Advanced search
Publication Cover
International Journal of Green Energy Volume 13, 2016 - Issue 4
Submit an article Journal homepage
481
Views
14
CrossRef citations to date
0
Altmetric
Original Articles

Co-pyrolysis of paper waste and mustard press cake in a semi-batch pyrolyzer—optimization and bio-oil characterization

Aparna SarkarChemical Engineering Department, Jadavpur University, Kolkata, IndiaView further author information
&
Ranjana ChowdhuryChemical Engineering Department, Jadavpur University, Kolkata, IndiaCorrespondence[email protected]
View further author information
Pages 373-382 | Published online: 27 Oct 2014

References

  • Abnisa, F., W. M. A. W. Daud, and J. N. Sahu. 2011. Optimization and characterization studies on bio-oil production from palm shell by pyrolysis using response surface technology. Biomass and Bioenergy 35:3604–16.
  • Antony, S., Dr. R. Kenedy, and Dr. B. C. Pillai. 2009. Flash pyrolysis of jatropha oil cake in fluidised bed reactor. eNREE 6:753–57.
  • Bandhyopadhyay, S., R. Chowdhury, and G. K. Biswas. 1999. Thermal deactivation studies of coconut shell pyrolysis. The Canadian Journal of Chemical Engineering 77:1028–36.
  • Barisci, S., and M. S. Oncel. 2014. The disposal of combed cotton wastes by pyrolysis. International Journal of Green Energy 11:255–66.
  • Beis, H., O. Onay, and O. M. Koçkar. 2002. Fixed-bed pyrolysis of safflower seed: Influence of pyrolysis parameters on product yields and compositions. Renewable Energy 26:21–32.
  • Bhuiyan, M. N. A., K. Murakami, and M. Ota. 2008. On thermal stability and chemical kinetics of waste newspaper by thermogravimetric and pyrolysis analysis. Journal of Environment and Engineering 3:1–12.
  • Branca, C., P. Giudicianni, and C. Di. Blasi. 2003. GC/MS characterization of liquids generated from low-temperature pyrolysis of wood. Industrial & Engineering Chemistry Research 42:3190–202.
  • Chang, C. D., and A. J. Silvestri. 1977. The conversion of methanol and other O-compounds to hydrocarbons over zeolites catalysts. Journal of Catalysis 47:249–59.
  • Chang, C. Y., C. H. Wu, J. Y. Hwang, J. P. Lin, W. F. Yang, S. M. Shih, L. W. Chen, and F. W. Chang. 1996. Journal Environmental Engineering 122:299–305.
  • Chowdhury, R., and A. Sarkar. 2012. Reaction kinetics and product distribution of slow pyrolysis of Indian textile wastes. International Journal of Chemical Reactor Engineering 10:1–23.
  • David, C., S. Salvador, J. L. Dirion, and M. Quintard. 2003. Determination of a reaction scheme for cardboard thermal degradation using thermal gravimetric analysis. Journal of Analytical and Applied Pyrolysis 67:307–23.
  • Dominguez, A., J. A. Menendez, M. Inguanzo, and J. J. Pis. 2005. Investigation into the characteristics of oil produced from microwave pyrolysis of sewage sludge. Fuel Processing Technology 86:1007–20.
  • Fabbri, D., G. Chiavari, S. Prati, I. Vassura, and M. Vangelista. 2002. Gas chromatography/mass spectrometric of pyrolysis/silylation products of glucose and cellulose. Italy: John Wiley & Sons ltd.
  • French, R., and S. Czernik. 2010. Catalytic pyrolysis of biomass for biofuels production. Fuel Processing Technology 91:25–32.
  • Fukuda, S. 2014. Pyrolysis investigation for bio-oil production from various biomass feedstocks in Thailand. International Journal of Green Energy 12:215–24.
  • Giannakopoulou, K., M. Lukas, A. Vasiliev, C. Brunner, and H. Schnitzer. 2010a. Low pressure catalytic co-conversion of biogenic waste (rapeseed cake) and vegetable oil. Bioresource Technology 101:3209–19.
