Upgrading pyrolysis bio-oil to biofuel over bifunctional Co-Zn/HZSM-5 catalyst in supercritical methanol

Energy Conversion and Management

Volumn 147, Issue , 2017, Pages 19-28

  Cheng, Shouyun ^a   Wei, Lin ^a   Julson, James ^a   Muthukumarappan, Kasiviswanathan ^a   Kharel, Parashu Ram ^a  

^a SOUTH DAKOTA STATE UNIVERSITY   (United States)

Author keywords

Biofuel; Co Zn HZSM 5; Hydrocarbons; Hydrodeoxygenation; Pyrolysis; Supercritical methanol

Indexed keywords

CALORIFIC VALUE; CARBON DIOXIDE; CARBOXYLATION; CATALYSTS; EFFLUENT TREATMENT; ENERGY EFFICIENCY; HYDROCARBONS; METHANOL; PRODUCED WATER; PYROLYSIS; SUPERCRITICAL FLUIDS; ZINC;

CATALYST EFFICIENCY; CRYSTALLINE STRUCTURE; HETEROGENEOUS CATALYST; HIGHER HEATING VALUE; HYDRODEOXYGENATION; PHYSICOCHEMICAL PROPERTY; SUPERCRITICAL METHANOL; ZN/HZSM-5;

BIOFUELS;

EID: 85019651783     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2017.05.044     Document Type: Article

References (86)

