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Review

Hydrogen via steam reforming of liquid biofeedstock

Gaurav Nahar Energy Research Institute, School of Process, Environmental & Materials Engineering, The University of Leeds, Leeds, LS2 9JT, UK. [email protected]
&
Valerie Dupont Energy Research Institute, School of Process, Environmental & Materials Engineering, The University of Leeds, Leeds, LS2 9JT, UK.
Pages 167-191 | Published online: 09 Apr 2014

References

  • Martin S, Wörner A. On-board reforming of biodiesel and bioethanol for high temperature PEM fuel cells: comparison of autothermal reforming and steam reforming. J. Power Sources196(6),3163–3171 (2011).
  • Jurado F, Valverde M, Cano A. Effect of a SOFC plant on distribution system stability. J. Power Sources129(2),170–179 (2004).
  • Rampe T, Heinzel A, Vogel B. Hydrogen generation from biogenic and fossil fuels by autothermal reforming. J. Power Sources86(1–2),536–541 (2000).
  • Ahmed S, Krumpelt M. Hydrogen from hydrocarbon fuels for fuel cells. Int. J. Hydrogen Energy26(4),291–301 (2001).
  • Specchia S, Tillemans FWA, Oosterkamp PFVD, Saracco G. Conceptual design and selection of a biodiesel fuel processor for a vehicle fuel cell auxiliary power unit. J. Power Sources145(2),683–690 (2005).
  • Sá S, Silva H, Brandão L, Sousa JM, Mendes A. Catalysts for methanol steam reforming – a review. Appl. Catal. B Environ.99(1–2),43–57 (2010).
  • Cheekatamarla PK, Finnerty CM. Reforming catalysts for hydrogen generation in fuel cell applications. J. Power Sources160(1),490–499 (2006).
  • Kamarudin SK, Achmad F, Daud WRW. Overview on the application of direct methanol fuel cell (DMFC) for portable electronic devices. Int. J. Hydrogen Energy34(16),6902–6916 (2009).
  • Holladay JD, Hu J, King DL, Wang Y. An overview of hydrogen production technologies. Catal. Today139(4),244–260 (2009).
  • Huang TJ, Wang SW. Hydrogen production via partial oxidation of methanol over copper-zinc catalysts. Appl. Catal.24(1–2),287–297 (1986).
  • Rostrup-Nielsen JR. Production of synthesis gas. Catal. Today18(4),305–324 (1993).
  • Pena MA, Gómez JP, Fierro JLG. New catalytic routes for syngas and hydrogen production. Appl. Catal. A Gen.144(1–2),7–57 (1996).
  • Wyman CE. Ethanol from lignocellulosic biomass: technology, economics, and opportunities. Bioresour. Technol.50(1),3–15 (1994).
  • Prasad S, Singh A, Joshi HC. Ethanol as an alternative fuel from agricultural, industrial and urban residues. Resour. Conserv. Recycling50(1),1–39 (2007).
  • Lynd LR, Cushman JH, Nichols RJ, Wyman CE. Fuel ethanol from cellulosic biomass. Science251(4999),1318–1323 (1991).
  • Wang W, Wang YQ. Thermodynamic analysis of steam reforming of ethanol for hydrogen generation. Int. J. Energy Res.32(15),1432–1443 (2008).
  • Díaz Alvarado F, Gracia F. Steam reforming of ethanol for hydrogen production: thermodynamic analysis including different carbon deposits representation. Chem. Eng. J.165(2),649–657 (2010).
  • Lima Da Silva A, Malfatti CDF, Müller IL. Thermodynamic analysis of ethanol steam reforming using Gibbs energy minimization method: a detailed study of the conditions of carbon deposition. Int. J. Hydrogen Energy34(10),4321–4330 (2009).
  • Bshish A, Yaakob Z, Narayanan B, Ramakrishnan R, Ebshish A. Steam-reforming of ethanol for hydrogen production. Chem. Papers65(3),251–266 (2011).
  • Ni M, Leung DYC, Leung MKH. A review on reforming bio-ethanol for hydrogen production. Int. J. Hydrogen Energy32(15),3238–3247 (2007).
  • Alberton AL, Souza MMVM, Schmal M. Carbon formation and its influence on ethanol steam reforming over Ni/Al2O3 catalysts. Catal. Today123(1–4),257–264 (2007).
