Assessment of steam gasification kinetics of the char from lignocellulosic biomass in a conical spouted bed reactor

Energy

Volumn 107, Issue , 2016, Pages 493-501

  Lopez, Gartzen ^a   Alvarez, Jon ^a   Amutio, Maider ^a   Arregi, Aitor ^a   Bilbao, Javier ^a   Olazar, Martin ^a  

^a UNIVERSITY OF THE BASQUE COUNTRY UPV EHU   (Spain)

Author keywords

Biomass; Char; Kinetics; Spouted bed; Steam gasification

Indexed keywords

ACTIVATION ENERGY; BIOMASS; ENZYME KINETICS; KINETICS; PARTICLE SIZE; STEAM;

CHAR; CHAR GASIFICATION; CONICAL SPOUTED BED REACTOR; LIGNOCELLULOSIC BIOMASS; RANDOM PORE MODEL; SPOUTED BED; STEAM GASIFICATION; STEAM PARTIAL PRESSURE;

GASIFICATION;

ACTIVATION ENERGY; ASSESSMENT METHOD; BIOMASS; BIOREACTOR; CELLULOSE; CHARCOAL; EXPERIMENTAL STUDY; HOMOGENEITY; LIGNIN; PARTIAL PRESSURE; PARTICLE SIZE; PYROLYSIS; REACTION KINETICS; TEMPERATURE PROFILE;

EID: 84964863000     PISSN: 03605442     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.energy.2016.04.040     Document Type: Article

References (60)

