References

[1] “Climate change 2007:synthesis report,” IPCC, IPCC, Geneva, Switzerland,
Tech. Rep., 2007.

[2] (2010) Sustainable Energy Authority. [Online]. Available: http://www.energy.
gov.lk/sub pgs/energy managment.html

[3] (2008, June) National energy policy & strategies of sri lanka. Ministry
of Power and Energy. [Online]. Available: http://www.ceb.lk/download/db/
national energy policy.pdf

[4] W. E. Council. World energy resources -2013 survey. World Energy Council.
[Online]. Available: http://www.worldenergy.org/wp-content/uploads/2013/09/
Complete WER 2013 Survey.pdf

[5] (2012) Sri lanka energy balance. Sustainable Energy Authority,Sri Lanka.
[Online]. Available: http://www.info.energy.gov.lk/

[6] T. Jurena and J. Hajek, “Mathematical modelling of grate combustion: Bed and
freeboard coupling issues,” in Chemical engineering transactions, P. Varbanov,
J. Klemes, P. Seferlis, A. I. Papadopoulos, and S. Voutetakis, Eds., vol. 35, no.
DOI:10.3303/CET1335164. The Italian Association of Chemical Engineering,
2013, pp. 985–990.

[7] H. Thunman and B. Leckner, “Thermo chemical conversion of biomass and
wastes,” Nordic graduate school BiofuelGS-2,Chalmers, Goteborg, November
2007.

[8] C. D. Blasi, “Multi-phase moisture transfer in the high-temperature drying of
wood particles,” ChemicalChemical Engineering Science, vol. 53, no. 2, pp. 353–
366, 1998.

100

http://www.energy.gov.lk/sub_pgs/energy_managment.html
http://www.energy.gov.lk/sub_pgs/energy_managment.html
http://www.ceb.lk/download/db/national_energy_policy.pdf
http://www.ceb.lk/download/db/national_energy_policy.pdf
http://www.worldenergy.org/wp-content/uploads/2013/09/Complete_WER_2013_Survey.pdf
http://www.worldenergy.org/wp-content/uploads/2013/09/Complete_WER_2013_Survey.pdf
http://www.info.energy.gov.lk/


[9] T. Jurena, “Numerical modelling of grate combustion.” Ph.D. dissertation, Brno
University of Technology,Faculty of Mechanical Engineering,Institute of Process
and ENvironmental Engineering, 2012.

[10] Y.B.Yang, Y.R.Goh, R.Zakaria, R.Nasserzadeh, and J.Swithenbank, “Mathemat-
ical modelling of msw incineration on a travelling bed,” in Waste Management.
Elsevier Science Limited, 2002, vol. 22, pp. 369–380.

[11] Y. B.Yang, C.Ryu, J.Goodfellow, V.N.Sharifi, and J.Swithenbank, “Modelling
waste combustion in grate furnaces,” in Trans IChemE, Part B, Process Safety

and Environmental Protection, vol. 82, 2004, pp. 208–222.

[12] Y.B.Yang, H.Yamauchi, V.Nasserzadeh, and J.Swithenbank, “Effects of fuel de-
volatilisation on the combustion of wood chips and incineration of simulated mu-
nicipal solid wastes in a packed bed,” Fuel, vol. 82, no. 18, Dec 2003.

[13] K.W.Ragland, D.J.Aerts, and A.J.Baker, “Properties of wood combustion for
analysis,” in Bioresource Technology, vol. 37. Elsevier Science Ltd, 1991, pp.
161–168.

[14] Y.B.Yang, V. Sharifi, and J.Swithenbank, “Numerical simulation of the burn-
ing characteristics of thermally-thick biomass fuels in packed-beds,” in Trans

IChemE, Part B,Process Safety and Environmental Protection, vol. 83, 2005, pp.
549–558.

[15] R. Mehrabian, R. Scharler, A. Weissinger, I. Obernberger, and S.Stangl, “Cfd
simulation of biomass grate furnaces with a comprehensive 3d packed bed
model,” in Proceedings of the 25th German Flame Day, September 2011.

[16] C. Ryu, Y. B. Yang, A. Khor, N. E. Yates, V. N. Sharifi, and J. Swithenbank, “Ef-
fect of fuel properties on biomass combustion - identification of the controlling
factors(part two- modelling approach),” in Fuel, vol. 84. Elsevier Ltd., 2005,
pp. 2116–2130.

101



[17] D.Shin and S.Choi, “The combustion of simulated waste particles in a fixed bed,”
in Combustion and flame, vol. 121, The Combustion Institute. Elsevier Science
Inc., 2000, pp. 167–180.

