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2017 | OriginalPaper | Buchkapitel

10. Production of Renewable Hydrogen; Liquid Transportation Fuels (BTL)

verfasst von : Samira Bagheri

Erschienen in: Catalysis for Green Energy and Technology

Verlag: Springer International Publishing

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Abstract

The main challenges in transportation sector at United States are the volatility of the global oil market, the prices of energy highly increasing and consistent pressure to reduce the emissions of the lifecycle greenhouse gas. Due to the concern on the “peak-oil” domestic for production of crude oil, the nations of OPEC are remains unrest (Wang et al. 2013; Nashawi et al. 2010), and efforts to develop liquid fuels which can be produced from domestic feedstocks based on carbon have been motivated in order to provide a significant means for increasing security of nation by enhanced the independence of energy. Therefore, it is expected that the demand for additional fuel using “non-petroleum” based feedstocks will be largely satisfied for the country. To process the alternative feedstocks, investigation on several technologies have been carried out. The main supply of the liquid fuels come from the biomass sources.

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Vorheriges Kapitel Catalytic Upgrading of Bio-oil: Biomass Gasification in the Presence of Catalysts

Nächstes Kapitel Catalytic Transformation of CO2 to Fuels

Agrawal R, Singh NR, Ribeiro FH, Delgass WN (2007) Sustainable fuel for the transportation sector. Proc Natl Acad Sci 104(12):4828–4833CrossRef

Baliban RC, Elia JA, Floudas CA (2010) Toward novel hybrid biomass, coal, and natural gas processes for satisfying current transportation fuel demands, 1: process alternatives, gasification modeling, process simulation, and economic analysis. Ind Eng Chem Res 49(16):7343–7370CrossRef

Baliban RC, Elia JA, Floudas CA (2011) Optimization framework for the simultaneous process synthesis, heat and power integration of a thermochemical hybrid biomass, coal, and natural gas facility. Comput Chem Eng 35(9):1647–1690CrossRef

Baliban RC, Elia JA, Floudas CA (2012) Simultaneous process synthesis, heat, power, and water integration of thermochemical hybrid biomass, coal, and natural gas facilities. Comput Chem Eng 37:297–327CrossRef

Boerrigter H, Van Der Drift A (2004) Biosyngas: description of R&D trajectory necessary to reach large-scale implementation of renewable syngas from biomass. Energy Research Centre of the Netherlands, The Netherlands

Boerrigter H, Calis HP, Slort DJ, Bodenstaff H (2004a) Gas cleaning for integrated biomass gasification (BG) and Fischer-Tropsch (FT) systems; experimental demonstration of two BG-FT systems. Acknowledgement/Preface:51

Boerrigter H, Zwart R, van Ree R, Veringa H (2004b) High efficiency co-production of Fischer-Tropsch (FT) transportation fuels and Substitute Natural Gas (SNG) from biomass. ECN, The Netherlands

Borgwardt RH (1997) Biomass and natural gas as co-feedstocks for production of fuel for fuel-cell vehicles. Biomass Bioenerg 12(5):333–345CrossRef

Bridgwater AV, Double JM (1991) Production costs of liquid fuels from biomass. Fuel 70(10):1209–1224CrossRef

Bridgwater A, Czernik S, Piskorz J (2001) An overview of fast pyrolysis. In: Progress in thermochemical biomass conversion, pp 977–997

Caldwell L (1980) Selectivity in Fischer-Tropsch synthesis: review and recommendations for further work

Chen Y, Adams TA, Barton PI (2011) Optimal design and operation of flexible energy polygeneration systems. Ind Eng Chem Res 50(8):4553–4566CrossRef

Clausen LR, Elmegaard B, Houbak N (2010) Technoeconomic analysis of a low CO₂ emission dimethyl ether (DME) plant based on gasification of torrefied biomass. Energy 35(12):4831–4842CrossRef

Council NR (2004) The hydrogen economy: opportunities, costs, barriers, and R&D needs. National Academies Press, Washington D.C.

Council NR (2008) Water implications of biofuels production in the United States. National Academies Press, Washington D.C.

Council NR (2010) Liquid transportation fuels from coal and biomass: technological status, costs, and environmental impacts. National Academies Press, Washington D.C.