1. Huber G.W., Iborra S., Corma A. Synthesis of transportation fuels from biomass: chemistry, catalysts, and engineering. Chem Rev 2006, 106:4044-4098.
2. Corma Canos A., Iborra S., Velty A. Chemical routes for the transformation of biomass into chemicals. Chem Rev 2007, 107:2411-2502.
3. Haarlemmer G., Boissonnet G., Peduzzi E., Setier P. Investment and production costs of synthetic fuels - a literature survey. Energy 2014, 66:667-676.
4. Heidenreich S., Foscolo P.U. New concepts in biomass gasification. Prog Energy Combust Sci 2015, 46:72-95.
5. Bhaduri S., Contino F., Jeanmart H., Breuer E. The effects of biomass syngas composition, moisture, tar loading and operating conditions on the combustion of a tar-tolerant HCCI (Homogeneous Charge Compression Ignition) engine. Energy 2015, 87:289-302.
6. Hernandez J.J., Ballesteros R., Aranda G. Characterisation of tars from biomass gasification: effect of the operating conditions. Energy 2013, 50:333-342.
7. Anis S., Zainal Z.A. Tar reduction in biomass producer gas via mechanical, catalytic and thermal methods: a review. Renew Sustain Energy Rev 2011, 15:2355-2377.
8. Shen Y., Yoshikawa K. Recent progresses in catalytic tar elimination during biomass gasification or pyrolysis - a review. Renew Sustain Energy Rev 2013, 21:371-392.
9. Berrueco C., Montané D., Matas Güell B., del Alamo G. Effect of temperature and dolomite on tar formation during gasification of torrefied biomass in a pressurized fluidized bed. Energy 2014, 66:849-859.
10. Chiang K.-Y., Lu C.-H., Lin M.-H., Chien K.-L. Reducing tar yield in gasification of paper-reject sludge by using a hot-gas cleaning system. Energy 2013, 50:47-53.
11. 2 gasification kinetics of olive residue. Biomass Bioenergy 2003, 24:151-161.
12. Ahmed I.I., Gupta A.K. Kinetics of woodchips char gasification with steam and carbon dioxide. Appl Energy 2011, 88:1613-1619.
13. Di Blasi C. Combustion and gasification rates of lignocellulosic chars. Prog Energy Combust Sci 2009, 35:121-140.
14. Kajita M., Kimura T., Norinaga K., Li C.-Z., Hayashi J.-I. Catalytic and noncatalytic mechanisms in steam gasification of char from the pyrolysis of biomass. Energy Fuels 2010, 24:108-116.
15. Duman G., Uddin M.A., Yanik J. The effect of char properties on gasification reactivity. Fuel Process Technol 2014, 118:75-81.
16. López-González D., Fernandez-Lopez M., Valverde J.L., Sanchez-Silva L. Gasification of lignocellulosic biomass char obtained from pyrolysis: kinetic and evolved gas analyses. Energy 2014, 71:456-467.
17. 2 gasification reactivity of biomass char: catalytic influence of alkali, alkaline earth and transition metal salts. Bioresour Technol 2013, 144:288-295.
18. Zhang Y., Ashizawa M., Kajitani S., Miura K. Proposal of a semi-empirical kinetic model to reconcile with gasification reactivity profiles of biomass chars. Fuel 2008, 87:475-481.
19. Umeki K., Moilanen A., Gómez-Barea A., Konttinen J. A model of biomass char gasification describing the change in catalytic activity of ash. Chem Eng J 2012, 207-208:616-624.
20. Nilsson S., Gómez-Barea A., Fuentes-Cano D., Campoy M. Gasification kinetics of char from olive tree pruning in fluidized bed. Fuel 2014, 125:192-199.
21. Bryan Woodruff R., Weimer A.W. A novel technique for measuring the kinetics of high-temperature gasification of biomass char with steam. Fuel 2013, 103:749-757.
22. Cetin E., Gupta R., Moghtaderi B. Effect of pyrolysis pressure and heating rate on radiata pine char structure and apparent gasification reactivity. Fuel 2005, 84:1328-1334.
23. Mermoud F., Salvador S., Van de Steene L., Golfier F. Influence of the pyrolysis heating rate on the steam gasification rate of large wood char particles. Fuel 2006, 85:1473-1482.
24. 2. Fuel 2013, 108:812-823.
25. Sircar I., Sane A., Wang W., Gore J.P. Experimental and modeling study of pinewood char gasification with CO 2. Fuel 2014, 119:38-46.
26. 2 gasification of torrefied and pyrolyzed chars. Energy 2014, 67:319-327.
27. 2 gasification kinetics of biomass char at medium to high temperatures. Appl Energy 2013, 109:220-228.
28. Alvarez J., Lopez G., Amutio M., Bilbao J., Olazar M. Kinetic study of carbon dioxide gasification of rice husk fast pyrolysis char. Energy Fuels 2015, 29:3198-3207.
29. 2 gasification of chars prepared from wood and forest residue: a kinetic study. Energy Fuels 2013, 27:6098-6107.
30. 2 gasification reactivity. Energy 2015, 88:703-710.
31. López-González D., Fernandez-Lopez M., Valverde J.L., Sanchez-Silva L. Comparison of the steam gasification performance of three species of microalgae by thermogravimetric-mass spectrometric analysis. Fuel 2014, 134:1-10.
