Experiment of Gasification of the Synthetically Mixed Sample of Waste in Nitrogen Atmosphere

• Autorzy: Lázár M. , Jasminská N. , Lengyelová N.
• Języki publikacji: EN

Abstrakty

EN

New classes of singular fractional continuous-time and discrete-time linear systems are introduced. Electrical circuits are example of singular fractional continuous-time systems. Using the Caputo definition of the fractional derivative, the Weierstrass regular pencil decomposition and Laplace transformation the solution to the state equation of singular fractional linear systems is derived. It is shown that every electrical circuit is a singular fractional systems if it contains at least one mesh consisting of branches with only ideal supercondensators and voltage sources or at least one node with branches with supercoils. Using the Weierstrass regular pencil decomposition the solution to the state equation of singular fractional discrete-time linear systems is derived. The considerations are illustrated by numerical examples.

Słowa kluczowe

EN

plasma reactor; gasification; organic waste; syngas

PL

reaktor plazmowy; zgazowanie; odpady organiczne; gaz syntezowy

• Wydawca: Oficyna Wydawnicza Politechniki Białostockiej
• Czasopismo: Acta Mechanica et Automatica
• Rocznik: 2013
• Tom: Vol. 7, no. 1
• Strony: 34--37
• Opis fizyczny: Bibliogr. 12 poz., wykr.

Twórcy

autor

Lázár M.

autor

Jasminská N.

autor

Lengyelová N.

• Faculty of Mechanical Engineering, Technical University of Košice, ul. Vysokoškolská 4, 042 00 Košice, Slovak Republic,

Bibliografia

• 1. Arena U. (2012), Process and technological aspects of municipal solid waste gasification. A review, Waste Management, Vol. 32, 625-639.
• 2. Blejchař T., Čech B., Malý R., Kolat P., Dluhoš M. (2007), Plazmové systémy v energetice In: Environmental Protection into the Future, Czenstochowa University of Technology, 30-42., ISBN 978-83-7193-340-0.
• 3. Consonni S., Vigano F. (2012), Waste gasification vs. conventional Waste-To-Energy: A comparative evaluation of two commercial Technologies, Waste Management,Vol. 32, 653-666.
• 4. Gomez E., Rani A. D., Cheeseman R. C., Deegan D., Wise M., Boccaccini R. A. (2009), Thermal plasma technology for the treatment of wastes, Journal of Hazardous Materials, Vol. 161, 614-626.
• 5. Horbaj P., Imriš I. (2000), Some possibilities of municipal waste treating (Niektoré možnosti využívania komunálneho odpadu), International Conference TOP 2000, Častá Papiernička 15–16 jún 2000, 233-243.
• 6. Hrabovský M. (2011), Thermal Plasma Gasification of Biomass, Biomass and Bioenergy, 39-62, ISBN 978-953-307-491-7.
• 7. Imriš I. (2006), Plasma reactor for waste treatment, Heat transfer and renewable sources of energy Szczecin, Wydawnictwo Uczelniane Politechniki Szczecinskiej, 301-308.
• 8. Internal Material of company „Silvergas s.r.o.“
• 9. Koukouzas N., Katsiadakis A., Karlopoulos E., Kakaras E.(2008), Co-gasification of solid waste and lignite – A case study for Western Macedonia, Waste Management, Vol. 28, 1263-2675.
• 10. Lázár M. (2012), Research of municipal waste utilization possibilities in the plasma reactor, Doktorant thesis, Technical University of Košice.
• 11. Shibaike, H., et. al. (2005), Development of high-performance direct melting process for municipal solid waste, Nippon Steel Technical Report [online].
• 12. Tanigaki N., Manako K., Osada M. (2012), Co-gasification of municipal solid waste and material recovery in a large-scale gasification and melting system, Waste Management, Vol. 32, 667-675.