  • Giannakopoulou, K., M. Lukas, A. Vasiliev, C. Brunner, and H. Schnitzer. 2010b. Conversion of rapeseed cake into bio-fuel in a batch reactor: Effect of catalytic vapor upgrading. Microporous and Mesoporous Materials 128:126–35.
  • Gungora, A., S. Onenc, S. Ucar, and J. Yanik. 2012. Comparison between the “one-step” and “two-step” catalytic pyrolysis of pine bark. Journal of Analytical and Applied Pyrolysis 97:39–48.
  • Hasan, F. G. 2002. The production and evaluation of bio-oils from the pyrolysis of sunflower-oil cake. Biomass and Bioenergy 23:307–14.
  • Jin, L., L. Wang, L. Su, and Q. Cao. 2012. Characteristics of gases from co-pyrolysis of sawdust and tires. International Journal of Green Energy 9:719–30.
  • Karagoz, S., T. Bhaskar, A. Muto, Y. Sakata, and Md. A. Uddin. 2004. Low-temperature hydrothermal treatment of biomass: Effect of reaction parameters on products and boiling point distributions. Energy Fuels 18:234–41.
  • Li, G., Y. Zhou, F. Ji, Y. Liu, B. Adhikari, L. Tian, Z. Ma, and R. Dong. 2013. Yield and characteristics of pyrolysis products obtained from Schizochytrium limacinum under different temperature regimes. Energies 6:3339–52.
  • Loulou, T., S. Salvador, and J. L. Dirion. 2003. Determination of reaction parameters for cardboard thermal degradation using experimental data. Institution of Chemical Engineers 81:1265–70.
  • Meier, D., A. Oasmaa, and G. V. C. Peacocke. 1997. Properties of fast pyrolysis liquids: Status of test methods. In Advances in thermochemical biomass conversion, ed. A. V. Bridgwater, and D. G. B. Boocock, London: Blackie: Academic & Professional, pp. 391–408.
  • Mulligan, C. J., L. Strezov, and V. Strezov. 2010. Thermal decomposition of wheat straw and Mallee residue under pyrolysis condition. Energy Fuel 24:46–52.
  • NEERI (National Environmental Engineering Research Institute) 2005. Comprehensive characterization of municipal solid waste at Calcutta. India: NEERI.
  • Ozimen, D., and F. Karaosmanoglee. 2004. Production and characterization of bio-oil and bio-char from rapeseed cake. Renewable Energy 29:779–87.
  • Park, H. J., H. S. Heo, J. H. Yim, J. K. Jeon, Y. S. Ko, and S. S. Kim. 2010. Catalytic pyrolysis of Japanese larch using spent HZSM-5. Korean Journal of Chemical Engineering 27:73–5.
  • PUA, F. L., S. Zakaria, C. H. Chia, S. P. Fan, T. R. A. Potthast, and F. Liebner. 2013. Solvolytic liquefaction of oil palm empty fruit bunch (EFB) fibres: Analysis of product fractions using FTIR and pyrolysis-GCMS. Sains Malaysiana 42:793–99.
  • Putun, A. E., B. B. Uzun, and E. Apaydin. 2005. Pyrolysis of olive residue under different conditions. Fuel Processing Technology 87:25–32.
  • Putun, E., B. B. Uzun, and A. E. Putun. 2006. Fixed-bed catalytic pyrolysis of cotton-seed cake: Effects of pyrolysis temperature, natural zeolite content and sweeping gas flow rate. Bioresource Technology 97:701–10.
  • Putun, E., A. Esin, and P. Ersan. 2002. Bio-oil production from pyrolysis and steam pyrolysis of soybean-cake: Product yields and composition. Energy 27:703–13.
  • Raja, S., S. Antony, D. S. Robinson, B. C. Pillai, L. Robert, and C. Lindon. 2011. Parametric studies on Pyrolysis of pungam oil cake in electrically heated fluidized bed reactor. Research Journal of Chemical Sciences 1:70–80.
  • Roy, R., P. Bhattachariya, and R. Chowdhury. 2004. Simulation and modeling of vegetable market wastes pyrolysis under progressive deactivation conditions. The Canadian Journal of Chemical Engineering 82:566–79.
