TECHNICAL PAPERS: Gas Turbines: Cycle Innovations

Integrated Pyrolysis Regenerated Plant (IPRP): An Efficient and Scalable Concept for Gas Turbine Based Energy Conversion From Biomass and Waste

[+] Author and Article Information
Francesco Fantozzi

Dipartimento di Ingegneria Industriale, Universitá degli Studi di Perugia, Via G. Duranti 1A/4, 06125 Perugia, Italye-mail: fanto@unipg.it

Bruno D’Alessandro

Ingegneria dei Materiali, Universitá degli Studi di Perugia, Loc. Pentima Bassa 21, 05100 Terni, Italye-mail: dalessandro@mach.ing.unipg.it

Umberto Desideri

Dipartimento di Ingegneria Industriale, Universitá degli Studi di Perugia, Via G. Duranti 1A/4, 06125 Perugia, Italye-mail: umberto.desideri@unipg.it

J. Eng. Gas Turbines Power 127(2), 348-357 (Apr 15, 2005) (10 pages) doi:10.1115/1.1789513 History: Received October 01, 2002; Revised March 01, 2003; Online April 15, 2005
Copyright © 2005 by ASME
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UN Convention on Climate Change, 1997, Report of the conference of the parties on its third session, held at Kyoto from 1 to 11 December, FCCC/CP/1997/7/Add. 1.
van den Broek,  R., Faaij,  A., and van Wijk,  A., 1996, “Biomass Combustion for Power Generation,” Biomass Bioenergy, 11, pp. 271–281.
Stàhl,  K., and Neergaard,  M., 1998, “IGCC Power Plant for Biomass Utilisation, Värnamo, Sweden,” Biomass Bioenergy, 15, pp. 205–211.
Elmegaard, B., Henriksen, U., and Qvale, B., 2002, “Thermodynamic Analysis of Supplementary-Fired Gas Turbine Cycles,” Proceedings of the Conference “ECOS 2002”.
Elmegaard, B., Qvale, B., Carapelli, G., and De Faveri, P., 2001, “Open-Cycle Indirectly Fired Gas Turbine for Wet Biomass Fuels,” Proceedings of the Conference “ECOS 2001,” July 4–6, Istanbul, Turkey.
Solantausta,  Y., Bridgwater,  A. V., and Beckman,  D., 1995, “Feasibility of Power Production With Pyrolysis and Gasification Systems,” Biomass Bioenergy, 9, pp. 257–269.
Bridgwater,  A. V., Elliot,  D. C., Fagernas,  L., Gifford,  J. S., Mackie,  K. L., and Toft,  A. J., 1995, “The Nature and Control of Solid, Liquid and Gaseous Emissions From the Thermochemical Processing of Biomass,” Biomass Bioenergy, 9, pp. 325–341.
Demirbas,  A., 2001, “Carbonisation Ranking of Selected Biomass for Charcoal, Liquid and Gaseous Products,” Energy Convers. Manage., 42, pp. 1229–1238.
Demirbas,  A., 1997, “Calculation of Higher Heating Values of Biomass Fuels,” Fuel, 76, pp. 431–434.
Demirbas,  A., 2000, “Mechanism of Liquefaction and Pyrolysis Reactions of Biomass,” Energy Convers. Manage., 41, pp. 633–646.
Di Blasi, C., and Branca, C., 2000, “Evaluation of the Performance of a Novel Straw Pyrolysis Reactor,” 1st World Conference on Biomass for Energy and Industry, Sevilla, Spain, 5–9 June, pp. 1767–1770.
Di Blasi,  C., Signorelli,  G., Di Russo,  C., and Rea,  G., 1999, “Product Distribution From Pyrolysis of Wood and Agricultural Residues,” Ind. Eng. Chem. Res., 38, pp. 2216–2224.
Di Blasi,  C., Signorelli,  G., and Portoricco,  G., 1999, “Countercurrent Fixed-Bed Gasification of Biomass at Laboratori Scale,” Ind. Eng. Chem. Res., 38, pp. 2571–2581.
Roy, C., and Morin, D., 1998, “Efficient Electricity Production From Biomass Through IPCC Power Plants,” 4th International Conference on Greenhouse Gas Control Technologies (GHGT4), Interlaken, Switzerland.
