Variables influyentes en el secado discontinuo del carbón asistido con microondas

Authors

DOI:

https://doi.org/10.15665/rp.v10i2.231

Keywords:

Carbón, Microondas, Secado, Humedad

Abstract

En este estudio se evalúa la influencia del tamaño de partícula, el tipo de carbón, el tiempo de operación y la
energía microondas suministrada como variables influyentes en el proceso de secado del carbón mineral. Posteriormente,
se compara el secado con microondas con el secado térmico del carbón en estufa convencional. Los
resultados evidencian que con el secado en horno microonda se remueve hasta el 50% de la humedad contenida
en el carbón en el 10% del tiempo requerido por la técnica convencional. Se encontró que el proceso microondas
no afecta las propiedades de Índice de Hard Grove, poder calorífico y contenido de ceniza del carbón bajo las
condiciones empleadas en esta investigación.

References

Bélanger, J. M., Jocelyn Paré, J.R., Poon, O., Fairbridge,

C., Ng, S., Mutyala. S., Hawkins, R., Remarks on Various

Applications of Microwave Energy, J. Microw. Power Electromagn.

Energy, 42(4), 24-44, 2008.

Mutyala, S., Fairbridge, C., Jocelyn Paré, J.R., Bélanger,

J.M., Ng, S., Hawkins, R., Microwave applications to oil

sands and petroleum: A review, Fuel Process. Technol, 91(2),

-135, 2010.

Lester, E., and Kingman, S., The effect of microwave

pre-heating on five different coals, Fuel 83,1941–1947, 2004.

Seehra, M.S., Kalra, A., Manivannan, A., Dewatering

of fine coal slurries by selective heating with microwaves,

Fuel, 86(5-6), 829–834, 2007.

Wilson, J.W., and Ding, Y., Ultra fine coal single-stage

dewatering and briquetting process, Society for Mining, Metallurgy

and Exploration Transactions, 298, 1921-1924, 1994.

Yang, J., Wang, X.H., Parekh, B.K., Improved techniques

for dewatering of fine clean coal, Mineral processing:

Recent Advances and future trends, 694-699, 1998.

Church, R.H., Webb, W.E., Salsman, J.B., Dielectric properties

of low-loss minerals; U.S. Bureau of Mines, Report

of Investigations. Report 9, 194, 1-13, 1988.

Beary, E.S., Comparison of microwave drying and conventional

drying techniques for reference materials, Anal.

Chem. 60, 742-746, 1988.

Metaxas, A.C., and Meredith, R.J., Industrial Microwave

Heating. Peter Peregrinus Ltd., London, UK. 1983.

Perkin, R.M., The heat and mass transfer characteristics

of boiling point drying using radio frequency and microwave

electromagnetic fields, Intl. J. of heat & mass transfer,

, 687-695. 1980.

Marland, S., Han, B., Merchant, A., Rowson, N. The

effect of microwave radiation on coal grindability, Fuel, 79,

-1288, 2000.

Menéndez, J.A., Arenillas, A., Fidalgo, B., Fernández,

Y., Zubizarreta, L., Calvo, E.G., Bermúdez, J.M., Microwave

heating processes involving carbon materials,

Fuel Process. Technol, 91, 1-8, 2010.

Méndez, U.O., Kharissova, O.V., Rodríguez, M.,

Synthesis and morphology of nanostructures via microwave

heating, Reviews on Advances Materials Science, 5,

-402, 2003.

Kharissova, O.V., Vertically aligned carbon nanotubes

fabricated by microwaves. Reviews on Advanced Materials

Science, 7, 50-54, 2004.

Fidalgo, B., Fernández, Y., Zubizarreta, L., Arenillas, A.,

Dominguez, A., Pis, J.J., Menéndez, J.A., Growth of nanofilaments

on carbon based materials from microwave-assisted

decomposition of CH4. Appl. Surf. Sci., 254, 3553-3557, 2008.

