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http://dx.doi.org/10.7464/ksct.2018.24.3.233

Effect of the Recycling of Non-condensable Gases on the Process of Fast Pyrolysis for Palm Wastes  

Oh, Changho (Daekyung Esco)
Lee, Jang Hoon (Department of Environmental Engineering, Hoseo University)
Publication Information
Clean Technology / v.24, no.3, 2018 , pp. 233-238 More about this Journal
Abstract
Bio-oil is produced by the fast quenching of hot vapor produced by fast pyrolysis of biomass in an inert atmosphere. Nitrogen is used as carrier gas to control the concentration of oxygen less than 3%. The consumption of nitrogen should be increased with increasing process size, and leading to increasing of facility and operating costs due to nitrogen charge. The effects of the recycling of non-condensable gases on the fast pyrolysis, bio-oil yield and quality, and nitrogen consumption have systematically investigated to see the possibility of these results in fast pyrolysis process of palm residue.
Keywords
Fast pyrolysis; Non-condensable gases; Recycling process; Bio-oil; Fluidized bed reactor;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
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1 Upton Jr., G. B., and Snyder, B. F., "Funding Renewable Energy: An Analysis of Renewable Portfolio Standards," Energ. Econ., 66, 205-216 (2017).   DOI
2 Brigljevic, B., Woo, H. C., and Liu, J., "Process Design and Simulation of Fast Pyrolysis of Brown Seaweed," Clean Technol., 23(4), 435-440 (2017).   DOI
3 http://www.motie.go.kr/motie/ne/rt/press/bbs/bbsView.do?bbs_seq_n=79293&bbs_cd_n=16.
4 Bridgwater, A. V., and Peacocke, G. V. C., "Fast Pyrolysis Processes for Biomass," Renew. Sust. Energ. Rev., 4, 1-73 (2000).   DOI
5 Bridgwater, A. V., Toft, A. J., and Brammer, J. G., "A Techno-Economic Comparison of Power Production by Biomass Fast Pyrolysis with Gasification and Combustion," Renew. Sust. Energ. Rev., 6, 181-248 (2002).   DOI
6 Kim, S.-S., Shenoy, A., and Agblevor, F. A., "Thermogravimetric and Kinetics Study of Pinyon Pine in the Various Gases," Bioresour. Technol., 156, 297-302 (2014).   DOI
7 Mante, O., Agblevor, F. A., Oyama, S. T., and McClung, R., "The Influence of Recycling Non-Condensable Gases in the Fractional Catalytic Pyrolysis of Biomass," Bioresour. Technol., 111, 482-490 (2012).   DOI
8 Park, Y-H., Kim, J., Kim, S.-S., and Park, Y.-K., "Pyrolysis Characteristics and Kinetics of Oak Trees Using Thermogravimetric Analyzer and Micro-Tubing Reactor," Bioresour. Technol., 100, 400-405 (2009).   DOI
9 Kim, S.-S., Ly, H. V., Kim, J., Choi, J. H., and Woo, H. C., "Thermogravimetric Characteristics and Pyrolysis Kinetics of Alga Sagarssum sp. Biomass," Bioresour. Technol., 139, 242-248 (2013).   DOI
10 Kim, S.-S., Kim, J., Park, Y.-H., and Park, Y.-K., "Pyrolysis Kinetics and Decomposition Characteristics of Pine Trees," Bioresour. Technol., 101, 9797-9802 (2010).   DOI
11 Choi, J. H., Kim, S.-S., Ly, H. V., Kim, J., and Woo, H. C., "Effect of Water-Washing Saccharina Japonica on Fast Pyrolysis in a Bubbling Fluidized-Bed Reactor," Biomass Bioenerg., 98, 112-123 (2017).   DOI
12 Varhegyi, G., Bobaly, B., Jakab, E., and Chen, H., "Thermogravimetric Study of Biomass Pyrolysis Kinetics. A Distributed Activation Energy Model with Prediction Test," Energ. Fuel., 25, 24-32 (2011).   DOI
13 Yang, H., Yan, R., Chen, H., Lee, D. H., and Zheng, C., "Characteristics of Hemicellulose, Cellulose and Lignin Pyrolysis," Fuel, 86, 1781-1788 (2007).   DOI
14 ASTM D7544-12 (2017), "Standard Specification for Pyrolysis Liquid Biofuel".