1. Omajali, J.B., Hart, A., Walker, M., Wood, J., Macaskie, L.E., In-situ catalytic upgrading of heavy oil using dispersed bionanoparticles supported on gram-positive and gram-negative bacteria. Appl Catal, B 203 (2017), 807–819.
2. Hu, X., Gunawan, R., Mourant, D., Hasan, M.M., Wu, L., Song, Y., et al. Upgrading of bio-oil via acid-catalyzed reactions in alcohols—a mini review. Fuel Process Technol 155 (2017), 2–19.
3. Luo, Y., Guda, V.K., Steele, P.H., Mitchell, B., Yu, F., Hydrodeoxygenation of oxidized distilled bio-oil for the production of gasoline fuel type. Energy Convers Manage 112 (2016), 319–327.
4. Ravikumar C, Kumar PS, Subhashni S, Tejaswini P, Varshini V. Microwave assisted fast pyrolysis of corn cob, corn stover, saw dust and rice straw: Experimental investigation on bio-oil yield and high heating values. Sustain Mater Technol; 2016.
5. Cordero-Lanzac, T., Palos, R., Arandes, J.M., Castaño, P., Rodríguez-Mirasol, J., Cordero, T., et al. Stability of an acid activated carbon based bifunctional catalyst for the raw bio-oil hydrodeoxygenation. Appl Catal, B 203 (2017), 389–399.
6. Kadarwati, S., Hu, X., Gunawan, R., Westerhof, R., Gholizadeh, M., Hasan, M.M., et al. Coke formation during the hydrotreatment of bio-oil using NiMo and CoMo catalysts. Fuel Process Technol 155 (2017), 261–268.
7. Li, Y., Zhang, C., Liu, Y., Tang, S., Chen, G., Zhang, R., et al. Coke formation on the surface of Ni/HZSM-5 and Ni-Cu/HZSM-5 catalysts during bio-oil hydrodeoxygenation. Fuel 189 (2017), 23–31.
8. Li, X., Chen, G., Liu, C., Ma, W., Yan, B., Zhang, J., Hydrodeoxygenation of lignin-derived bio-oil using molecular sieves supported metal catalysts: a critical review. Renew Sustain Energy Rev, 2016.
9. Yang, T., Jie, Y., Li, B., Kai, X., Yan, Z., Li, R., Catalytic hydrodeoxygenation of crude bio-oil over an unsupported bimetallic dispersed catalyst in supercritical ethanol. Fuel Process Technol 148 (2016), 19–27.
10. Ahmadi, S., Yuan, Z., Rohani, S., Xu, C.C., Effects of nano-structured CoMo catalysts on hydrodeoxygenation of fast pyrolysis oil in supercritical ethanol. Catal Today 269 (2016), 182–194.
11. Horáček, J., Kubička, D., Bio-oil hydrotreating over conventional CoMo & NiMo catalysts: the role of reaction conditions and additives. Fuel, 2016.
12. Yan, N., Yuan, Y., Dykeman, R., Kou, Y., Dyson, P.J., Hydrodeoxygenation of lignin-derived phenols into alkanes by using nanoparticle catalysts combined with brønsted acidic ionic liquids. Angew Chem Int Ed 49 (2010), 5549–5553.
13. Arun, N., Sharma, R.V., Dalai, A.K., Green diesel synthesis by hydrodeoxygenation of bio-based feedstocks: strategies for catalyst design and development. Renew Sustain Energy Rev 48 (2015), 240–255.
14. Bui, V.N., Laurenti, D., Afanasiev, P., Geantet, C., Hydrodeoxygenation of guaiacol with CoMo catalysts. Part I: promoting effect of cobalt on HDO selectivity and activity. Appl Catal, B 101 (2011), 239–245.
15. Cheng, S., Wei, L., Zhao, X., Huang, Y., Raynie, D., Qiu, C., et al. Directly catalytic upgrading bio-oil vapor produced by prairie cordgrass pyrolysis over Ni/HZSM-5 using a two stage reactor. AIMS Energy 3 (2015), 227–240.
16. Zhao, X., Wei, L., Cheng, S., Julson, J., Optimization of catalytic cracking process for upgrading camelina oil to hydrocarbon biofuel. Ind Crops Prod 77 (2015), 516–526.