[18] Y. B. Yang, V. N. Sharifi, and J. Swithenbank, “Converting moving-grate in-
cineration from combustion to gasification (numerical simulation of the burning
characteristics),” 2006.

[19] J.C.Wurzenberger, S.Wallner, H.Raupenstrauch, and J.G.Khinast, “Thermal con-
version of biomass: Comprehensive reactor and particle modeling,” in AIChE

Journal, vol. 48, no. 10, October 2002, pp. 2398–2411.

[20] H.Sabelstrom, Tech. Rep.

[21] M. van Blijderveen, “Ignition and combustion phenomena on a moving grate:
with application to the thermal conversion of biomass and municipal solid waste,”
Ph.D. dissertation, University of Twente, December 2011.

[22] R. Mehrabian, R. Scharler, A. Weissinger, and I. Obernberger, “Optimisation of
biomass grate furnaces with a new 3d packed bed combustion model -on example
of a small-scale underfeed stoker furnace,” in 18th European Biomass Conference

& Exhibition. ETA-Renewable Energies (Ed.), Italy, May 2010.

[23] W. Yang, C. Ryu, and S. Choi, “Unsteady one-dimensional model for a bed com-
bustion of solid fuels,” Proceedings of Institution of Mechanical Engineers, vol.
218, 2004.

[24] Y. B. Yang, V. N. Sharifi, J. Swithenbank, L. Lin Ma, I. Darvell, J. M.
Jones, M. Pourkashanian, and A. Williams, “Combustion of a single particle of
biomass,” in Energy & Fuels, vol. 22, no. 1. American Chemical Society, 2008,
pp. 306–316.

[25] C. Brucha, B. Petersb, and T. Nussbaumerc, “Modelling wood combustion under
fixed bed conditions,” in Fuel, vol. 82. El, 2003, pp. 729–738.

102



[26] S. R. Turns, An introduction to combustion-Concepts and Applications, 2nd ed.
Mcgraw Hill, 2000.

[27] A. Frassoldati, A. Cuoci, T. Faravelli, E. Ranzi, C. Candusso, and D. Tolazzi,
“Simplified kinetic schemes for oxy fuel combustion,” in 1st International Con-

ference on Sustainable Fossil Fuels for Future Energy, 2009, pp. 4–5.

[28] H.K.Versteeg and W. Malalasekera, An Introduction to Computational Fluid Dy-

namics. Pearson Education Limited, 2007, no. 978-0-13-127498-3.

[29] R. Bord, W. E.Stewart, and E. N.Lightfoot, Transport Phenomena, 2nd ed.
Chemical Engineering Department,University of Wisconsin: John Wiley &
Sons,Inc, 2002.

[30] L. Davidson. (2011, February) An introduction to turbulence models.
Department of Thermo and fluid dynamics. Chalmers University of Technol-
ogy,Goteborg,Sweden. [Online]. Available: http://www.tfd.chalmers.se/∼lada

[31] J. Karlsson, “Modeling auto-ignition,flame propagation and combustion in non-
stationary turbulent sprays,” Ph.D. dissertation, Chalmers university of technol-
ogy, 1995.

[32] F. P. Karrholm, Numerical Modelling of Diesel Spray Injection and Turbulence

Interaction. Department of Applied Mechanics, Chalmers Univesity of Tech-
nology, 2006, ch. Appendix-Rhie-Chow interpolation in OpenFOAM.

[33] P. Nordin, “Complex chemistry modeling of diesel spray combustion,” Ph.D. dis-
sertation, Chalmers University of Technology,Dept. of Thermo and Fluid Dy-
namics,Goteborg, 2001.

[34] D. Joseph, P. Perez, M. E. Hafi, and B. Cuenot, “Discrete ordinates
and monte carlo methods for radiative transfer simulation applied to cfd
combustion modelling,” Tech. Rep., February 2008. [Online]. Available:
http://www.cerfacs.fr/∼cfdbib/repository/TR CFD 08 21.pdf

103

http://www.tfd.chalmers.se/~lada
http://www.cerfacs.fr/~cfdbib/repository/TR_CFD_08_21.pdf


[35] Y. B.Yang, C. N.Lim, J.Goodfellow, V.N.Sharifi, and J.Swithenbank, “A diffusion
model for particle mixing in a packed bed of burning solids,” in Fuel, vol. 84,
2005, pp. 213–225.

[36] G.IBorman and K.W.Ragland, Combustion Engineering, 1st ed. McGraw-Hill,
1998, no. 0-07-006567-5.

