References
- Enestam S, Mäkelä K, Backman R and Hupa M: ‘Occurrence of zinc and lead in aerosols and deposits in the fluidized-bed combustion of recovered waste wood. Part 2: Thermodynamic considerations’, Energy Fuels, 2011, 25, (5), 1970–1977.
- Hohman U and Mohr G: ‘High temperature corrosion in biomass-fired boilers’, VGB PowerTech, 2005, 85, (6), 47–52.
- Henderson P, Kjörk A, Ljung P and Nyström O: ‘Superheater corrosion in combustion of biofuels – a status’, Report No. 700, Värmeforsk Service, Stockholm, Sweden, 2000.
- Bakker WT: ‘The effect of deposits on waterwall corrosion in fossil fueled boilers’, Mater. High Temp., 2003, 20, (2), 161–168.
- Enestam S: ‘Corrosivity of hot flue gases in the fluidized bed combustion of recovered waste wood’, PhD thesis, Åbo Akademi, Åbo, Finland, 2011.
- Bradshaw A, Simms NJ and Nicholls JR: ‘Passage of trace metal contaminants through hot gas paths of gas turbines burning biomass and waste-fuels’, Fuel, 2008, 87, (17–18), 3529–3536.
- Krook J, Mårtensson A and Eklund M: ‘Metal contamination in recovered waste wood used as energy source in Sweden’, Resources Conserv. Recycl., 2004, 41, (1), 1–14.
- Krause HH and Wright IG: ‘Boiler tube failures in municipal waste-to-energy plants’, Mater. Perf., 1996, 35, (1), 46–54.
- Kohan AL: ‘Boiler operator’s guide’, 4th edn; 1997, New York, McGraw-Hill Profetional.
- Pinder LW, Dawson K and Tatlock GJ: ‘1·22 – High temperature corrosion of low alloy steels’, in ‘Shreir’s corrosion’, (ed. B. Cottis et al.), 558–582; 2010, Oxford, Elsevier.
- Davis CJ, James PJ, Pinder LW and Mehta AK: ‘Effects of fuel composition and combustion parameters on furnace wall fireside corrosion in pulverised coal-fired boilers’, Mater. Sci. Forum, 2001, 369–372, 857–864.
- Reese E and Grabke HJ: ‘influβ von chloriden auf die oxidation des 2¼ Cr–1Mo–stahls’, Werkst. Korros., 1992, 43, 547–557.
- Grabke HJ, Spiegel M and Zahs A: ‘Role of alloying elements and carbides in the chlorine-induced corrosion of steels and alloys’, Mater. Res., 2004, 7, 89–95.
- Szakalos P, Henderson P and Pettersson R: ‘Mechanisms of chlorine induced corrosion and effect of sulphur additions in superheater corrosion in biomass- and waste fired boilers’, Proc. 16th Int. Corrosion Cong., Beijing, China, September 2005, Chinese Society for Corrosion and Protection. 13–36.
- Ishitsuka T and Nose K: ‘Stability of protective oxide films in waste incineration environment – solubility measurement of oxides in molten chlorides’, Corros. Sci., 2002, 44, (2), 247–263.
- Pettersson C, Pettersson J, Asteman H, Svensson JE and Johansson LG: ‘KCl-induced high temperature corrosion of the austenitic Fe–Cr–Ni alloys 304L and Sanicro 28 at 600°C’, Corros. Sci., 2006, 48, (6), 1368–1378.
- Alipour Y, Viklund P and Henderson P: ‘The analysis of furnace wall deposits in a low-NOx waste wood-fired bubbling fluidised bed boiler’, VGB PowerTech, 2012, 12, 96–100.
- Andersson JO, Helander T, Höglund L, Shi P and Sundman B: ‘Thermo-Calc and DICTRA, computational tools for materials science’, Calphad, 2002, 26, (2), 273–312.
- Kawahara Y and Kaihara Y: ‘Recent trends in corrosion-resistant tube materials and improvements of corrosion environments in WTE plants’, Proc. Conf. Corrosion 2001, Houston, TX, USA, March 2001, NACE International. 1173.
- Spiegel M, Zahs A and Grabke HJ: ‘Fundamental aspects of chlorine induced corrosion in power plants’, Mater. High Temp., 2003, 20, (2), 153–159.
- Avison J: ‘The world of physics’, 2nd edn; 1989, Cheltenham, Nelson Thornes.
- Naval Facilities Engineering Command: ‘Corrosion control’; 1992, Washtonging, DC, Public Work Center.
