Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/oxford-university-press/integration-of-biocrude-production-from-fast-pyrolysis-of-biomass-with-YlUETZSpbV
References (75)
-
M. Amutio, G. Lopez, R. Aguado, J. Bilbao, M. Olazar (2012)
Biomass Oxidative Flash Pyrolysis: Autothermal Operation, Yields and Product PropertiesEnergy & Fuels, 26
-
D. Scott, P. Majerski, J. Piskorz, D. Radlein (1999)
A second look at fast pyrolysis of biomass—the RTI processJournal of Analytical and Applied Pyrolysis, 51
-
J. Alvarez, G. Lopez, M. Amutio, J. Bilbao, M. Olazar (2014)
Bio-oil production from rice husk fast pyrolysis in a conical spouted bed reactorFuel, 128
-
citation_author=Ensyn; citation_publisher=In: International Bioenergy Conference & Exhibition, Prince George, British Columbia, Canada, 17 June 2016, ; Evolution of Next Generation Bioproducts -
R. Venderbosch (2015)
A critical view on catalytic pyrolysis of biomass.ChemSusChem, 8 8
-
Q. Lu, Wenzhi Li, Xifeng Zhu (2009)
Overview of fuel properties of biomass fast pyrolysis oilsEnergy Conversion and Management, 50
-
Vaibhav Dhyani, T. Bhaskar (2017)
A comprehensive review on the pyrolysis of lignocellulosic biomassRenewable Energy
-
D. Meier, O. Faix (1999)
State of the art of applied fast pyrolysis of lignocellulosic materials - a reviewBioresource Technology, 68
-
K. Iisa, D. Robichaud, M. Watson, J. Dam, Abhijit Dutta, C. Mukarakate, Seonah Kim, M. Nimlos, R. Baldwin (2018)
Improving biomass pyrolysis economics by integrating vapor and liquid phase upgradingGreen Chemistry, 20
-
(1987)
citation_publisher=McGraw-Hill, New York; The Properties of Gases and Liquids -
D. Vamvuka (2011)
Bio‐oil, solid and gaseous biofuels from biomass pyrolysis processes—An overviewInternational Journal of Energy Research, 35
-
T. Odetoye, K. Onifade, M. Abubakar, J. Titiloye (2014)
Pyrolysis of Parinari polyandra Benth fruit shell for bio-oil production, 1
-
(2015)
Pyrolysis oil utilization in 50 KWe gas turbine -
John Rezaiyan, N. Cheremisinoff (2005)
Gasification Technologies: A Primer for Engineers and Scientists -
(2017)
citation_author=Snowy Hydro; citation_publisher=Snowy Hydro Ltd, Sydney, Australia; Snowy 2.0: Feasibility Study Summary -
D. Bulushev, J. Ross (2011)
Catalysis for conversion of biomass to fuels via pyrolysis and gasification: A reviewCatalysis Today, 171
-
Zixu Yang, Ajay Kumar, R. Huhnke (2015)
Review of recent developments to improve storage and transportation stability of bio-oilRenewable & Sustainable Energy Reviews, 50
-
(2014)
citation_publisher=VTT, Espoo, Finland; Bio-oil for the Future: Fast Pyrolysis Liquids as Energy Carriers -
R. Reid, J. Prausnitz, T. Sherwood (1989)
Properties of Gases and Liquids -
G. Lopez, A. Erkiaga, M. Amutio, J. Bilbao, M. Olazar (2015)
Effect of polyethylene co-feeding in the steam gasification of biomass in a conical spouted bed reactorFuel, 153
-
G. Perkins, T. Bhaskar, Muxina Konarova (2018)
Process development status of fast pyrolysis technologies for the manufacture of renewable transport fuels from biomassRenewable and Sustainable Energy Reviews
-
Jon Makibar, A. Fernandez-Akarregi, M. Amutio, G. Lopez, M. Olazar (2015)
Performance of a conical spouted bed pilot plant for bio-oil production by poplar flash pyrolysisFuel Processing Technology, 137
-
K. Sipilä, E. Kuoppala, L. Fagernäs, A. Oasmaa (1998)