Devi L, Ptasinski KJ, Janssen FJ (2003) A review of the primary measures for tar elimination in biomass gasification processes. Biomass Bioenerg 24(2):125–140CrossRef

Dong Y, Steinberg M (1997) Hynol—an economical process for methanol production from biomass and natural gas with reduced CO₂ emission. Int J Hydrogen Energy 22(10–11):971–977CrossRef

Dry ME (2002) The fischer–tropsch process: 1950–2000. Catal Today 71(3):227–241CrossRef

Dry M (2004) FT catalysts. Stud Surf Sci Catal 152:533–600CrossRef

Elia JA, Baliban RC, Xiao X, Floudas CA (2011) Optimal energy supply network determination and life cycle analysis for hybrid coal, biomass, and natural gas to liquid (CBGTL) plants using carbon-based hydrogen production. Comput Chem Eng 35(8):1399–1430CrossRef

Elia JA, Baliban RC, Floudas CA (2012) Nationwide energy supply chain analysis for hybrid feedstock processes with significant CO₂ emissions reduction. AIChE J 58(7):2142–2154CrossRef

Floudas CA, Elia JA, Baliban RC (2012) Hybrid and single feedstock energy processes for liquid transportation fuels: a critical review. Comput Chem Eng 41:24–51CrossRef

Hamelinck CN, Faaij AP, den Uil H, Boerrigter H (2004) Production of FT transportation fuels from biomass; technical options, process analysis and optimisation, and development potential. Energy 29(11):1743–1771CrossRef

Henrich E, Dahmen N, Dinjus E (2009) Cost estimate for biosynfuel production via biosyncrude gasification. Biofuels, Bioprod Biorefin 3(1):28–41CrossRef

Hirschenhofer J, Stauffer D, Engleman R, Klett M (2000) Fuel cell handbook. Business/Technology Books

Huber GW, Iborra S, Corma A (2006) Synthesis of transportation fuels from biomass: chemistry, catalysts, and engineering. Chem Rev 106(9):4044–4098CrossRef

Kreutz TG, Larson ED, Liu G (2008) Williams RH Fischer-Tropsch fuels from coal and biomass. In: 25th annual international Pittsburgh coal conference. vol 2.10, Citeseer

Lange J-P (2001) Methanol synthesis: a short review of technology improvements. Catal Today 64(1):3–8CrossRef

Lange JP (2007) Lignocellulose conversion: an introduction to chemistry, process and economics. Biofuels, Bioprod Biorefin 1(1):39–48CrossRef

Larson ED, Jin H, Celik FE (2009) Large-scale gasification-based coproduction of fuels and electricity from switchgrass. Biofuels, Bioprod Biorefin 3(2):174–194CrossRef

Larson ED, Fiorese G, Liu G, Williams RH, Kreutz TG, Consonni S (2010) Co-production of decarbonized synfuels and electricity from coal+ biomass with CO₂ capture and storage: an Illinois case study. Energy Environ Sci 3(1):28–42CrossRef

Laser M, Jin H, Jayawardhana K, Dale BE, Lynd LR (2009a) Projected mature technology scenarios for conversion of cellulosic biomass to ethanol with coproduction thermochemical fuels, power, and/or animal feed protein. Biofuels, Bioprod Biorefin 3(2):231–246CrossRef

Laser M, Larson E, Dale B, Wang M, Greene N, Lynd LR (2009b) Comparative analysis of efficiency, environmental impact, and process economics for mature biomass refining scenarios. Biofuels, Bioprod Biorefin 3(2):247–270CrossRef

Li H, Hong H, Jin H, Cai R (2010) Analysis of a feasible polygeneration system for power and methanol production taking natural gas and biomass as materials. Appl Energy 87(9):2846–2853CrossRef

Lipman TE (2004) What will power the hydrogen economy? Present and future sources of hydrogen energy

Liu G, Larson ED, Williams RH, Kreutz TG, Guo X (2010) Making Fischer − Tropsch fuels and electricity from coal and biomass: performance and cost analysis. Energy Fuels 25(1):415–437CrossRef

Liu G, Williams RH, Larson ED, Kreutz TG (2011a) Design/economics of low-carbon power generation from natural gas and biomass with synthetic fuels co-production. Energy Procedia 4:1989–1996CrossRef

Liu P, Whitaker A, Pistikopoulos EN, Li Z (2011b) A mixed-integer programming approach to strategic planning of chemical centres: a case study in the UK. Comput Chem Eng 35(8):1359–1373CrossRef

Magrini-Bair KA, Czernik S, French R, Chornet E (2003) Fluidizable catalysts for hydrogen production from biomass pyrolysis/steam reforming. FY 2003 Progress Report, National Renewable Energy Laboratory

Martínez A, López C (2005) The influence of ZSM-5 zeolite composition and crystal size on the in situ conversion of Fischer-Tropsch products over hybrid catalysts. Appl Catal A 294(2):251–259CrossRef