  • Fatsikostas AN, Kondarides DI, Verykios XE. Production of hydrogen for fuel cells by reformation of biomass-derived ethanol. Catal. Today75(1–4),145–155 (2002).
  • Sun J, Qiu XP, Wu F, Zhu WT. H2 from steam reforming of ethanol at low temperature over Ni/Y2O3, Ni/La2O3 and Ni/Al2O3 catalysts for fuel-cell application. Int. J. Hydrogen Energy30(4),437–445 (2005).
  • Sánchez-Sánchez MC, Navarro RM, Fierro JLG. Ethanol steam reforming over Ni/La-Al2O3 catalysts: influence of lanthanum loading. Catal. Today129(3–4),336–345 (2007).
  • Sánchez-Sánchez MC, Navarro RM, Fierro JLG. Ethanol steam reforming over Ni/MxOy-Al2O3 (M=Ce, La, Zr and Mg) catalysts: influence of support on the hydrogen production. Int. J. Hydrogen Energy32(10–11),1462–1471.
  • He L, Berntsen H, Chen D. Approaching sustainable H2 production: sorption enhanced steam reforming of ethanol. J. Phys. Chem. A114(11),3834–3844 (2009).
  • Zhang B, Cai W, Li Y, Xu Y, Shen W. Hydrogen production by steam reforming of ethanol over an Ir/CeO2 catalyst: reaction mechanism and stability of the catalyst. Int. J. Hydrogen Energy33(16),4377–4386 (2008).
  • Zhang C, Li S, Li M, Wang S, Ma X, Gong J. Enhanced oxygen mobility and reactivity for ethanol steam reforming. AlChE J.58(2),516–525 (2011).
  • Zhou G, Barrio L, Agnoli S et al. High activity of Ce1−xNixO2−y for H2 production through ethanol steam reforming: tuning catalytic performance through metal–oxide interactions. Angew. Chem.122(50),9874–9878 (2010).
  • Fajardo H, Probst L, Carreño N, Garcia I, Valentini A. Hydrogen production from ethanol steam reforming over Ni/CeO2 nanocomposite catalysts. Catal. Lett.119(3),228–236 (2007).
  • Laosiripojana N, Assabumrungrat S. Catalytic steam reforming of ethanol over high surface area CeO2: the role of CeO2 as an internal pre-reforming catalyst. Appl. Catal. B. Environ.66(1–2),29–39 (2006).
  • Laosiripojana N, Assabumrungrat S. Methane steam reforming over Ni/Ce-ZrO2 catalyst: influences of Ce-ZrO2 support on reactivity, resistance toward carbon formation, and intrinsic reaction kinetics. Appl. Catal. A. Gen.290(1–2),200–211 (2005).
  • Laosiripojana N, Chadwick D, Assabumrungrat S. Effect of high surface area CeO2 and Ce-ZrO2 supports over Ni catalyst on CH4 reforming with H2O in the presence of O2, H2, and CO2 . Chem. Eng. J.138(1–3),264–273 (2008).
  • Aneggi E, Boaro M, Leitenburg CD, Dolcetti G, Trovarelli A. Insights into the redox properties of ceria-based oxides and their implications in catalysis. J. Alloys Comp.408–412,1096–1102 (2006).
  • Srinivas D, Satyanarayana CVV, Potdar HS, Ratnasamy P. Structural studies on NiO-CeO2-ZrO2 catalysts for steam reforming of ethanol. Appl. Catal. A. Gen.246(2),323–334 (2003).
  • Biswas P, Kunzru D. Steam reforming of ethanol for production of hydrogen over Ni/CeO2-ZrO2 catalyst: effect of support and metal loading. Int. J. Hydrogen Energy32(8),969–980 (2007).
  • Breen JP, Burch R, Coleman HM. Metal-catalysed steam reforming of ethanol in the production of hydrogen for fuel cell applications. Appl. Catal. B. Environ.39(1),65–74 (2002).
  • Dasari MA, Kiatsimkul PP, Sutterlin WR, Suppes GJ. Low-pressure hydrogenolysis of glycerol to propylene glycol. Appl. Catal. A. Gen.281(1–2),225–231 (2005).
