Vol. 30(5), pp. 352-360.
[10]. Kalsi, S. S., Sidhu, T. S., Singh, H., and Karthikeyan, J., (2014B). “Behavior of Cold Spray Coating in Real Incineration Environment”. Mater. Manufact. Process., DOI:10.1080/10426914.2014.912319.
[11]. Kalsi, S. S., Sidhu, T. S., Singh, H., and Karthikeyan, J., (2014C). “Analysis of material degradation for uncoated and NiCoCrAlY cold spray coated Superfer 800H in the secondary chamber of medical waste incinerator”. Engineering Failure Analysis, Vol. 46, pp. 238-246.
[12]. Kalsi, S.S., Sidhu, T.S., and Singh, H., (2014D). “Performance of Cold Spray Coatings On Fe-Based o Superalloy in Na2SO4-NaCl Environment at 900 C”. Surf. Coat. Technol., Vol. 240, pp. 456-463.
[13]. Kawahara, Y. and Kira, M., (1997). “Effect of Physical Properties of Molten Deposits on High Temperature Corrosion of Alloys in Waste Incineration Environment”. Zairyo-to-Kankyo, Vol. 46(1), pp. 8-15.
[14]. Kawahara, Y., (2002A). “Recent Trends in Development and Application of High-temperature Corrosion-resistant Materials and Coatings in High Efficiency Waste Incineration Boiler”. MTERE2, Vol. 41(3), pp. 190.
[15]. Kawahara Y., (2006). “Application of High Temperature Corrosion-Resistant Materials and Coatings Under Severe Corrosive Environment in Waste-to-Energy Boilers”. Therm. Spray Technol., Vol. 16(2), pp. 202-213.
[16]. Kawahara, Y., Nakamura, M., Tsuboi, H. and K. Yukawa, K., (1998). “Evaluation of New Corrosion Resistant Super heater Tubings in High Efficiency Waste-to-Energy Plants”. Corros., Vol. 54(7), pp. 576.
[17]. Lee, S. H., Themelis, N. J., and Castaldi, M. J., (2007). “High-Temperature Corrosion in Waste-to-Energy Boilers”. J. of Therm. Spray Technol., Vol. 16(1), pp.104-110.
[18]. Michelsen, H. P., Frandsen, F., Dam-Johansen, K., and Larsen, O. H., (1998). “Deposition and High Temperature Corrosion in a 10 MW Straw Fired Boiler”. Fuel Process. Technol., Vol. 54, pp. 95-108.
[19]. Pedersen, J. I. A., Flemming, J. F., and Christian, R., (2009). “A Full-scale Study on the Partitioning of Trace Elements in Municipal Solid Waste Incinerations Effects of Firing Different Waste Types”. Energy & Fuels, Vol. 23, pp. 3475- 3489.
[20]. Rademarkers, P., Hesseling, W., and Wetering, J., (2002). “Review on Corrosion in Waste Incinerators, and Possible Effect of Bromine”. TNO Industrial Technology.
[21]. Rapp, R.A., (1986). “Chemistry and Electrochemistry of the Hot Corrosion of Metals”. Corros., Vol. 42(10), pp. 568-577.
[22]. Ruth, L.A., (1998). “Energy From Municipal Solid Waste: A Comparison With Coal Combustion Technology”. Prog. Energy Combust. Sci., Vol. 24, pp. 545-564.
[23]. Shinata, Y., and Nishi, Y., (1986). “NaCl-Induced Accelerated Oxidation of Chromium”. Oxidat. of Metals, Vol. 26, pp.201-212.
[24]. Singh, H., Sidhu, T.S., and Kalsi, S.S., (2014A). “Development and Characterization of Cr C -NiCr Coated 3 2 Super alloy by Novel Cold Spray Process”. Surf. Eng. DOI: 1 0.1080/ 104269 14.2014 973599.
[25]. Singh, H., Sidhu, T.S., and Kalsi, S.S., (2014B). “Evolution of Microstructure by High Velocity Impacts of Particles by Cold Spray”. Mater. Manufact. Process. DOI:10.1080/ 10426914.2014. 994766.
[26]. Singh, H., Sidhu, T.S., and Kalsi, S.S., (2014C), “Microstructure study of cold sprayed 50%Ni–50%Cr coating on Inconel-601”. Surf. Eng., Vol. 31(11), pp. 825-831.
[27]. Singh, H., Sidhu, T.S., and Kalsi, S.S., (2014D). “Behavior of Ni-based super alloys in actual waste incinerator plant under cyclic conditions for 1000h at 900°C”. Corrosion, Vol. 70(12), pp. 1249-1263.
[28]. Singh, H., Sidhu, T.S., and Kalsi, S.S., (2015). “Evaluation of characteristics and behavior of cold sprayed Ni–20Cr coating at elevated temperature in waste incinerator plant”. Surf. Coat. Technol., Vol. 261, pp. 375-384.
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