Harris, A.T., Desphpande, S., Kefeng, X., Synthesis of

graphitic carbon particle chains at low temperature under

microwave irradiation, Mater. Lett., 63, 1390-1392, 2009.

Liu, Z., Guo, B., Hong, L, Lim, T.H., Microwave heated

polyol synthesis of carbon-supported PtSn nanoparticles

for methanol electrooxidation, Electrochem. Commun.,

, 83-90, 2006.

Zubizarreta, L., Arenillas, A., Menéndez, J.A., Pis,

J.J., Pirard, J.P., Job, N., Microwave drying as an effective

method to obtain porous carbon xerogels. J. Non-Cryst. Solids.,

, 4024-4026, 2008.

Lee, H.I., Kim, J.H., Joo, S.H., Chang, H., Seung, D.,

Joo, O.S., Suh, D.J., Ahn, W.S., Pak, C., Kim, J.M., Ultrafast

production of ordered mesoporous carbons via microwave

irradiation, Carbon, 45,2851-2854, 2007.

Li, W., Peng, J., Zhng, L., Yang, K., Xia, H., Zhang, S.

et al., Preparation of activated carbon from coconut shell

chars in pilot-scale microwave heating equipment at 60

kW, Waste Manage, 29,756-760, 2009.

Yuen, F.K., Hameed, B.H., Recent developments in

the preparation and regeneration of activated carbons by

microwaves,

Adv. Colloid Interface Sci., 149, 19-27, 2009.

Menéndez, J.A., Menéndez, E.M., Iglesias, M.J., García,

A., Pis, J.J., Modification of the surface chemistry of active

carbons by means of microwave-induced treatments,

Carbon,

, 1115-1121, 1999.

Ania, C.O., Parra, J.B., Menéndez, J.A., Pis, J.J., Microwave-

assisted regeneration of activated carbons loaded

with pharmaceuticals, Water Res., 41, 3299-3306, 2007.

Cherbanski, R., Molga, E., Intensification of desorption

processes by use of microwaves – An overview of

possible applications and industrial perspectives, Chem.

Eng. Process., 48, 48-58, 2009.

Bradshaw, S.M., Van Wyk, E.J., De Swardt, J.B., Microwave

heating principles and the application to the regeneration

of granular activated carbon, J. S. Afr. Inst. Min.

Metall., 98, 201-210, 1998.

Uslu, T., Atalay, Ü., Microwave heating of coal for enhanced

magnetic removal of pyrite, Fuel Process. Technol.,

, 21-29, 2004.

Tahmasebi, A., et al., “Experimental study on microwave

drying of Chinese and Indonesian low-rank

coals,” Fuel Process. Technol., 92, 1821-1829, 2011.

Treybal. Operaciones de Transferencia de Masa.

Mc.Graw-Hill, 2a. Edición. México (1989).

Downloads

Issue

Vol. 10 No. 2 (2012)

Section

Articles

License

The authors to publish in this journal agree to the following conditions:

  1. The authors transfer the copyright and give the the journal first publication right of the work registered with Creative Commons Attribution License, which allows third parties to use the published work on the condition of always mentioning the authorship and first publication in this journal.
  2. The authors may perform other independent and additional contractual arrangements for the non-exclusive distribution of the version of the article published in this issue (E.g., Inclusion in an institutional repository or publication in a book), it must be indicated clearly that the work was first published in this journal.
  3. It allows and encourages the authors to publish their work online (eg institutional or personal pages) before and during the review and publication process. It can lead to productive exchanges and greater and faster dissemination of the published work (see The Effect of Open Access)

Instructions to fill out Certificate of Originality and Copyright Assignment

  1. Click here and get the forms of Certificate of Originality and Copyright Assignment  .
  2. In each field to fill out, click and complete the corresponding information.
  1. Once the fields are filled out, at the end of the form copy your scanned signature or digital signature. Please adjust the size of the signature on the form.
  2. Finally, you can save them as pdf files and send them through the OJS platform as an attachment.