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Original Articles

A One-Dimensional Transient Solid Fuel Conversion Model for Grate Combustion Optimization

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Pages 1208-1228 | Received 29 Oct 2013, Accepted 06 Mar 2015, Published online: 05 May 2015

REFERENCES

  • Ashtana, A., Yannick, M., Sessiecq, P., and Patisson, F. 2010. Modeling on-grate MSW incineration with experimental validation in a batch incinerator. Ind. Eng. Chem. Res., 49, 7597–7604.
  • Bruch, C., Peters, B., and Nussbaumer, T. 2002. Modelling wood combustion under fixed bed conditions. Fuel, 82, 729–738.
  • Chan, W.C., Kelbon, M., and Krieger, B.B. 1985. Modelling and experimental verification of physical and chemical processes during pyrolysis of large biomass particles. Fuel, 64, 1505–1513.
  • Collazo, J., Portiero, J., Patiño, D., and Granada, E. 2012. Numerical modeling of the combustion of densified wood under fixed–bed conditions. Fuel, 93, 149–159.
  • Di Blasi, C. 1993. Modeling and simulation of combustion processes of charring and non-charring solid fuels. Prog. Energy Combust. Sci., 19, 71–104.
  • Di Blasi, C. 1996. Heat, momentum and mass transport through a shrinking biomass particle exposed to thermal radiation. Chem. Eng. Sci., 51, 1121–1132.
  • Di Blasi, C. 2004. Modeling wood gasification in a countercurrent fixed-bed reactor. AIChE J., 50, 2306–2319.
  • EngineeringToolbox. 2013. Specific heat of carbon monoxide gas -CO- at temperatures ranging 175–6000 K. The Engineering ToolBox. Available at: http://www.engineeringtoolbox.com/carbon-monoxided_975.html.
  • Essenhigh, R.H., and Kuo, T.J. 1970. Combustion and emission phenomena in incinerators: Development of physical and mathematical models of incinerators, Part I: Statement of the problem. In Proceedings of the National Incinerator Conference, ASME, New York, pp. 261–271.
  • Goh, Y.R., Siddall, R.G., Nasserzadeh, V., Zakaria, R., Swithenbank, J., Lawrence, D., Garrod, N., and Jones, B. 1998. Mathematical modelling of the waste incinerator burning bed. J. Inst. Energy, 71, 110–118.
  • Goh, Y.R., Yang, Y.B., Zakaria, R., Siddall, R.G., Nasserzadeh, V., and Swithenbank, J. 2001. Develpment of an incinerator bed model for municipal solid waste incineration. Combust. Sci. Technol., 162, 37–58.
  • Hagge, M.J., and Bryden, K.M. 2002. Modeling the impact of shrinkage on the pyrolysis of dry biomass. Chem. Eng. Sci., 57, 2811–2823.
  • Haseli, Y., van Oijen, J.A., and de Goey, L.P.H. 2011. Modeling biomass particle pyrolysis with temperature-dependent heat of reactions. J. Anal. Appl. Pyrolysis, 90, 140–154.
  • Johansson, R., Thunman, H., and Leckner, B. 2007. Influence of intraparticle gradients in modeling of fixed bed combustion. Combust. Flame, 149, 49–62.
  • Kær, S.K. 2004a. Numerical modelling of a straw-fired grate boiler. Fuel, 83, 1183–1190.
  • Kær, S.K. 2004b. Straw combustion on slow-moving grates—A comparison of model predictions with experimental data. Biomass Bioenergy, 28, 307–320.
  • Kiener, M., and Nussbaumer, T. 2012. Influence of uneven fuel distribution on a grate on gas flow conditions and combustion quality. Presented at the 20th European Biomass Conference and Exhibition, Milan, Italy, June 18–22, pp. 1112–1117.
  • Liden, A.G., Berruti, F., and Scott, D.S. 1988. A kinetic model for the production of liquids from the flash pyrolysis of biomass. Chem. Eng. Commun., 65, 207–221.
  • Lu, H., Robert, W., Peirce, G., Ripa, B., and Baxter, L.L. 2008. Comprehensive study of biomass particle combustion. Energy Fuels, 22, 2826–2839.