Characterization of biomass-based flash pyrolysis oilsBiomass & Bioenergy, 14
-
(2005)
citation_publisher=CRC Press, Boca Raton, FL; Gasification Technologies: A Primer for Engineers and Scientists -
B. Beld, E. Holle, J. Florijn (2013)
The use of pyrolysis oil and pyrolysis oil derived fuels in diesel engines for CHP applicationsApplied Energy, 102
-
(2013)
citation_publisher=In: tcbiomass2013 (The International Conference on Thermochemical Conversion Science), Chicago, Illinois; Alternative heating oil from wood residues?industrial demonstration -
(2015)
Looking back at the first half year of commercial scale pyrolysis oil production at Empyro -
S. Maity (2015)
Opportunities, recent trends and challenges of integrated biorefinery: Part II.Renewable & Sustainable Energy Reviews, 43
-
R. Graham, B. Freel, D. Huffman, M. Bergougnou (1994)
Commercial-scale rapid thermal processing of biomassBiomass & Bioenergy, 7
-
(2016)
citation_author=Clean Energy Council; citation_publisher=Clean Energy Council, Melbourne, Australia; Clean Energy Australia Report 2016 -
A. Bridgwater (2012)
Review of fast pyrolysis of biomass and product upgradingBiomass & Bioenergy, 38
-
(2012)
Upgrading biomass fast pyrolysis liquidsEnv Prog Sust Eng, 31
-
Ville Paasikallio, C. Lindfors, J. Lehto, A. Oasmaa, M. Reinikainen (2013)
Short Vapour Residence Time Catalytic Pyrolysis of Spruce Sawdust in a Bubbling Fluidized-Bed Reactor with HZSM-5 CatalystsTopics in Catalysis, 56
-
A. Janse, X. Jong, W. Prins, W. Swaaij (1999)
Heat transfer coefficients in the rotating cone reactorPowder Technology, 106
-
Ofei Mante, D. Dayton, J. Carpenter, Kaige Wang, Jonathan Peters (2018)
Pilot-scale catalytic fast pyrolysis of loblolly pine over γ-Al 2 O 3 catalystFuel, 214
-
RH Venderbosch, W. Prins (2010)
Fast pyrolysis technology developmentBiofuels, 4
-
(2016)
citation_author=Queensland Department of State Development; citation_publisher=Queensland Government, Brisbane, Australia; Queensland Biofutures 10-Year Roadmap and Action Plan -
D. Chiaramonti, A. Oasmaa, Y. Solantausta (2007)
Power generation using fast pyrolysis liquids from biomassRenewable & Sustainable Energy Reviews, 11
-
J. Lehto, A. Oasmaa, Y. Solantausta, M. Kytö, D. Chiaramonti (2013)
Fuel oil quality and combustion of fast pyrolysis bio-oils -
(2013)
citation_publisher=In: 4th European Conference on Renewable Heating and Cooling, Dublin, Ireland; Fast pyrolysis oil production in connection to CHP production in Joensuu, Finland -
G. Kabir, B. Hameed (2017)
Recent progress on catalytic pyrolysis of lignocellulosic biomass to high-grade bio-oil and bio-chemicalsRenewable & Sustainable Energy Reviews, 70
-
R. Venderbosch, A. Ardiyanti, J. Wildschut, A. Oasmaa, H. Heeres (2010)
Stabilization of biomass‐derived pyrolysis oilsJournal of Chemical Technology & Biotechnology, 85
-
R. Graham, M. Bergougnou, B. Freel (1994)
The kinetics of vapour-phase cellulose fast pyrolysis reactionsBiomass & Bioenergy, 7
-
M. Amutio, G. Lopez, R. Aguado, M. Artetxe, J. Bilbao, M. Olazar (2011)
Effect of Vacuum on Lignocellulosic Biomass Flash Pyrolysis in a Conical Spouted Bed ReactorEnergy & Fuels, 25
-
D. Meier, B. Beld, A. Bridgwater, D. Elliott, A. Oasmaa, F. Preto (2013)
State-of-the-Art of Fast Pyrolysis in IEA Bioenergy Member CountriesRenewable & Sustainable Energy Reviews, 20
-
(2009, 915–22)