  • Suppes GJ, Dasari MA, Doskocil EJ, Mankidy PJ, Goff MJ. Transesterification of soybean oil with zeolite and metal catalysts. Appl. Catal. A. Gen.257(2),213–223 (2004).
  • Tyson KS. Biodiesel R&D and potential. Montana Biodiesel Workshop, MT, USA, 8 October 2003.
  • Prakash. A Critical Review of Biodiesel as a Transportation Fuel in Canada. Environment Canada, Gatineau, Canada (1998).
  • Vaidya PD, Rodrigues AE. Glycerol reforming for hydrogen production: a review. Chem. Eng. Technol.32(10),1463–1469 (2009).
  • Adhikari S, Fernando S, Gwaltney SR et al. A thermodynamic analysis of hydrogen production by steam reforming of glycerol. Int. J. Hydrogen Energy32(14),2875–2880 (2007).
  • Chen H, Ding Y, Cong NT et al. A comparative study on hydrogen production from steam-glycerol reforming: thermodynamics and experimental. Renew. Energy36(2),779–788 (2011).
  • Cui Y, Galvita V, Rihko-Struckmann L, Lorenz H, Sundmacher K. Steam reforming of glycerol: the experimental activity of La1-xCexNiO3 catalyst in comparison to the thermodynamic reaction equilibrium. Appl. Catal. B Environ.90(1–2),29–37 (2009).
  • Authayanun S, Arpornwichanop A, Patcharavorachot Y, Wiyaratn W, Assabumrungrat S. Hydrogen production from glycerol steam reforming for low- and high-temperature PEMFCs. Int. J. Hydrogen Energy36(1),267–275 (2011).
  • Adhikari S, Fernando SD, To SDF, Bricka RM, Steele PH, Haryanto A. Conversion of glycerol to hydrogen via a steam reforming process over nickel catalysts. Energy Fuels22(2),1220–1226 (2008).
  • Adhikari S, Fernando S, Haryanto A. Production of hydrogen by steam reforming of glycerin over alumina-supported metal catalysts. Catal. Today129(3–4),355–364 (2007).
  • Buffoni IN, Pompeo F, Santori GF, Nichio NN. Nickel catalysts applied in steam reforming of glycerol for hydrogen production. Catal. Commun.10(13),1656–1660 (2009).
  • Zhang B, Tang X, Li Y, Xu Y, Shen W. Hydrogen production from steam reforming of ethanol and glycerol over ceria-supported metal catalysts. Int. J. Hydrogen Energy32(13),2367–2373 (2007).
  • Dou B, Dupont V, Rickett G et al. Hydrogen production by sorption-enhanced steam reforming of glycerol. Bioresour. Technol.100(14),3540–3547 (2009).
  • Dou B, Rickett GL, Dupont V et al. Steam reforming of crude glycerol with in situ CO2 sorption. Bioresour. Technol.101(7),2436–2442 (2010).
  • He L, Parra JMS, Blekkan EA, Chen D. Towards efficient hydrogen production from glycerol by sorption enhanced steam reforming. Energy Environ. Sci.3(8),1046–1056 (2010).
  • Iriondo A, Barrio VL, Cambra JF et al. Glycerol steam reforming over Ni catalysts supported on ceria and ceria-promoted alumina. Int. J. Hydrogen Energy35(20),11622–11633 (2010).
  • Dave CD, Pant KK. Renewable hydrogen generation by steam reforming of glycerol over zirconia promoted ceria supported catalyst. Renewable Energy36(11),3195–3202 (2011).
  • Li Y. Development of polyurethane foam and its potential within the biofuels market. Biofuels2(4),357–359 (2011).
  • Alasfour FN. Butanol – a single cylinder engine study: engine performance. Int. J. Energy Res.21(1),21–30 (1997).
  • Alasfour FN. Butanol – a single-cylinder engine study: availability analysis. Appl. Ther. Eng.17(6),537–549 (1997).
  • Gautam M, Martin D II, Carder D. Emissions characteristics of higher alcohol/gasoline blends. J. Power Energy214(2),165–182 (2000).
  • Gautam M, Martin D II. Combustion characteristics of higher-alcohol/gasoline blends. J. Power Energy214(5),497–511 (2000).
