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/lp/de-gruyter/low-temperature-pyrolysis-of-oily-sludge-roles-of-fe-al-pillared-thqXhUvY92
- Publisher
- de Gruyter
- Copyright
- © 2017 Archives of Environmental Protection
- ISSN
- 2083-4810
- eISSN
- 2083-4810
- DOI
- 10.1515/aep-2017-0027
- Publisher site
- See Article on Publisher Site
Abstract
ReferencesAlbright, L.F., Crynes, B.L. & Corcora, W.H. (1983). Pyrolysis: Theory and Industrial Practice, Academic Press New York Ny. (https://www.osti.gov/scitech/biblio/6355324(02.06.2017)).Almon, W. & Johns, W. (1977). Petroleum forming reactions: the mechanism and rate of clay catalyzed fatty acid decarboxylation, Enadimsa: Madrid, pp. 157–172.Baik, O.D. & Mittal, G.S. (2002). Heat transfer coefficients during deep-fat frying of a tofu disc, Transactions of the ASAE, 45, pp. 1493–1538.Beis, H., Onay, O. & Kockar, O.M. (2002). Fixed-bed pyrolysis of safflower seed: influence of pyrolysis parameters on product yields and compositions, Renew Energy, 26(1), pp. 21–32.Berend, I., Cases, J.M., Francois, M., Uriot, J.P. & Michot, L. (1995). Mechanism of adsorption and desorption of water vapor by homoionic montmorillonites; 2, The Li (super+), Na (super+), K (super+), Rb (super+) and Cs (super+)-exchanged forms, Clays and Clay Minerals, 43, pp. 324–336.Bridgwater, A., Meier, D. & Radlein, D. (1999). An overview of fast pyrolysis of biomass, Organic Geochemistry, 30, pp. 1479–1493.Chen, K., Wang, G.H., Li, W.B., Wan, D., Hu, Q., Lu, L.L., Wei, X.B. & Cheng, Z.Z. (2015). Synthesis of magnetically modified Fe-Al pillared bentonite and heterogeneous Fenton-like degradation of Orange II, Journal of Wuhan University of Technology-Mater. Sci. Ed., 30(2), pp. 302–306.Chiaramonti, D., Oasmaa, A. & Solantausta, Y. (2007). Power generation using fast pyrolysis liquids from biomass, Renewable & Sustainable Energy Reviews, 11, pp. 1056–1086.Ciajolo, A. & Barbella, R. (1984). Pyrolysis and oxidation of heavy fuel oils and their fractions in a thermogravimetric apparatus, Fuel, 63, pp. 657–661.Czernik, S. & Bridgwater, A. V. (2004). Overview of applications of biomass fast pyrolysis oil, Fuel, 18, pp. 590–598.Da Silva, L.J., Alves, F.C. & Francfia, F.P. (2012). A review of the technological solutions for the treatment of oily sludges from petroleum refineries, Waste Management & Research, 30 (10), pp. 1–15.European Commission DG Environment-B/2, Disposal and recycling routes for sewage sludge scientific and technical sub-component report, 23/10/2001.Fakhru’l-Razi, A., Pendashteh, A., Abdullah, L.C., Biak, D.R.A., Madaeni, S.S. & Abidin, Z.Z. (2009). Review of technologies for oil and gas produced water treatment, Journal of Hazardous Materials, 170, pp. 530–551.Ge, Z.G., Li, D.Y. & Pinnavaia, T.J. (1994). Preparation of alumina-pillared montmorillonites with high thermal stability, regular microporosity and Lewis/Brönsted acidity, Microporous Materials, 3, pp. 165–175.Kandiyoti, R., Herod, A.A. & Bartle, K.D. (2006). Solid fuels and heavy hydrocarbon liquids: Thermal characterization and analysis, Elsevier: London, ISBN: 978008044864.Kök, M.V. & Karacan, O. (1998). Pyrolysis analysis and kinetics of crude oils, Journal of Thermal Analysis and Calorimetry, 52, pp. 781–788.Li, C.T., Lee, W.J., Mi, H.H. & Su, C.C. (1995). PAH emission from the incineration of waste oily sludge and PE plastic mixtures, Science of the Total Environment, 170, pp. 171–183.Liu, J.G., Jiang, X.M., Zhou, L.S. & Han, X.X. (2009). Pyrolysis treatment of oil sludge and model-free kinetics analysis, Journal of Hazardous Materials, 161, pp. 1208–1215.Maksimova, N.I. & Krivoruchko, O.P. (1999). Study of thermocatalytic decomposition of polyethylene and polyvinyl alcohol in the presence of an unsteady-state Fe-containing catalyst, Chemical Engineering Science, 54 (20), pp. 4351–4357.Mater, L., Sperb, R.M., Madureira, L., Rosin, A. & Correa, A. (2006). Proposal