17. Zhao, C., Lercher, J.A., Upgrading pyrolysis oil over Ni/HZSM-5 by cascade reactions. Angew Chem 124 (2012), 6037–6042.
18. Peng, J., Chen, P., Lou, H., Zheng, X., Catalytic upgrading of bio-oil by HZSM-5 in sub-and super-critical ethanol. Bioresour Technol 100 (2009), 3415–3418.
19. Sankaranarayanan, T.M., Berenguer, A., Ochoa-Hernández, C., Moreno, I., Jana, P., Coronado, J.M., et al. Hydrodeoxygenation of anisole as bio-oil model compound over supported Ni and Co catalysts: effect of metal and support properties. Catal Today 243 (2015), 163–172.
20. Loricera, C., Castaño, P., Infantes-Molina, A., Hita, I., Gutierrez, A., Arandes, J., et al. Designing supported ZnNi catalysts for the removal of oxygen from bio-liquids and aromatics from diesel. Green Chem 14 (2012), 2759–2770.
21. Tang, Z., Lu, Q., Zhang, Y., Zhu, X., Guo, Q., One step bio-oil upgrading through hydrotreatment, esterification, and cracking. Ind Eng Chem Res 48 (2009), 6923–6929.
22. Oh, S., Kim, U.-J., Choi, I.-G., Choi, J.W., Solvent effects on improvement of fuel properties during hydrodeoxygenation process of bio-oil in the presence of Pt/C. Energy 113 (2016), 116–123.
23. Dang, Q., Luo, Z., Zhang, J., Wang, J., Chen, W., Yang, Y., Experimental study on bio-oil upgrading over catalyst in supercritical ethanol. Fuel 103 (2013), 683–692.
24. Li, W., Pan, C., Sheng, L., Liu, Z., Chen, P., Lou, H., et al. Upgrading of high-boiling fraction of bio-oil in supercritical methanol. Bioresour Technol 102 (2011), 9223–9228.
25. Jacobson, K., Maheria, K.C., Dalai, A.K., Bio-oil valorization: a review. Renew Sustain Energy Rev 23 (2013), 91–106.
26. Li, W., Pan, C., Zhang, Q., Liu, Z., Peng, J., Chen, P., et al. Upgrading of low-boiling fraction of bio-oil in supercritical methanol and reaction network. Bioresour Technol 102 (2011), 4884–4889.
27. Park, H.J., Park, Y.-K., Kim, J.S., Influence of reaction conditions and the char separation system on the production of bio-oil from radiata pine sawdust by fast pyrolysis. Fuel Process Technol 89 (2008), 797–802.
28. Chen, T., Deng, C., Liu, R., Effect of selective condensation on the characterization of bio-oil from pine sawdust fast pyrolysis using a fluidized-bed reactor. Energy Fuels 24 (2010), 6616–6623.
29. Chen, W., Luo, Z., Yu, C., Li, G., Yang, Y., Zhang, H., Upgrading of bio-oil in supercritical ethanol: catalysts screening, solvent recovery and catalyst stability study. J Supercrit Fluids 95 (2014), 387–393.
30. Yang, Y., Gilbert, A., Xu, C.C., Production of bio-crude from forestry waste by hydro-liquefaction in sub-/super-critical methanol. AlChE J 55 (2009), 807–819.
31. Cheng S, Wei L, Zhao X, Kadis E, Julson J. Conversion of prairie cordgrass to hydrocarbon biofuel over Co-Mo/HZSM-5 using a two-stage reactor system. Energy Technol; 2016.
32. Cheng, S., Wei, L., Julson, J., Muthukumarappan, K., Kharel, P.R., Cao, Y., et al. Hydrodeoxygenation upgrading of pine sawdust bio-oil using zinc metal with zero valency. J Taiwan Inst Chem Eng 74 (2017), 146–153.
33. Zhao, X., Wei, L., Julson, J., Qiao, Q., Dubey, A., Anderson, G., Catalytic cracking of non-edible sunflower oil over ZSM-5 for hydrocarbon bio-jet fuel. New Biotechnol 32 (2015), 300–312.
34. Zhao, X., Wei, L., Julson, J., Gu, Z., Cao, Y., Catalytic cracking of inedible camelina oils to hydrocarbon fuels over bifunctional Zn/ZSM-5 catalysts. Korean J Chem Eng 32 (2015), 1528–1541.