  • García V, Päkkilä J, Ojamo H, Muurinen E, Keiski RL. Challenges in biobutanol production: how to improve the efficiency? Renew. Sust. Energy Rev.15(2),964–980 (2011).
  • Hess G. Biobutanol. Chem. Eng. News84(26),9 (2006).
  • Nahar GA, Madhani SS. Thermodynamics of hydrogen production by the steam reforming of butanol: analysis of inorganic gases and light hydrocarbons. Int. J. Hydrogen Energy35(1),98–109 (2010).
  • Wang W, Cao Y. Hydrogen production via sorption enhanced steam reforming of butanol: thermodynamic analysis. Int. J. Hydrogen Energy36(4),2887–2895 (2011).
  • Lima Da Silva A, Müller IL. Hydrogen production by sorption enhanced steam reforming of oxygenated hydrocarbons (ethanol, glycerol, n-butanol and methanol): Thermodynamic modelling. Int. J. Hydrogen Energy36(3),2057–2075 (2011).
  • Bimbela F, Oliva M, Ruiz J, García L, Arauzo J. Catalytic steam reforming of model compounds of biomass pyrolysis liquids in fixed bed: acetol and n-butanol. J. Anal. Appl. Pyrolysis85(1–2),204–213 (2009).
  • Palmeri N, Chiodo V, Freni S, Frusteri F, Bart JCJ, Cavallaro S. Hydrogen from oxygenated solvents by steam reforming on Ni/Al2O3 catalyst. Int. J. Hydrogen Energy33(22),6627–6634 (2008).
  • Herguido J, Corella J, Gonzalez-Saiz J. Steam gasification of lignocellulosic residues in a fluidized bed at a small pilot scale. Effect of the type of feedstock. Industr. Eng. Chem. Res.31(5),1274–1282 (1992).
  • Chen D, He L. Towards an efficient hydrogen production from biomass: a review of processes and materials. Chem. Catal. Chem.3(3),490–511 (2011).
  • Bridgwater AV. Review of fast pyrolysis of biomass and product upgrading. Biomass Bioenergy doi:10.1016/j.biombioe.2011.01.048 (2012) (In Press).
  • Bridgwater AV. Principles and practice of biomass fast pyrolysis processes for liquids. J. Anal. Appl. Pyrolysis51(1–2),3–22 (1999).
  • Yaman S. Pyrolysis of biomass to produce fuels and chemical feedstocks. Energy Convers. Manage.45(5),651–671 (2004).
  • Gayubo AG, Aguayo AT, Atutxa A, Prieto R, Bilbao J. Deactivation of a HZSM-5 zeolite catalyst in the transformation of the aqueous fraction of biomass pyrolysis oil into hydrocarbons. Energy Fuels18(6),1640–1647 (2004).
  • Ayhan D. The influence of temperature on the yields of compounds existing in bio-oils obtained from biomass samples via pyrolysis. Fuel Process. Technol.88(6),591–597 (2007).
  • Abdullah N, Gerhauser H. Bio-oil derived from empty fruit bunches. Fuel87(12),2606–2613 (2008).
  • Kumar G, Panda AK, Singh RK. Optimization of process for the production of bio-oil from eucalyptus wood. J. Fuel Chem. Technol.38(2),162–167 (2010).
  • Strezov V, Evans TJ, Hayman C. Thermal conversion of elephant grass (Pennisetum purpureum Schum) to bio-gas, bio-oil and charcoal. Bioresour. Technol.99(17),8394–8399 (2008).
  • Bulushev DA, Ross JRH. Catalysis for conversion of biomass to fuels via pyrolysis and gasification: a review. Catal. Today171(1),1–13 (2011).
  • Hu X, Lu G. Comparative study of alumina-supported transition metal catalysts for hydrogen generation by steam reforming of acetic acid. Appl. Catal. B. Environ.99(1–2),289–297 (2010).
  • Thaicharoensutcharittham S, Meeyoo V, Kitiyanan B, Rangsunvigit P, Rirksomboon T. Hydrogen production by steam reforming of acetic acid over Ni-based catalysts. Catal. Today164(1),257–261 (2011).
  • An L, Dong C, Yang Y, Zhang J, He L. The influence of Ni loading on coke formation in steam reforming of acetic acid. Renew. Energy36(3),930–935 (2011).