Fantozzi,  F., D’Alessandro,  B., and Bidini,  G., 2003, “IPRP—Integrated Pyrolysis Regenerated Plant—Gas Turbine and Externally Heated Rotary-Kiln Pyrolysis as a Biomass and Waste Energy Conversion System. Influence of Thermodynamic Parameters,” Proc. Inst. Mech. Eng., Part A: J. Power Energy 217, pp. 519–527.
Fantozzi, F., Di Maria, F., and Desideri, U., 2001, “Micro-Turbine Fuelled by Pyrolysis Gas,” Thermodynamic Analysis, Proceedings of the POWERGEN Europe Congress and Exhibition, Helsinki.
Fantozzi, F., Di Maria, F., and Desideri, U., 2002, “Integrated Micro-Turbine and Rotary Kiln Pyrolysis System as a Waste to Energy Solution for a Small Town in Central Italy—Cost Positioning and Global Warming Assessment,” ASME Paper GT-2002-30652.
Li,  A. M., Li,  X. D., Ren,  Y., Chi,  Y., Yan,  J. H., and Cen,  K. F., 1999, “Pyrolysis of Solid Waste in a Rotary Kiln: Influence of Final Pyrolysis Temperature on the Pyrolysis Products,” J. Anal. Appl. Pyrolysis, 50, pp. 149–162.
Yang,  J., and Roy,  C., 1996, “A New Method for DTA Measurement of Enthalpy Change During the Pyrolysis of Rubbers,” Thermochim. Acta, 288, pp. 155–168.
Arcangioli, S., Gamberi, F., Milli, A., and Scapecchi, N., “Analysis of an Indirectly Biomass-Fired Gasturbine Engine Integrated With Pyrolysis for Supplementary Firing,” Biomass Gasification Group, Department of Mechanical Engineering, Technical University of Denmark (DTU) Internal Report.
Neilson,  C. E., 1998, “LM2500 Gas Turbine Modifications for Biomass Fuel Operation,” Biomass Bioenergy, 15, pp. 269–273.
Encinar,  J. M., Gonzalez,  J. F., and Gonzalez,  J., 2000, “Fixed-Bed Pyrolysis of Cynara Cardunculus L. Product Yields and Compositions,” Fuel Process. Technol., 68, pp. 209–222.
Frantozzi, F., and Desideri, U., 2004, “Micro Scale Rotary Kiln Slow-Pyrolysis for Syngas and Char Production from Biomass and Waste: Reactor and Test Bench Realization,” ASME Paper GT-2004-54186.
Bidini, G., Moriconi, A., Rossi, D., and Fantozzi, F., 2004, “IPRP—Integrated Pyrolysis Regenerated Plant Rotary Kiln Pyrolyzer and Microturbine for Distributed Energy Conversion from Biomass—A 70 Kw Demonstration Unit in Central Italy,” Proceedings of the Second World Conference and Technology Exhibition on Biomass for Energy Industry and Clilmate Protection, May, Rome.


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Pyrolysis products yield (left) 18 and LHV (right) 18
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Effect of TIT and Tp on specific work
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Results for the simple cycle (Ref. 15)
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Plant efficiency versus TIT for the simple cycle (Ref. 15)
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Results for case B and case C cycle with REC and REC & REG
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Best efficiency points for case C
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Best efficiency points for typical GT size parameters for case C
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Comparison of plant efficiency in case A
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Pyrolysis products yield (a), LHV (b), and heat required for the pyrolysis (c) 22
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Results obtained for case C biomass fueled



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