35. Cheng, S., Wei, L., Zhao, X., Kadis, E., Cao, Y., Julson, J., et al. Hydrodeoxygenation of prairie cordgrass bio-oil over Ni based activated carbon synergistic catalysts combined with different metals. New Biotechnol 33 (2016), 440–448.
36. Huang, Y., Wei, L., Zhao, X., Cheng, S., Julson, J., Cao, Y., et al. Upgrading pine sawdust pyrolysis oil to green biofuels by HDO over zinc-assisted Pd/C catalyst. Energy Convers Manage 115 (2016), 8–16.
37. Thangalazhy-Gopakumar, S., Adhikari, S., Ravindran, H., Gupta, R.B., Fasina, O., Tu, M., et al. Physiochemical properties of bio-oil produced at various temperatures from pine wood using an auger reactor. Bioresour Technol 101 (2010), 8389–8395.
38. Lu, Q., Zhang, Z.-F., Dong, C.-Q., Zhu, X.-F., Catalytic upgrading of biomass fast pyrolysis vapors with nano metal oxides: an analytical Py-GC/MS study. Energies 3 (2010), 1805–1820.
39. Cui, H.-Y., Wang, J.-H., Zhuo, S.-P., Li, Z.-H., Wang, L.-H., Yi, W.-M., Upgrading bio-oil by esterification under supercritical CO2 conditions. J Fuel Chem Technol 38 (2010), 673–678.
40. Bakar, M.S.A., Titiloye, J.O., Catalytic pyrolysis of rice husk for bio-oil production. J Anal Appl Pyrol 103 (2013), 362–368.
41. Bertero, M., Sedran, U., Upgrading of bio-oils over equilibrium FCC catalysts. Contribution from alcohols, phenols and aromatic ethers. Catal Today 212 (2013), 10–15.
42. Huang, Y., Wei, L., Julson, J., Gao, Y., Zhao, X., Converting pine sawdust to advanced biofuel over HZSM-5 using a two-stage catalytic pyrolysis reactor. J Anal Appl Pyrol 111 (2015), 148–155.
43. Cheng, S., Wei, L., Zhao, X., Development of a bifunctional Ni/HZSM-5 catalyst for converting prairie cordgrass to hydrocarbon biofuel. Energy Sources, Part A 38 (2016), 2433–2437.
44. Wei L, Gao Y, Qu W, Zhao X, Cheng S. Torrefaction of raw and blended Corn Stover, switchgrass, and prairie Grass; 2016.
45. Zhao, X., Wei, L., Cheng, S., Julson, J., Anderson, G., Muthukumarappan, K., et al. Development of hydrocarbon biofuel from sunflower seed and sunflower meat oils over ZSM-5. J Renew Sustain Energy, 8, 2016, 013109.
46. Khoshbin, R., Haghighi, M., Direct syngas to DME as a clean fuel: the beneficial use of ultrasound for the preparation of CuO–ZnO–Al2O3/HZSM-5 nanocatalyst. Chem Eng Res Des 91 (2013), 1111–1122.
47. Liu, N., Chen, P., Li, Y., Zhang, R., N2O direct dissociation over MgxCeyCo1− x− yCo2O4 composite spinel metal oxide. Catalysts, 7, 2017, 10.
48. Cheng, X., Zhao, H., Huo, L., Gao, S., Zhao, J., ZnO nanoparticulate thin film: preparation, characterization and gas-sensing property. Sens Actuat B: Chem 102 (2004), 248–252.
49. Cheng, S., Wei, L., Zhao, X., Kadis, E., Julson, J., Conversion of prairie cordgrass to hydrocarbon biofuel over Co-Mo/HZSM-5 using a two-stage reactor system. Energy Technol 4 (2016), 706–713.
50. Wei, Y., Lei, H., Zhu, L., Zhang, X., Liu, Y., Yadavalli, G., et al. Hydrocarbon produced from upgrading rich phenolic compound bio-oil with low catalyst coking. Fuel 178 (2016), 77–84.
51. Wang, S., Yin, Q., Guo, J., Ru, B., Zhu, L., Improved Fischer-Tropsch synthesis for gasoline over Ru, Ni promoted Co/HZSM-5 catalysts. Fuel 108 (2013), 597–603.
52. Zhao, Y., Chen, S., Sun, B., Su, D., Huang, X., Liu, H., et al. Graphene-Co3O4 nanocomposite as electrocatalyst with high performance for oxygen evolution reaction. Scient Rep, 5, 2015, 7629.