  • Basagiannis AC, Verykios XE. Catalytic steam reforming of acetic acid for hydrogen production. Int. J. Hydrogen Energy32(15),3343–3355 (2007).
  • Vagia EC, Lemonidou AA. Investigations on the properties of ceria-zirconia-supported Ni and Rh catalysts and their performance in acetic acid steam reforming. J. Catal.269(2),388–396 (2010).
  • Vagia EC, Lemonidou AA. Thermodynamic analysis of hydrogen production via steam reforming of selected components of aqueous bio-oil fraction. Int. J. Hydrogen Energy32(2),212–223 (2007).
  • Aktaş S, Karakaya M, Avcı AK. Thermodynamic analysis of steam assisted conversions of bio-oil components to synthesis gas. Int. J. Hydrogen Energy34(4),1752–1759 (2009).
  • Lea-Langton A, Zin RM, Dupont V, Twigg MV. Biomass pyrolysis oils for hydrogen production using chemical looping reforming. Int. J. Hydrogen Energy37(2),2037–2043 (2012).
  • Rioche C, Kulkarni S, Meunier FC, Breen JP, Burch R. Steam reforming of model compounds and fast pyrolysis bio-oil on supported noble metal catalysts. Appl. Catal. B. Environ.61(1–2),130–139 (2005).
  • Yan CF, Cheng FF, Hu RR. Hydrogen production from catalytic steam reforming of bio-oil aqueous fraction over Ni/CeO2-ZrO2 catalysts. Int. J. Hydrogen Energy35(21),11693–11699 (2010).
  • Marquevich M, Medina F, Montané D. Hydrogen production via steam reforming of sunflower oil over Ni/Al catalysts from hydrotalcite materials. Catal. Commun.2(3–4),119–124 (2001).
  • Dupont V. Steam reforming of sunflower oil for hydrogen gas production. HELIA30(46),103–132 (2007).
  • Yenumala SR, Maity SK. Reforming of vegetable oil for production of hydrogen: a thermodynamic analysis. Int. J. Hydrogen Energy36(18),11666–11675 (2011).
  • Pimenidou P, Rickett G, Dupont V, Twigg MV. Chemical looping reforming of waste cooking oil in packed bed reactor. Bioresour. Technol.101(16),6389–6397 (2010).
  • Pimenidou P, Rickett G, Dupont V, Twigg MV. High purity H2 by sorption-enhanced chemical looping reforming of waste cooking oil in a packed bed reactor. Bioresour. Technol.101(23),9279–9286 (2010).
  • Marquevich M, Farriol X, Medina F, Montané D. Steam reforming of sunflower oil over Ni/Al catalysts prepared from hydrotalcite-like materials. Catal. Lett.85(1),41–48 (2003).
  • Marquevich M, Coll R, Montané D. Steam reforming of sunflower oil for hydrogen production. Ind. Eng. Chem. Res.39(7),2140–2147 (2000).
  • Marquevich M, Farriol X, Medina F, Montané D. Hydrogen production by steam reforming of vegetable oils using nickel-based catalysts. Ind. Eng. Chem. Res.40(22),4757–4766 (2001).
  • Shotipruk A, Assabumrungrat S, Pavasant P, Laosiripojana N. Reactivity of CeO2 and Ce-ZrO2 toward steam reforming of palm fatty acid distilled (PFAD) with co-fed oxygen and hydrogen. Chem. Eng. Sci.64(3),459–466 (2009).
  • Katikaneni SPR, Adjaye JD, Idem RO, Bakhshi NN. Catalytic conversion of canola oil over potassium-impregnated HZSM-5 catalysts: C2-C4 olefin production and model reaction studies. Ind. Eng. Chem. Res.35(10),3332–3346 (1996).
  • Kim T, Liu G, Boaro M et al. A study of carbon formation and prevention in hydrocarbon-fueled SOFC. J. Power Sources155(2),231–238 (2006).
  • Adjaye JD, Bakhshi NN. Biomass Bioenergy8,131 (1995).
  • Adebanjo AO, Dalai AK, Bakhshi NN. Production of diesel-like fuel and other value-added chemicals from pyrolysis of animal fat. Energy Fuels19(4),1735–1741 (2005).