Integrated heat, electricity and bio-oil production -
J. Akhtar, N. Amin (2012)
A review on operating parameters for optimum liquid oil yield in biomass pyrolysisRenewable & Sustainable Energy Reviews, 16
-
C. Pfitzer, N. Dahmen, N. Troeger, Friedhelm Weirich, J. Sauer, A. Günther, M. Müller-Hagedorn (2016)
Fast Pyrolysis of Wheat Straw in the Bioliq Pilot PlantEnergy & Fuels, 30
-
Ville Paasikallio, C. Lindfors, E. Kuoppala, Y. Solantausta, A. Oasmaa, J. Lehto, J. Lehtonen (2014)
Product quality and catalyst deactivation in a four day catalytic fast pyrolysis production runGreen Chemistry, 16
-
(2013)
citation_publisher=VTT, Espoo, Finland; Fuel Oil Quality and Combustion of Fast Pyrolysis Bio-oils -
Poritosh Roy, G. Dias (2017)
Prospects for pyrolysis technologies in the bioenergy sector: A reviewRenewable & Sustainable Energy Reviews, 77
-
A. Bridgwater, G. Peacocke (2000)
Fast pyrolysis processes for biomassRenewable & Sustainable Energy Reviews, 4
-
L. Mok, R. Graham, B. Freel, M. Bergougnou, R. Overend (1985)
Fast pyrolysis (ultrapyrolysis) of cellulose and wood componentsJournal of Analytical and Applied Pyrolysis, 8
-
A. Fernandez-Akarregi, Jon Makibar, G. Lopez, M. Amutio, M. Olazar (2013)
Design and operation of a conical spouted bed reactor pilot plant (25 kg/h) for biomass fast pyrolysisFuel Processing Technology, 112
-
N. Dahmen, E. Dinjus, T. Kolb, U. Arnold, H. Leibold, R. Stahl (2012)
State of the art of the bioliq® process for synthetic biofuels productionEnvironmental Progress & Sustainable Energy, 31
-
(2010)
Fundamentals, kinetics and endothermicity of the biomass pyrolysis reactionJ Renew Energy, 35
-
A. Fernandez-Akarregi, Jon Makibar, G. Lopez, M. Amutio, H. Altzibar, M. Olazar (2014)
Development of a dual conical spouted bed system for heat integration purposesPowder Technology, 268
-
J. Lehto, A. Oasmaa, Y. Solantausta, M. Kytö, D. Chiaramonti (2014)
Review of fuel oil quality and combustion of fast pyrolysis bio-oils from lignocellulosic biomassApplied Energy, 116
-
M. Velden, J. Baeyens, A. Brems, B. Janssens, R. Dewil (2010)
Fundamentals, kinetics and endothermicity of the biomass pyrolysis reactionRenewable Energy, 35
-
Ofei Mante, F. Agblevor (2014)
Catalytic pyrolysis for the production of refinery-ready biocrude oils from six different biomass sourcesGreen Chemistry, 16
-
A. Janse, P. Biesheuvel, W. Prins, W. Swaaij (2000)
A novel interconnected fluidised bed for the combined flash pyrolysis of biomass and combustion of charChemical Engineering Journal, 75
-
(2017)
Rapid Thermal Conversion of Biomass -
M. Amutio, G. Lopez, M. Artetxe, G. Elordi, M. Olazar, J. Bilbao (2012)
Influence of temperature on biomass pyrolysis in a conical spouted bed reactorResources Conservation and Recycling, 59
-
M. Pelaez-Samaniego, J. Mesa-Pérez, L. Cortez, J. Rocha, C. Sanchez, H. Marin (2011)
Use of blends of gasoline with biomass pyrolysis-oil derived fractions as fuels in an Otto engineEnergy for Sustainable Development, 15
-
A. Bridgwater (2012)
Upgrading biomass fast pyrolysis liquidsEnvironmental Progress & Sustainable Energy, 31
-
S. Nanda, Javeed Mohammad, S. Reddy, J. Kozinski, A. Dalai (2014)
Pathways of lignocellulosic biomass conversion to renewable fuelsBiomass Conversion and Biorefinery, 4
-
(1999)
Apparatus for a Circulating Bed Transport Fast Pyrolysis Reactor System -