53. Triwahyono, S., Jalil, A.A., Mukti, R.R., Musthofa, M., Razali, N.a.M., Aziz, M.a.A., Hydrogen spillover behavior of Zn/HZSM-5 showing catalytically active protonic acid sites in the isomerization of n-pentane. Appl Catal, A 407 (2011), 91–99.
54. Önal, Y., Schimpf, S., Claus, P., Structure sensitivity and kinetics of D-glucose oxidation to D-gluconic acid over carbon-supported gold catalysts. J Catal 223 (2004), 122–133.
55. Thangalazhy-Gopakumar, S., Adhikari, S., Gupta, R.B., Catalytic pyrolysis of biomass over H+ ZSM-5 under hydrogen pressure. Energy Fuels 26 (2012), 5300–5306.
56. Huynh, T.M., Armbruster, U., Pohl, M.M., Schneider, M., Radnik, J., Hoang, D.L., et al. Hydrodeoxygenation of phenol as a model compound for bio-oil on non-noble bimetallic nickel-based catalysts. ChemCatChem 6 (2014), 1940–1951.
57. Wang, L., Lei, H., Bu, Q., Ren, S., Wei, Y., Zhu, L., et al. Aromatic hydrocarbons production from ex situ catalysis of pyrolysis vapor over Zinc modified ZSM-5 in a packed-bed catalysis coupled with microwave pyrolysis reactor. Fuel 129 (2014), 78–85.
58. Gayubo, A.G., Aguayo, A.T., Atutxa, A., Aguado, R., Bilbao, J., Transformation of oxygenate components of biomass pyrolysis oil on a HZSM-5 zeolite. I. Alcohols and phenols. Ind Eng Chem Res 43 (2004), 2610–2618.
59. Zhu, X., Lobban, L.L., Mallinson, R.G., Resasco, D.E., Bifunctional transalkylation and hydrodeoxygenation of anisole over a Pt/HBeta catalyst. J Catal 281 (2011), 21–29.
60. Park, H.J., Heo, H.S., Jeon, J.-K., Kim, J., Ryoo, R., Jeong, K.-E., et al. Highly valuable chemicals production from catalytic upgrading of radiata pine sawdust-derived pyrolytic vapors over mesoporous MFI zeolites. Appl Catal, B 95 (2010), 365–373.
61. Huynh, T.M., Armbruster, U., Kreyenschulte, C.R., Nguyen, L.H., Phan, B.M., Nguyen, D.A., et al. Understanding the performance and stability of supported Ni-Co-based catalysts in phenol HDO. Catalysts, 6, 2016, 176.
62. Seyedeyn-Azad, F., Salehi, E., Abedi, J., Harding, T., Biomass to hydrogen via catalytic steam reforming of bio-oil over Ni-supported alumina catalysts. Fuel Process Technol 92 (2011), 563–569.
63. Elliott, D.C., Hart, T.R., Neuenschwander, G.G., Rotness, L.J., Olarte, M.V., Zacher, A.H., et al. Catalytic hydroprocessing of fast pyrolysis bio-oil from pine sawdust. Energy Fuels 26 (2012), 3891–3896.
64. Oasmaa, A., Elliott, D.C., Korhonen, J., Acidity of biomass fast pyrolysis bio-oils. Energy Fuels 24 (2010), 6548–6554.
65. Martínez-Palou, R., De Lourdes Mosqueira, M., Zapata-Rendón, B., Mar-Juárez, E., Bernal-Huicochea, C., De La Cruz, Clavel.-López J., et al. Transportation of heavy and extra-heavy crude oil by pipeline: a review. J Pet Sci Eng 75 (2011), 274–282.
66. Oasmaa, A., Kuoppala, E., Fast pyrolysis of forestry residue. 3. Storage stability of liquid fuel. Energy Fuels 17 (2003), 1075–1084.
67. Ben, H., Ragauskas, A.J., Pyrolysis of kraft lignin with additives. Energy Fuels 25 (2011), 4662–4668.
68. Huang, X., Korányi, T.I., Boot, M.D., Hensen, E.J., Catalytic depolymerization of lignin in supercritical ethanol. ChemSusChem 7 (2014), 2276–2288.
69. Wang, S., Guo, Z., Cai, Q., Guo, L., Catalytic conversion of carboxylic acids in bio-oil for liquid hydrocarbons production. Biomass Bioenergy 45 (2012), 138–143.
