Biodiesel production direct from high acid value oil with a novel magnetic carbonaceous acid

Applied Energy

Volumn 155, Issue , 2015, Pages 637-647

  Zhang, Fan ^a,b   Fang, Zhen ^a   Wang, Yi Tong ^a,b  

^a KEY LABORATORY OF TROPICAL FOREST ECOLOGY   (China)

^b UNIVERSITY OF CHINESE ACADEMY OF SCIENCES   (China)

Author keywords

Biodiesel; High acid value; Hydrothermal; Magnetic carbonaceous acid; Sulfonation

Indexed keywords

BIODIESEL; CATALYST DEACTIVATION; CATALYSTS; CHLORINE COMPOUNDS; FUNCTIONAL GROUPS; SULFONATION;

ACID VALUE; BIODIESEL PRODUCTION; CRYSTALLINE PHASIS; ELEMENTAL COMPOSITIONS; FACTOR OPTIMIZATION; HYDROTHERMAL; HYDROTHERMAL PRECIPITATION; MAGNETIC CATALYSTS;

MAGNETISM;

BIOFUEL; CATALYST; CHEMICAL COMPOSITION; CHLORIDE; ESTER; FUNCTIONAL GROUP; GLUCOSE; MAGNETIZATION; OIL PRODUCTION; PRECIPITATION (CHEMISTRY); PYROLYSIS; RECYCLING; SULFONATE; TECHNOLOGICAL CHANGE; TEMPERATURE EFFECT; VEGETABLE OIL;

JATROPHA;

EID: 84934755322     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2015.06.044     Document Type: Article

References (44)

