Biomedical Engineering Reference
In-Depth Information
Aznar, M.P., Delgado, J., Corella, J., Borque, J.A., Campos, I.J., 1997. Steam gasification in fluid-
ized bed of a synthetic refuse containing chlorine with a catalytic gas cleaning at high tem-
perature. In: Bridgwater, A.V., Boocock, D.G.B. (Eds.), Developments in Thermochemical
Biomass Conversion. Blackie Academic and Professional, London, UK, pp. 1194 1208.
ISBN 0 7514 0350 4.
Babu, B.V., Chaurasia, A.S., 2004a. Parametric study of thermal and thermodynamic properties
on pyrolysis of biomass in thermally thick regime. Energ. Convers. Manage. 45 (1), 53 72.
Babu, B.V., Chaurasia, A.S., 2004b. Pyrolysis of biomass: improved models for simultaneous
kinetics and transport of heat, mass and momentum. Energ. Convers. Manage. 45 (9 10),
1297 1327.
Baker, E.G., Brown, M.D., Elliott, D.C., Mudge, L.K., 1988. Characterization and Treatment of
Tars from Biomass Gasifiers. AIChE 1988 Summer National Meeting, Denver, CO,
pp. 1
11.
Barea, A.G., 2009. Personal communication.
Barooah, J.N., Long, V.D., 1976. Rates of thermal decomposition of some carbonaceous
materials in a fluidized bed. Fuel 55, 116 120.
Barrio, M., Hustad, J.E., 2001. CO 2 gasification of birch char and the effect of CO inhibition on
the calculation of chemical kinetics. In: Bridgwater, A.V. (Ed.), Progress in Thermochemical
Biomass Conversion, vol. 1. Blackwell Science, Oxford, pp. 47 60.
Barrio, M., Gøbel, B., Risnes, H., Henriksen, U., Hustad, J.E., Sørensen, L.H., 2001. Steam gasifica-
tion of wood char and the effect of hydrogen inhibition on the chemical kinetics.
In: Bridgwater, A.V. (Ed.), Progress in Thermochemical Biomass Conversion, vol. 1. Blackwell
Science, Oxford, pp. 32 46.
Basu, P., 1977. Burning rate of carbon in fluidized beds. Fuel 56 (4), 390 392.
Basu, P., 2006. Combustion and Gasification in Fluidized Beds. CRC Press, Taylor & Francis,
New York, NY.
Basu, P., Wu, S., 1993. Surface Reaction Rate of Coarse Sub-bituminous Char Particles in the
Temperature Range 600-1340 K, Fuel, October.
Basu, P., Kefa, C., Jestin, L., 2000. Boilers and Burners Design and Theory. Springer, New
York, p. 25.
Basu, P., Butler, J., Leon, M.A., 2011. Biomass co-firing options on the emission reduction and
electricity generation costs in coal-fired power plants. Renew. Energ. 36, 282 288.
Basu, P., Rao, S., Dhungana, A., 2013a. An investigation into the effect of biomass particle size
on its torrefaction. Can. J. Chem. Eng. June 94, 466 474.
Basu, P., Rao, S., Acharya, B., Dhungana, A., 2013b. Effect of torrefaction on the density and
volume changes of coarse biomass particles. Can. J. Chem. Eng. Available from: http://dx.
doi.org/10.1002/c3ce-2817 .
Basu, P., Dhungana, A., Rao, S., Acharya, B., 2013c. Effect of oxygen presence in torrefier.
J. Energy Inst 128.3r in press. 10.1179/.00000000060.
Basu, P., Dhungana, A., Dutta, A., 2013d. Effects of reactor design on the torrefaction of bio-
mass. ASME J. Energ. Res. 134 (4), 11 1062. Available from: http://dx.doi.org/10.1115/
1.4007u84 .
Batista, J.D., Tilaman, D., Hughers, E., 1998. Cofiring wood waste with coal in a wall fired
boiler: initiating a three year demonstration program. Proceedings Ionergy'98, 4 8 October,
Madison, WI, pp. 243 250.
Baumeister, T. (Ed.), 1967. Standard Handbook for Mechanical Engineers. McGraw-Hill.
Behrendt, F., Neubauer, Y., Overmann, M., Wilmes, B., Zobel, N., 2008. Direct liquefaction of
biomass. Chem. Eng. Technol. 31 (5), 667 677.
Search WWH ::




Custom Search