- Fontana MG: ‘Corrosion engineering’, 3rd edn; 1987, New York, McGraw-Hill.
- Atkins PW: ‘Physical chemistery’, 8th edn; 2006, Oxford, Oxford University Press.
- Andersson C and Högberg J: ‘Fouling and slagging problems at recovered wood fuel combustion’, Report No. 733, Värmeforsk Service, Stockholm, Sweden, 2001.
- Strömberg B and Svärd SH: ‘The fuel handbook 2012’, Report No. 1234, Värmeforsk Service, Stockholm, Sweden, 2012.
- Henderson P, Szakalos P, Pettersson R, Andersson C and Hogberg J: ‘Reducing superheater corrosion in wood-fired boilers’, Mater. Corros., 2006, 57, (2), 128–134.
- Folkesson N, Jonsson T, Halvarsson M, Johansson LG and Svensson JE: ‘The influence of small amounts of KCl(s) on the high temperature corrosion of a Fe–2·25Cr–1Mo steel at 400 and 500°C’, Mater. Corros., 2011, 62, (7), 606–615.
- Pettersson J, Folkesson N, Johansson L.-G and Svensson J.-E: ‘The effects of KCl, K2SO4 and K2CO3 on the high temperature corrosion of a 304-type austenitic stainless steel’, Oxid. Met., 2011, 76, (1–2), 93–109.
- Folkesson N, Johansson L.-G and Svensson J.-E: ‘Initial stages of the HCl-induced high temperature corrosion of alloy 310’, J. Electorchem. Soc., 2007, 154, (9), C515–C521.
- Nielsen HP, Frandsen FJ, Dam-Johansen K and Baxter LL: ‘The implications of chlorine-associated corrosion on the operation of biomass-fired boilers’, Prog. Energy Combust. Sci., 2000, 26, (3), 283–298.
- Backman R, Hupa M, Hiltunen N and Peltola K: ‘Interaction of Pb and Zn with alkalis in fluidized bed combustion or gasification of waste derived fuels’, Proc. 18th Int. Conf. on ‘Fluidized bed combustion’, Toronto, Canada, May 2005, ASME, Paper FBC2005-78074, 651–659.
- Young D J (ed.): ‘Effects of water vapour on oxidation’, in ‘Corrosion series’, 455–495; 2008, Amsterdam, Elsevier Science.
- Asteman H, Svensson J.-E, Norell M and Johansson L.-G: ‘Influence of water vapor and flow rate on the high-temperature oxidation of 304L: effect of chromium oxide hydroxide evaporation’, Oxid. Met., 2000, 54, (1–2), 11–26.
- Hänsel M, Boddington CA and Young DJ: ‘Internal oxidation and carburisation of heat-resistant alloys’, Corros. Sci., 2003, 45, (5), 967–981.
- Szakálos P: ‘Mechanisms of metal dusting’, PhD thesis, KTH Royal Institute of Technology, Stockholm, Sweden, 2004.
- Giggins CS and Pettit FS: ‘Corrosion of metals and alloys in mixed gas environments at elevated temperatures’, Oxid. Met., 1980, 14, (5), 363–413.
- Viklund P: ‘Superheater corrosion in biomass and waste fired boilers: characterisation, causes and prevention of chlorine-induced corrosion’, PhD thesis, KTH Royal Institute of Technology, Stockholm, Sweden, 2013.
- Abels JM and Strehblow HH: ‘A surface analytical approach to the high temperature chlorination behaviour of inconel 600 at 700°C’, Corros. Sci., 1997, 39, (1), 115–132.
- Zahs A, Spiegel M and Grabke HJ: ‘Chloridation and oxidation of iron, chromium, nickel and their alloys in chloridizing and oxidizing atmospheres at 400–700°C’, Corros. Sci., 2000, 42, (6), 1093–1122.
- Gullett BK, Bruce KR and Beach LO: ‘The effect of metal catalysts on the formation of polychlorinated dibenzo-p-dioxin and polychlorinated dibenzofuran precursors’, Chemosphere, 1990, 20, (10–12), 1945–1952.
- Kawahara Y: ‘High temperature corrosion mechanisms and effect of alloying elements for materials used in waste incineration environment’, Corros. Sci., 2002, 44, (2), 223–245.
- Alipour Y, Henderson P and Szakálos P: ‘The effect of a nickel alloy coating on the corrosion of furnace wall tubes in a waste wood fired power plant’, Mater. Corros., 2014, 65, (2), 217–225.