  • Nussbaumer, T., and Kiener, M. 2013. Moving grate combustion optimisation with CFD and PIV. Presented at the 21st European Biomass Conference and Exhibition, Cophenhagen, Denmark, June 3–7, pp. 1112–1117.
  • Okuga, A. 2007. Analysis and operability optimization of an updraft gasifier unit. Master thesis. Department of Mechanical Engineering, Eindhoven University of Technology, Eindhoven, Netherlands.
  • Pantakar, S. 1980. Numerical Heat Transfer and Fluid Flow, Hemisphere, New York.
  • Peters, B. 2002. Measurements and application of a discrete particle model (DPM) to simulate combustion of a packed bed of individual fuel particles. Combust. Flame, 131, 132–146.
  • Peters, B. 2003. Thermal Conversion of Solid Fuels, WIT Press, Southampton, UK.
  • Peters, B., and Bruch, C. 2003. Drying and pyrolysis of wood particles: Experiments and simulation. J. Anal. Appl. Pyrolysis, 70, 233–250.
  • Petzold, L.R. 1983. Automatic selection of methods for solving stiff and nonstiff systems of ordinary differential equations. J. Sci. Stat. Comput., 4, 136–148.
  • Portiero, J., Granada, E., Patiño, D., and Morán, J.C. 2007. A model for the combustion of large particles of densified wood. Energy Fuels, 21, 3151—3159.
  • Schiesser, W.E. 1991. The Numerical Method of Lines, Academic Press, San Diego, CA.
  • Schlünder, E.U., and Tsotsas, E. 1988. Wärmeübertragung in Festbetten, Durchmischten Schüttungen und Wirbelschichten, Thieme Verlag, Stuttgart.
  • Schroer, K., Guillmann, P., and Görner, K. 2008. Probleme beim Einsatz von Ersatzbrennstoffen in Kleinen Dezentralen Anlagen, Deutscher Flammentag, Berlin.
  • Shin, D., and Choi, S. 2000. The combustion of simulated waste particles in a fixed bed. Combust. Flame, 121, 167–180.
  • Thunman, H. 2001. Principles and models of solid fuel combustion. PhD thesis. Department of Energy Conversion, Chalmers University of Technology, Göteborg, Sweden.
  • Troccia, N., Palmeri, F., and Gallucci, F. 2012. Combustion modeling of a biomass packed bed in moving grate furnaces. Presented at the 20th European Biomass Conference and Exhibition, Milan, Italy, June 18–22, pp. 1276–1285.
  • Van der Lans, R.P., Pedersen, L.T., Jensen, A., Glarbog, P., and Dam-Johansen, K. 2000. Modelling and experiments of straw combustion in a grate furnace. Biomass Bioenergy, 19, 199–208.
  • Wakao, N., and Funazkri, T. 1978. Effect of fluid dispersion coefficients on particle-to-fluid mass transfer coefficients in packed beds: Correlation of sherwood numbers. Chem. Eng. Sci., 33, 1375–1384.
  • Yang, Y.B., Goh, Y.R., Zakaria, R., Nasserzadeh, V., and Swithenbank, J. 2002. Mathematical modelling of MSW incineration on a travelling bed. Waste Manage., 22, 369–380.
  • Yang, Y.B., Ryu, C., Goodfellow, J., Shafiri, V.N., and Swithenbank, J. 2004. Modelling waste combustion in grate furnaces. Trans. IchemE, Part B, 82(B3), 208–222.
  • Yang, Y.B., Ryu, C., Khor, A., Yates, N.E., Sharifi, V.N., and Swithenbank, J. 2005a. Effect of fuel properties on biomass combustion. Part II. Modelling approach-identification of the controlling factors. Fuel, 84, 2116–2130.
  • Yang, Y.B., Sharifi, V.N., and Swithenbank, J. 2005b. Numerical simulation of the burning characteristics of thermally-thick biomass fuels in packed-beds. Trans. IchemE, Part B, 83(B6), 549–558.
  • Yang, Y.B., Sharifi, V.N., Swithenbank, J., Ma, L., Darvell, L.I., Jones, J.M., Pourkashanian, M., and Williams, A. 2008. Combustion of a single particle of biomass. Energy Fuels, 22, 306–316.
  • Zhou, H., Jensen, A.D., Glarborg, P., Jensen, P.A., and Kavaliauskas, A. 2005. Numerical modeling of straw combustion in a fixed bed. Fuel, 84, 389–403.

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