  • Katikaneni SPR, Adjaye JD, Bakhshi NN. Studies on the catalytic conversion of canola oil to hydrocarbons: influence of hybrid catalysts and steam. Energy Fuels9(4),599–609 (1995).
  • Katikaneni SPR, Adjaye JD, Bakhshi NN. Performance of aluminophosphate molecular sieve catalysts for the production of hydrocarbons from wood-derived and vegetable oils. Energy Fuels9(6),1065–1078 (1995).
  • Yarlagadda PS, Hu Y, Bakhshi NN. Effect of hydrothermal treatment of HZSM-5 catalyst on its performance for the conversion of canola and mustard oils to hydrocarbons. Ind. Eng. Chem. Product Res. Dev.25(2),251–257 (1986).
  • Demirbas A. Fuel properties and calculation of higher heating values of vegetable oils. Fuel77(9–10),1117–1120 (1998).
  • Jon Van G. Biodiesel processing and production. Fuel Process. Technol.86(10),1097–1107 (2005).
  • Chongkhong S, Tongurai C, Chetpattananondh P, Bunyakan C. Biodiesel production by esterification of palm fatty acid distillate. Biomass Bioenergy31(8),563–568 (2007).
  • Leung DYC, Wu X, Leung MKH. A review on biodiesel production using catalyzed transesterification. Appl. Energy87(4),1083–1095 (2010).
  • Jain S, Sharma MP. Kinetics of acid base catalyzed transesterification of Jatropha curcas oil. Bioresource Technol.101(20),7701–7706 (2010).
  • Hoekman SK, Broch A, Robbins C, Ceniceros E, Natarajan M. Review of biodiesel composition, properties, and specifications. Renewable Sustainable Energy Rev.16(1),143–169 (2012).
  • Nahar GA. Hydrogen rich gas production by the autothermal reforming of biodiesel (FAME) for utilization in the solid-oxide fuel cells: a thermodynamic analysis. Int. J. Hydrogen Energy35(17),8891–8911 (2010).
  • Sgroi M, Bollito G, Saracco G, Specchia S. BIOFEAT. Biodiesel fuel processor for a vehicle fuel cell auxiliary power unit: study of the feed system. J. Power Sources149,8–14 (2005).
  • Kraaij GJ, Specchia S, Bollito G, Mutri L, Wails D. Biodiesel fuel processor for APU applications. Int. J. Hydrogen Energy34(10),4495–4499 (2009).
  • Abatzoglou NFLC, Braidy N. Biodiesel reforming with a NiAl2O4/Al2O3-YSZ catalyst for the production of renewable SOFC fuel. Energy Sustainability9(145–155),11 (2011).
  • Hu X, Lu G. Bio-oil steam reforming, partial oxidation or oxidative steam reforming coupled with bio-oil dry reforming to eliminate CO2 emission. Int. J. Hydrogen Energy35(13),7169–7176 (2010).
  • BP /DuPont launches Butamax biobutanol. Focus on Catalysts12,5 (2009).
  • Gevo launches biobutanol plant. Focus on Catalysts3,6 (2010).
  • Huang H, Liu H, Gan YR. Genetic modification of critical enzymes and involved genes in butanol biosynthesis from biomass. Biotechnol. Adv.28(5),651–657 (2010).
  • Brian JG. The economics of producing biodiesel from algae. Renewable Energy36(1),158–162 (2011).
  • Biodiesel plant planned for Singapore. Pump Industry Analyst2,3 (2008).
  • Jacobs to support Neste’s renewable diesel plant in Singapore. Pump Industry Analyst9,4 (2008).
  • Arvidsson R, Persson S, Fröling M, Svanström M. Life cycle assessment of hydrotreated vegetable oil from rape, oil palm and Jatropha. J. Cleaner Production19(2–3),129–137.
  • Holladay JD, Wang Y, Jones E. Review of developments in portable hydrogen production using microreactor technology. Chem. Rev.104(10),4767–4790 (2004).
  • InnovaTek uses biodiesel in microchannel steam reformer. Fuel Cells Bulletin5,2 (2006).
  • Chevron to develop bio-diesel processing technology. Fuel Cells Bulletin2,4 (2007).
  • Ray AK, Sinha SK, Tiwari YN et al. Analysis of failed reformer tubes. Eng. Fail. Anal.10(3),351–362 (2003).

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