[37] V. Francescato, E. Antonini, L. Z. Bergomi, C. Metschina, C. Schnedl,
N. Krajnc, K. Koscik, P. Gradziuk, G. Nocentini, and S. Stranieri. (2009, April)
Wood fuels handbook. AIEL - Italian Agriforestry Energy Association. [Online].
Available: WWW.BIOMASSTRADECENTRES.EU

[38] B. M. Jenkins, L. L. Baxter, and J. Koppejan, Thermochemical Processing of

Biomass: Conversion into Fuels, Chemicals and Power, R. C.Brown, Ed. John
Wiley & Sons, Ltd., 2011.

[39] B. Jenkins, L. Baxter, T. M. Jr., and T. Miles, “Combustion properties of
biomass,” Fuel processing technology, vol. 54, pp. 17–46, 1998.

[40] (2012, January) Lower and higher heating values of fuels. U.S. Department
of Energy. Hydrogen analysis resource center. [Online]. Available: http:
//hydrogen.pnl.gov/cocoon/morf/hydrogen/site specific/fuel heating calculator

[41] R. H. Perry and D. W.Green, Perry’s Chemical Engineering Hand Book, R. H.
Perry, Ed. McGraw-Hill, 1999.

[42] L. R. l., H. Sabelstrom, S. K. Kaer, H. Sorensen, M. Berry, R. Jensen, S. Heine-
sen, and K. B. Andersen, “Ps02002-4730 development of generalised model for
grate combustion of biomass-final report,” Aalborg University, Tech. Rep., Febru-
ary 2007.

[43] Y.R.Goh, R.G.Siddall, V. Nasserzadeh, R.Zakaria, J.Swithenbank, D.Lawrence,
N.Garrod, and B.Jones, “Mathematical modelling of the waste incinerator burn-
ing bed,” Journal of the Inst. Of Energy, 1998.

104

WWW.BIOMASSTRADECENTRES.EU
http://hydrogen.pnl.gov/cocoon/morf/hydrogen/site_specific/fuel_heating_calculator
http://hydrogen.pnl.gov/cocoon/morf/hydrogen/site_specific/fuel_heating_calculator


[44] Y.R.Goh, C.N.Lim, K.H.Chan, R.Zakaria, G.Reynolds, Y.B.Yang, R.G.Siddall,
V.Nasserzadeh, and J.Swithenbank, “Mixing, modelling and measurements of
incinerator bed combustion,” in 2nd International Symposium on Incineration

and Flue Gas Treatment Technology, 1999.

[45] A. Kimbrell, “Development and verification of a navier-stokes solver with vor-
ticity confinement using openfoam,” Master’s thesis, University of Tennessee,
2012.

[46] E.Kindler and I.Krivy, “Object-oriented simulation of systems with sophisticated
control,” in International Journal of General Systems, 2011, pp. 313–343.

[47] L. John and L. William, section 1.6”Object-Oriented Programming”, 2008, no.
ISBN 0-321-53205-8.

[48] B. Wuthrich, “Simulation and validation of compressible flow in nozzle geome-
tries and validation of openfoam for this application,” Master’s thesis, Institute of
Fluid Dynamics,ETH Zurich, 2007.

[49] OpenFOAM Programmer’s Guide v2.2.1. OpenFOAM Foundation, 2013, June.

[50] OpenFOAM User Guide v2.1.0. OpenFOAM Foundation, 2011, December.

[51] http://openfoamwiki.net/index.php/Contrib/swak4Foam. (2014, April)

[52] B. F. Gschaider, README for swak4Foam, 2012.

[53] http://openfoamwiki.net/index.php/Contrib/groovyBC. (2014, April)

[54] http://openfoamwiki.net/index.php/Contrib/PyFoam.

[55] N.Wakao and S.Kaguei, Heat and Mass Transfer in Packed Beds. Gorden &
Breach Science Publishers& Breach Science Publishers, 1982.

[56] T. Lang, K. D. Johansen, E. Garrijo, P. Glarborg, T. Grotkjaer, A. D. Jensen,
P. A. Jensen, J. E. Johnsson, A. Kavalauskas, J. N. Knudsen, K. B. Pedersen, and
H. Zhou, “Straw combustion on a grate physical, chemical and reaction kinetic

105



data for grate modeling(the joint project ),” Department of Chemical Engineering,
Technical University of Denmark and Department of Mechanical Engineering,
Technical University of Denmark, Tech. Rep., May 2005.

[57] F. P. Karrholm, “Numerical modelling of diesel spray injection, turbulence inter-
action and combustion,” Ph.D. dissertation, Chalmers University of Technology,
Department of Applied Mechanics, Chalmers University of Technology, Gote-
borg, Sweden, 2008.

106