70. Xu, X., Zhang, C., Liu, Y., Zhai, Y., Zhang, R., Two-step catalytic hydrodeoxygenation of fast pyrolysis oil to hydrocarbon liquid fuels. Chemosphere 93 (2013), 652–660.
71. Zhang, X., Zhang, Q., Wang, T., Li, B., Xu, Y., Ma, L., Efficient upgrading process for production of low quality fuel from bio-oil. Fuel 179 (2016), 312–321.
72. Zhang, X., Chen, L., Kong, W., Wang, T., Zhang, Q., Long, J., et al. Upgrading of bio-oil to boiler fuel by catalytic hydrotreatment and esterification in an efficient process. Energy 84 (2015), 83–90.
73. Cheng, S., Wei, L., Zhao, X., Julson, J., Application, deactivation, and regeneration of heterogeneous catalysts in bio-oil upgrading. Catalysts, 6, 2016, 195.
74. Nava, R., Pawelec, B., Castaño, P., Álvarez-Galván, M., Loricera, C., Fierro, J., Upgrading of bio-liquids on different mesoporous silica-supported CoMo catalysts. Appl Catal, B 92 (2009), 154–167.
75. Mortensen, P.M., Grunwaldt, J.-D., Jensen, P.A., Knudsen, K., Jensen, A.D., A review of catalytic upgrading of bio-oil to engine fuels. Appl Catal, A 407 (2011), 1–19.
76. Ren, Y., Zhang, F., Hua, W., Yue, Y., Gao, Z., ZnO supported on high silica HZSM-5 as new catalysts for dehydrogenation of propane to propene in the presence of CO2. Catal Today 148 (2009), 316–322.
77. Pidko, E.A., Van Santen, R.A., Activation of light alkanes over zinc species stabilized in ZSM-5 zeolite: a comprehensive DFT study. J Phys Chem C 111 (2007), 2643–2655.
78. Wang, S., Cai, Q., Chen, J., Zhang, L., Zhu, L., Luo, Z., Co-cracking of bio-oil model compound mixtures and ethanol over different metal oxide-modified HZSM-5 catalysts. Fuel 160 (2015), 534–543.
79. Cheng, Y.T., Jae, J., Shi, J., Fan, W., Huber, G.W., Production of renewable aromatic compounds by catalytic fast pyrolysis of lignocellulosic biomass with bifunctional Ga/ZSM-5 catalysts. Angew Chem 124 (2012), 1416–1419.
80. Adjaye, J.D., Katikaneni, S.P., Bakhshi, N.N., Catalytic conversion of a biofuel to hydrocarbons: effect of mixtures of HZSM-5 and silica-alumina catalysts on product distribution. Fuel Process Technol 48 (1996), 115–143.
81. Shabtai, J., Nag, N., Massoth, F., Catalytic functionalities of supported sulfides: IV. CO hydrogenolysis selectivity as a function of promoter type. J Catal 104 (1987), 413–423.
82. Romero, Y., Richard, F., Brunet, S., Hydrodeoxygenation of 2-ethylphenol as a model compound of bio-crude over sulfided Mo-based catalysts: promoting effect and reaction mechanism. Appl Catal, B 98 (2010), 213–223.
83. Qian, Y., Liang, S., Wang, T., Wang, Z., Xie, W., Xu, X., Enhancement of pyrolysis gasoline hydrogenation over Zn-and Mo-promoted Ni/γ-Al2O3 catalysts. Catal Commun 12 (2011), 851–853.
84. Xu, Y., Wang, T., Ma, L., Zhang, Q., Liang, W., Upgrading of the liquid fuel from fast pyrolysis of biomass over MoNi/γ-Al2O3 catalysts. Appl Energy 87 (2010), 2886–2891.
85. Ardiyanti, A., Khromova, S., Venderbosch, R., Yakovlev, V., Heeres, H., Catalytic hydrotreatment of fast-pyrolysis oil using non-sulfided bimetallic Ni-Cu catalysts on a δ-Al2O3 support. Appl Catal, B 117 (2012), 105–117.
86. Xu, X., Zhang, C., Zhai, Y., Liu, Y., Zhang, R., Tang, X., Upgrading of bio-oil using supercritical 1-butanol over a Ru/C heterogeneous catalyst: role of the solvent. Energy Fuels 28 (2014), 4611–4621.