  • Shadangi, K. P. and K. Mohanty. 2014. Thermal and catalytic pyrolysis of Karanja seed to produce liquid fuel. Fuel 115:434–42.
  • Shadangi, K. P. and R. K. Singh. 2012. Thermolysis of polanga seed cake to bio-oil using semi batch reactor. Fuel 97:450–6.
  • Shafizadeh, F., and P. S. Chin. 1977. In Thermal deterioration of wood, ed. F. Shafizadeh and P. S. Chin, Wood Technology A. C. S Symposium, pp. 57–81.
  • Shafizadeh, F., R. H. Furneaux, T. G. Cochram, J. P. Scholl, and Y. Sakai. 1979. Production of levaglucosan and glucose from pyrolysis of cellulosic materials. Journal of Applied Polymer Science 23:3525–39.
  • Simoneit, B. R. T., W. F. Rogge, Q. Lang, and R. Jaec. 2000. Molecular characterization of smoke from camp®re burning of pine wood (Pinus elliottii). Chemosphere: Global Change Science 2:107–22.
  • Singh, R. K., and K. P. Shadangi. 2011. Liquid fuel from castor seeds by pyrolysis. Fuel 90:2538–44.
  • Sorum, L., M. G. Gronli, and J. E. Hustad. 2001. Pyrolysis characteristics and kinetics of municipal solid wastes. Fuel 80:1217–27.
  • Sreejith, C. C., P. Arun, and C. Muraleedharan. 2013. Thermochemical analysis of biomass gasification by Gibbs free energy minimization model—Part: I (optimization of pressure and temperature). International Journal of Green Energy 10:231–56.
  • Ucar, S., and A. R. Ozkan. 2008. Characterisation of products from the pyrolysis of rapeseed oil cake. Bioresource Technology 99:8771–6.
  • Volli, V., and R. K. Singh. 2012. Production of bio-oil from de-oiled cakes by thermal pyrolysis. Fuel 96:579–85.
  • Wang, S., Q. Liu, K. Wang, X. Guo, Z. Luo, K. Cen, and T. Fransson. 2010. Study on catalytic pyrolysis of manchurian ash for production of bio-oil. International Journal of Green Energy 7:300–9.
  • Weisz, P. B., W. O. Hagg, and P. G. Rodewald. 1979. Catalytic production of high grade fuel (gasoline) from biomass compounds by shape-selective catalysis. Science 206:57–8.
  • Wu, C. H., C. Y. Chang, and C. H. Tseng. 2002. Pyrolysis products of uncoated printing and writing paper of MSW. Fuel 81:719–25.
  • Wu, C. H., C. Y. Chang, C. H. Tseng, and J. P. Lin. 2003. Pyrolysis product distribution of waste newspaper in MSW. Journal of analytical and applied Pyrolysis 67:41–53.
  • Yang, Y. B., A. N. Phan, C. Ryu, V. Sharifi, and J. Swithenbank. 2007. Mathematical modelling of slow pyrolysis of segregated solid wastes in a packed-bed pyrolyser. Fuel 86:169–80.
  • Yildiz, G., M. Pronk, M. Djokic, K. M. V. Geemc, F. Ronssea, R. V. Durenb, and W. Prinsa. 2013. Validation of a new set-up for continuous catalytic fast pyrolysis of biomass coupled with vapour phase upgrading. Journal of Analytical and Applied Pyrolysis 103:343–51.
  • Zhang, Q., T. Wang, C. Wu, L. Ma, and Y. Xu. 2010. Fractioned preparation of bio-oil by biomass vacuum pyrolysis. International Journal of Green Energy 7:263–72.
  • Zhou, L., H. Yang, H. Wu, M. Wang, and D. Cheng. 2013. Catalytic pyrolysis of rice husk by mixing with zinc oxide: Characterization of bio-oil and its rheological behaviour. Fuel Processing Technology 106:385–91.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Supercharge Your Next Research Paper: Research and write your next paper with Jenni AI.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.