32. 2 and steam gasification of a grapefruit skin char. Fuel 2002, 81:423-429.
33. 2 atmosphere and its kinetics since 1948: a brief review. Energy 2011, 36:12-40.
34. Seo D.K., Lee S.K., Kang M.W., Hwang J., Yu T. Gasification reactivity of biomass chars with CO2. Biomass Bioenergy 2010, 34:1946-1953.
35. Zeng X., Wang F., Wang Y., Li A., Yu J., Xu G. Characterization of char gasification in a micro fluidized bed reaction analyzer. Energy Fuels 2014, 28:1838-1845.
36. 2 at elevated temperatures with a modified random pore model. Energy Fuels 2003, 17:961-970.
37. Kramb J., Konttinen J., Gómez-Barea A., Moilanen A., Umeki K. Modeling biomass char gasification kinetics for improving prediction of carbon conversion in a fluidized bed gasifier. Fuel 2014, 132:107-115.
38. Gomez-Barea A., Leckner B. Modeling of biomass gasification in fluidized bed. Prog Energy Combust Sci 2010, 36:444-509.
39. Makibar J., Fernandez-Akarregi A.R., Alava I., Cueva F., Lopez G., Olazar M. Investigations on heat transfer and hydrodynamics under pyrolysis conditions of a pilot-plant draft tube conical spouted bed reactor. Chem Eng Process 2011, 50:790-798.
40. Gómez-Barea A., Ollero P., Leckner B. Mass transport effects during measurements of gas-solid reaction kinetics in a fluidised bed. Chem Eng Sci 2007, 62:1477-1493.
41. Erkiaga A., Lopez G., Amutio M., Bilbao J., Olazar M. Steam gasification of biomass in a conical spouted bed reactor with olivine and γ-alumina as primary catalysts. Fuel Process Technol 2013, 116:292-299.
42. Erkiaga A., Lopez G., Amutio M., Bilbao J., Olazar M. Influence of operating conditions on the steam gasification of biomass in a conical spouted bed reactor. Chem Eng J 2014, 237:259-267.
43. Erkiaga A., Lopez G., Amutio M., Bilbao J., Olazar M. Syngas from steam gasification of polyethylene in a conical spouted bed reactor. Fuel 2013, 109:461-469.
44. Lopez G., Erkiaga A., Amutio M., Bilbao J., Olazar M. Effect of polyethylene co-feeding in the steam gasification of biomass in a conical spouted bed reactor. Fuel 2015, 153:393-401.
45. Amutio M., Lopez G., Aguado R., Artetxe M., Bilbao J., Olazar M. Kinetic study of lignocellulosic biomass oxidative pyrolysis. Fuel 2012, 95:305-311.
46. Olazar M., San Jose M., Aguayo A., Arandes J., Bilbao J. Design factors of conical spouted beds and jet spouted beds. Ind Eng Chem Res 1993, 32:1245-1250.
47. Alvarez J., Amutio M., Lopez G., Barbarias I., Bilbao J., Olazar M. Sewage sludge valorization by flash pyrolysis in a conical spouted bed reactor. Chem Eng J 2015, 273:173-183.
48. Alvarez J., Lopez G., Amutio M., Bilbao J., Olazar M. Bio-oil production from rice husk fast pyrolysis in a conical spouted bed reactor. Fuel 2014, 128:162-169.
49. Artetxe M., Lopez G., Amutio M., Elordi G., Bilbao J., Olazar M. Cracking of high density polyethylene pyrolysis waxes on HZSM-5 catalysts of different acidity. Ind Eng Chem Res 2013, 52:10637-10645.
50. Artetxe M., Lopez G., Elordi G., Amutio M., Bilbao J., Olazar M. Production of light olefins from polyethylene in a two-step process: pyrolysis in a conical spouted bed and downstream high-temperature thermal cracking. Ind Eng Chem Res 2012, 51:13915-13923.
51. Lopez G., Olazar M., Aguado R., Elordi G., Amutio M., Artetxe M., et al. Vacuum pyrolysis of waste tires by continuously feeding into a conical spouted bed reactor. Ind Eng Chem Res 2010, 49:8990-8997.
52. Lopez G., Olazar M., Aguado R., Bilbao J. Continuous pyrolysis of waste tyres in a conical spouted bed reactor. Fuel 2010, 89:1946-1952.
53. 2 gasification of coconut-shell chars: carbonization temperature effects on char reactivity and porous properties of produced activated carbons. Eng J 2013, 1:13-27.
54. Bhatia S.K., Perlmutter D.D.A. Random pore model for fluid solid reactions: I. Isothermal, kinetic control. AIChE J 1980, 26:379-386.
55. 2 reactions. Chem Eng Sci 2011, 66:4499-4509.
56. 2. Fuel Process Technol 2015, 134:175-188.
57. Malekshahian M., De Visscher A., Hill J.M. A non-equimolar mass transfer model for carbon dioxide gasification studies by thermogravimetric analysis. Fuel Process Technol 2014, 124:1-10.
58. 2. Chem Eng Sci 2011, 66:36-41.
59. 2 gasification of torrefied wood: a kinetic study. Energy Fuels 2014, 28:7582-7590.
60. Xu C., Hu S., Xiang J., Zhang L., Sun L., Shuai C., et al. Interaction and kinetic analysis for coal and biomass co-gasification by TG-FTIR. Bioresour Technol 2014, 154:313-321.