A. Oasmaa, Bert Beld, P. Saari, D. Elliott, Y. Solantausta (2015)
Norms, Standards, and Legislation for Fast Pyrolysis Bio-oils from Lignocellulosic BiomassEnergy & Fuels, 29
-
J. Lédé, F. Broust, F. Ndiaye, M. Ferrer (2007)
Properties of bio-oils produced by biomass fast pyrolysis in a cyclone reactorFuel, 86
-
B. Wagenaar, W. Prins, W. Swaaij (1994)
Pyrolysis of biomass in the rotating cone reactor: modelling and experimental justificationChemical Engineering Science, 49
-
J. Alvarez, M. Amutio, G. Lopez, J. Bilbao, M. Olazar (2015)
Fast co-pyrolysis of sewage sludge and lignocellulosic biomass in a conical spouted bed reactorFuel, 159
-
K. Onarheim, Y. Solantausta, J. Lehto (2015)
Process simulation development of fast pyrolysis of wood using aspen plusEnergy & Fuels, 29
-
K. Iisa, R. French, Kellene Orton, Abhijit Dutta, Joshua Schaidle (2017)
Production of low-oxygen bio-oil via ex situ catalytic fast pyrolysis and hydrotreatingFuel, 207
-
D. Dayton, J. Carpenter, A. Kataria, Jonathan Peters, David Barbee, Ofei Mante, Raghubir Gupta (2015)
Design and operation of a pilot-scale catalytic biomass pyrolysis unitGreen Chemistry, 17
-
(2010)
Fast pyrolysis as pretreatment for further upgrading of biomass. In: Gasification 2010?
- Publisher
- Oxford University Press
- Copyright
- © The Author 2018. Published by Oxford University Press on behalf of National Institute of Clean-and-Low-Carbon Energy
- ISSN
- 2515-4230
- eISSN
- 2515-396X
- DOI
- 10.1093/ce/zky013
- Publisher site
- See Article on Publisher Site
Abstract
This article analyses the integration of distributed biocrude production facilities using fast pyrolysis with solar photovoltaic (PV) for dispatchable electricity production. The strong growth of intermittent electricity generation from solar PV and wind is leading to a greater need for energy storage at grid scale and dynamic demand management. Various forms of energy storage, including electrochemical (e.g. batteries), mechanical (e.g. flywheels) and gravitational (e.g. pumped-hydro), are being developed. This work studies the issues of integrating fast pyrolysis of biomass to produce biocrude that can be readily stored in tanks and combusted to produce electricity when required to supplement the electricity generation from a solar PV unit to meet an arbitrary energy demand curve. The use of biomass pyrolysis in this application has a range of benefits, including the flexibility to augment intermittent renewables, the integration of more bioenergy into the electricity sector and the creation of commercial quantities of biocrudes that can be refined into renewable transport fuels such as jet fuel for which few other alternatives exist. Biocrudes, especially partially upgraded, can be stored and used when required in engines and gas turbines, making them a suitable fuel for augmenting the intermittent nature of solar and wind projects. The development of the distributed 100% renewable power stations using a mix of biomass/biocrude and solar PV and/or wind would also increase the certainty of supply, knowledge of quality and price of raw biocrudes that can also be used to supply a centralized biorefinery, thereby substantially reducing the risk of investing in new biorefinery capacity.
Journal
Clean Energy – Oxford University Press
Published: Aug 13, 2018
Keywords: biomass; pyrolysis; biocrude; intermittent renewables; biofuels