Milne TA, Abatzoglou N, Evans RJ (1998) Biomass gasifier” tars”: their nature, formation, and conversion, vol 570. National Renewable Energy Laboratory Golden, COCrossRef

Mitchell D, Brown M (1985) Catalytic steam gasification of biomass for methanol and methane production1. J Sol Energy Eng 107:89CrossRef

Nashawi IS, Malallah A, Al-Bisharah M (2010) Forecasting world crude oil production using multicyclic Hubbert model. Energy Fuels 24(3):1788CrossRef

Onel O, Niziolek AM, Floudas CA (2016) Optimal production of light olefins from Natural gas via the methanol intermediate. Ind Eng Chem Res 55(11):3043–3063CrossRef

Perales AV, Valle CR, Ollero P, Gómez-Barea A (2011) Technoeconomic assessment of ethanol production via thermochemical conversion of biomass by entrained flow gasification. Energy 36(7):4097–4108CrossRef

Perlack R, Wright L, Turhollow A, Graham R, Stokes B, Erbach D (2005) A bioenergy and bioproducts industry: the technical feasibility of a billion ton annual supply. US Department of Energy, Office of Scientific and Technical Information, Po Box 63:37831–30062

Rapagna S, Jand N, Kiennemann A, Foscolo P (2000) Steam-gasification of biomass in a fluidised-bed of olivine particles. Biomass Bioenerg 19(3):187–197CrossRef

Serrano-Ruiz JC, Braden DJ, West RM, Dumesic JA (2010) Conversion of cellulose to hydrocarbon fuels by progressive removal of oxygen. Appl Catal B 100(1):184–189CrossRef

Sharma P, Sarker B, Romagnoli JA (2011) A decision support tool for strategic planning of sustainable biorefineries. Comput Chem Eng 35(9):1767–1781CrossRef

Spath PL, Dayton DC (2003) Preliminary screening-technical and economic assessment of synthesis gas to fuels and chemicals with emphasis on the potential for biomass-derived syngas. DTIC Document

Ståhl K, Waldheim L, Morris M, Johnsson U (2004) Gårdmark L Biomass IGCC at Värnamo. GCEP energy workshop, Sweden-past and future. In

Sunde K, Brekke A, Solberg B (2011) Environmental impacts and costs of hydrotreated vegetable oils, transesterified lipids and woody BTL—a review. Energies 4(6):845–877CrossRef

Sutton D, Kelleher B, Ross JR (2001) Review of literature on catalysts for biomass gasification. Fuel Process Technol 73(3):155–173CrossRef

Tijmensen MJ, Faaij AP, Hamelinck CN, van Hardeveld MR (2002) Exploration of the possibilities for production of Fischer Tropsch liquids and power via biomass gasification. Biomass Bioenerg 23(2):129–152CrossRef

Tock L, Gassner M, Maréchal F (2010) Thermochemical production of liquid fuels from biomass: thermo-economic modeling, process design and process integration analysis. Biomass Bioenerg 34(12):1838–1854CrossRef

Tomishige K, Asadullah M, Kunimori K (2004) Syngas production by biomass gasification using Rh/CeO₂/SiO₂ catalysts and fluidized bed reactor. Catal Today 89(4):389–403CrossRef

Wang J, Feng L, Tverberg GE (2013) An analysis of China’s coal supply and its impact on China’s future economic growth. Energy Policy 57:542–551CrossRef

Warren A, El-Halwagi M (1996) An economic study for the co-generation of liquid fuel and hydrogen from coal and municipal solid waste. Fuel Process Technol 49(1–3):157–166CrossRef

Williams RH, Liu G, Kreutz TG, Larson ED (2011) Alternatives for decarbonizing existing USA coal power plant sites. Energy Procedia 4:1843–1850CrossRef

Wright MM, Daugaard DE, Satrio JA, Brown RC (2010) Techno-economic analysis of biomass fast pyrolysis to transportation fuels. Fuel 89:S2–S10CrossRef

Zhang R, Cummer K, Suby A, Brown RC (2005) Biomass-derived hydrogen from an air-blown gasifier. Fuel Process Technol 86(8):861–874CrossRef

Titel: Production of Renewable Hydrogen; Liquid Transportation Fuels (BTL)
verfasst von: Samira Bagheri
Verlag: Springer International Publishing
Buch: Catalysis for Green Energy and Technology
Print ISBN: 978-3-319-43103-1

Electronic ISBN: 978-3-319-43104-8

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-3-319-43104-8_10