of a sequential treatment methodology for the safe reuse of oil sludge-contaminated soil, Journal of Hazardous Materials, 136, pp. 967–971.Pánek, P. & Kostura, B. (2014). Pyrolysis of oil sludge with calcium-containing additive, Journal of Analytical & Applied Pyrolysis, 108, pp. 274–283.Saha, B., Maiti, A.K. & Ghoshal, A.K. (2006). Model-free method for isothermal and non-isothermal decomposition kinetics analysis of PET sample, Thermochimica Acta, 444, pp. 46–52.Shen, L. & Zhang, D.K. (2002). An experimental study of oil recovery from sewage sludge by low-temperature pyrolysis in a fluidised-bed, Fuel, 82, pp. 465–472.Shen, L. & Zhang, D.K. (2005). Low-temperature pyrolysis of sewage sludge and putrescible garbage for fuel oil production, Fuel, 84, pp. 809–815.Shie, J.L., Chang, C.Y., Lin, J.P., Wu, C.H. & Lee, D.J. (2000). Resources recovery of oil sludge by pyrolysis: kinetics study, Journal of Chemical Technology & Biotechnology, 75, pp. 443–450.Shie, J.L., Chang, C.Y. & Lin, J.P. (2000). Major Products obtained from the pyrolysis of oil sludge, Energy & Fuels, 14, pp. 1176–1183Shie, J.L., Lin, J.P., Chang, C.Y., Lee, D.J. & Wu, C.H. (2003). Pyrolysis of oil sludge with additives of sodium and potassium compounds, Resources Conservation & Recycling, 39, pp. 51–64.Shie, J.L., Chang, C.Y., Lee, D.J. & W u, C.H. (2002). Use of inexpensive additives in pyrolysis of oil sludge, Energy & Fuels, 16, pp. 102–108.Shie, J.L., Lin, J.P., Chang, C.Y., Lee, D.J. & Wu, C.H. (2002). Use of calcium compounds as additives for oil sludge pyrolysis, Journal of the Chinese Institute of Environmental Engerineering (Taiwan), 12(4), pp. 363–371.Shie, J.L., Lin, J.P., Chang, C.Y., Shih, S.M., Lee, D.J. & Wu, C.H. (2004). Pyrolysis of oil sludge with additives of catalytic wastes, Journal of Analytical & Applied Pyrolysis, 71, pp. 695–707.Sing, K.S.W., Everett, D.H., Haul, R.A.W., Moscou, L. & Pierotti, R.A. (1958). Reporting physisorption data for gas/solid systems with special reference to the determination of surface area and porosity, Pure & Applied Chemistry, 57, pp. 603–619.Tamer, K., Jale, Y.K., Mithat, Y. & Henning, B. (2006). Characterisation of products from pyrolysis of waste sludges, Fuel, 85, pp. 1498–1508.Tyagi, B., Chudasama, C.D. & Jasra, R.V. (2006). Characterization of surface acidity of an acid montmorillonite activated with hydrothermal, ultrasonic and microwave techniques, Applied Clay Science, 31, pp. 16–28.Ubani O., Atagana, H.I., Thantsha, M.S. & Rasheed, A. (2016). Identification and characterisation of oil sludge degrading bacteria isolated from compost, Archives of Environmental Protection, 42(2), pp. 67–77.Wang, Z.Q., Guo, Q.J. & Liu, X. (2007). Low temperature pyrolysis characteristics of oil sludge under various heating conditions, Energy Fuels, 21, pp. 957–962.Wang, Z.Q., Guo, Q.G., Liu, X.M. & Cao, C.Q. (2007). Low Temperature pyrolysis characteristics of oil sludge under various heating conditions, Energy & Fuels, 21, pp. 957–962.Wei, Z.B, Michael Moldowan, J., Dahl, J., Goldstein, T.P. & Jarvie, D.M. (2006). The catalytic effects of minerals on the formation of diamondoids from kerogen macromolecules, Organic Geochemistry, 37(11), pp. 1421–1436.Werle, S. (2012). Possibility of NOx emission reduction from combustion process using sewage sludge gasification gas as an additional fuel, Archives of Environmental Protection, 38(3), pp. 81–89.Wiśniewski, D., Gołaszewski, J. & Białowiec, A. (2015). The pyrolysis and gasification of digestate from agricultural biogas plant, Archives of Environmental Protection, 41(3), pp. 70–75.Yan, P., Lu, M., Yang, Q., Zhang, H.L., Zhang, Z.Z. & Chen, R. (2012). Oil recovery from refinery oily sludge using a rhamnolipid biosurfactant-producing Pseudomonas, Bioresource Technology, 116, pp. 24–28.
Journal
Archives of Environmental Protection – de Gruyter
Published: Sep 1, 2017