1. Jacobson M.Z. Review of solutions to global warming, air pollution, and energy security. Energy Environ Sci 2009, 2:148-173.
2. Sathre R. Comparing the heat of combustion of fossil fuels to the heat accumulated by their lifecycle greenhouse gases. Fuel 2014, 115:674-677.
3. Lois E. Definition of biodiesel. Fuel 2007, 86:1212-1213.
4. Lin L., Zhou C.S., Saritporn V., Shen X.Q., Dong M.D. Opportunities and challenges for biodiesel fuel. Appl Energy 2011, 88:1020-1031.
5. Tang Y., Meng M., Zhang J., Lu Y. Efficient preparation ofbiodieselfrom rapeseed oil over modified CaO. Appl Energy 2011, 88:2735-2739.
6. 3/honeycomb ceramic catalyst. Appl Energy 2015, 146:196-201.
7. Long Y.D., Fang Z., Su T.C., Yang Q. Co-production of biodiesel and hydrogen from rapeseed and Jatropha oils with sodium silicate and Ni catalysts. Appl Energy 2014, 113:1819-1825.
8. Deng X., Fang Z., Liu Y.H. Ultrasonic transesterification of Jatropha curcas L. oil to biodiesel by a two-step process. Energy Convers Manage 2010, 51:2802-2809.
9. Shu Q., Gao J., Nawaz Z., Liao Y., Wang D., Wang J. Synthesis of biodiesel from waste vegetable oil with large amounts of free fatty acids using a carbon-based solid acid catalyst. Appl Energy 2010, 87:2589-2596.
10. Fu J., Chen L., Lv P., Yang L., Yuan Z. Free fatty acids esterification for biodiesel production using self-synthesized macroporous cation exchange resin as solid acid catalyst. Fuel 2015, 154:1-8.
11. Talebian-Kiakalaieh A., Amin N.A.S., Zarei A., Noshadi I. Transesterification of waste cooking oil by heteropoly acid (HPA) catalyst: optimization and kinetic model. Appl Energy 2013, 102:283-292.
12. Kiss A.A., Dimian A.C., Rothenberg G. Solid acid catalysts for biodiesel production - towards sustainable energy. Adv Synth Catal 2006, 348:75-81.
13. Furuta S., Matsuhashi H., Arata K. Catalytic action of sulfated tin oxide for etherification and esterification in comparison with sulfated zirconia. Appl Catal 2004, 269:187-191.
14. Furuta S., Matsuhashi H., Arata K. Biodiesel fuel production with solid superacid catalysis in fixed bed reactor under atmospheric pressure. Catal Commun 2004, 5:721-723.
15. Ezebor F., Khairuddean M., Abdullah A.Z., Boey P.L. Esterification of oily-FFA and transesterification of high FFA waste oils using novel palm trunk and bagasse-derived catalysts. Energy Convers Manage 2014, 88:1143-1150.
16. Kulkarni M.G., Gopinath R., Meher L.C., Dalai A.K. Solid acid catalyzed biodiesel production by simultaneous esterification and transesterification. Green Chem 2006, 45:2901-2913.
17. Huang C.C., Chen H.M., Chen C.H., Huang J.C. Effect of surface oxides on hydrogen storage of activated carbon. Sep Purif Technol 2010, 70:291-295.
18. Díaz J.A., Akhavan H., Romero A., Garcia-Minguillan A.M., Romero R., Giroir-Fendler A., et al. Cobalt and iron supported on carbon nanofibers as catalysts for Fischer-Tropsch synthesis. Fuel Process Technol 2014, 128:417-424.
19. Santos A., Yustos P., Rodriguez S., Garcia-Ochoa F. Wet oxidation of phenol, cresols and nitrophenols catalyzed by activated carbon in acid and basic media. Appl Catal B - Environ 2006, 65:269-281.
20. Ji J., Zhang G., Chen H., Wang S., Zhang G., Zhang F., et al. Sulfonated graphene as water-tolerant solid acid catalyst. Chem Sci 2011, 2:484-487.
21. Kanbur Y., Küçükyavuz Z. Synthesis and characterization of surface modified fullerene. Fuller Nanotu Car N 2012, 2:119-126.
22. Peng F., Zhang L., Wang H., Lv P., Yu H. Sulfonated carbon nanotubes as a strong protonic acid catalyst. Carbon 2005, 43:2405-2408.
23. Pua F.L., Fang Z., Zakaria S., Chia C.H., Guo F. Direct production of biodiesel from high-acid value Jatropha oil with solid acid catalyst derived from lignin. Biotechnol Biofuels 2011, 4:56-64.
24. 3H nanoparticle catalyst for hydrolysis of cellulose. Cellulose 2013, 20:127-134.
25. Hu L., Tang X., Wu Z., Lin L., Xu J., Xu N., et al. Magnetic lignin-derived carbonaceous catalyst for the dehydration of fructose into 5-hydroxymethylfurfural in dimethylsulfoxide. Chem Eng J 2015, 263:299-308.
26. Liu Z., Fu X., Tang S., Cheng Y., Zhu L., Xing L., et al. Sulfonated magnetic carbon nanotube arrays as effective solid acid catalysts for the hydrolyses of polysaccharides in crop stalks. Catal Commun 2014, 56:1-4.
27. 4/C catalyst and ultrasound. Fuel 2015, 150. 377-7.
28. Lemmon EW, Huber ML, McLinden MO. NIST reference fluid thermodynamic and transport properties-REFPROP; 2002.
29. 5-based catalyst. Energy 2014, 68:584-591.
30. Nakajima K., Hara M. Environmentally benign production of chemicals and energy using a carbon-based strong solid acid. J Am Ceram Soc 2007, 90:3725-3734.
31. Liu X.R. Catalyst characterization and evaluation. Handbook of Industrial Catalyst 2004, 187-189. Chemical Industry Press, Beijing, [in Chinese]. Z.T. Huang (Ed.).
32. Pereira M.C., Coelho F.S., Nascentes C.C., Fabris J.D., Araújo M.H., Sapag K., et al. Use of activated carbon as a reactive support to produce highly active-regenerable Fe-based reduction system for environmental remediation. Chemosphere 2010, 81:7-12.
33. Fei Y., Brosh E. Experimental study and thermodynamic calculations of phase relations in the Fe-C system at high pressure. Earth Planet Sci Lett 2014, 408:155-162.
34. Dawodu F.A., Ayodele O., Xin J., Zhang S., Yan D. Effective conversion of non-edible oil with high free fatty acid into biodiesel by sulphonated carbon catalyst. Appl Energy 2014, 114:819-826.
35. Wang L., Dong X., Jiang H., Li G., Zhang M. Preparation of a novel carbon-based solid acid from cassava stillage residue and its use for the esterification of free fatty acids in waste cooking oil. Bioresour Technol 2014, 158:392-395.
36. 3C ultrasmall particles. Environ Sci Technol 2008, 42:2451-2456.
37. 3H sites. Carbon 2014, 74:333-345.
38. Hara M., Yoshida T., Takagaki A., Takata T., Kondo J.N., Hayashi S., et al. A carbon material as a strong protonic acid. Angew Chem Int Ed 2004, 43:2955-2958.
39. Shu Q., Nawaz Z., Gao J., Liao Y., Zhang Q., Wang D., et al. Synthesis of biodiesel from a model waste oil feedstock using a carbon-based solid acid catalyst: reaction and separation. Bioresour Technol 2010, 101:5374-5384.
40. Shu Q., Zhang Qiang, Xu G., Nawaz Z., Wang D., Wang J. Synthesis of biodiesel from cottonseed oil and methanol using a carbon-based solid acid catalyst. Fuel Process Technol 2009, 90:1002-1008.
41. ASTM D6751-07b. Standard Specification for Biodiesel Fuel Blend Stock (B100) for Middle Distillate Fuels, ASTM International, West Conshohocken, PA; 2007 http://www.astm.org.
42. Zhang Y., Dube M.A., McLean D.D., Kates M. Biodiesel production from waste cooking oil: 1. Process design and technological assessment. Bioresour Technol 2003, 89:1-15.
43. Zhang Y., Dube M.A., McLean D.D., Kates M. Biodiesel production from waste cooking oil: 2. Economic assessment and sensitivity analysis. Bioresour Technol 2003, 90:229-240.
44. Oguma M., Lee Y.J., Goto S. An overview of biodiesel in Asian countries and the harmonization of quality standards. Int J Automot Technol 2012, 13:33-41.