Institut für Feuerungs- und Kraftwerkstechnik

Publikationen 2014

Dissertationen und Veröffentlichungen des Jahres 2014

Dissertationen

D. Kurz, "Numerische Simulation industrieller Rostfeuerungen nach der Euler-Euler Methode". Dissertation Universität Stuttgart, 2014.
Kurzfassung

J. Brellochs, "Experimentelle Untersuchung und Prozess-Simulation der AER-Biomassevergasung zur Erzeugung eines regenerativen Erdgassubstitutes".Dissertation Universität Stuttgart, 2014.
Kurzfassung

Kraftwerksfeuerungen

  1. L. Al-Makhadmeh, J. Maier, and G. Scheffknecht, “Oxyfuel technology: NO reduction during oxy-oil shale combustion,” Fuel, vol. 128, pp. 155–161, DOI: 10.1016/j.fuel.2014.03.003, 2014.
  2. S. Babat, R. Spörl, J. Maier, and G. Scheffknecht, “Investigation of iron-rich initial layer deposits at the inlet of the superheater level in a large pulverized fuel power plant,” in Tagungsband: Impacts of Fuel Quality on Power Production conference, October 26-31, 2014, in Snowbird, Utah, USA, Snowbird, Utah, USA, 2014.
  3. L. Belo et al., “Laboratory investigations on the differences in the homogeneous and catalytic conversions with fly ash of SO2 to SO3 from air and oxy-fuel pulverised fuel combustion,” in Conference Proceedings: Impacts of Fuel Quality on Power Production Conference, 26.-31.10.2014, Snowbird, Utah, USA, 2014.
  4. L. Belo et al., “The differences in Sulfur capture behaviour by fly ash between air and oxy-fuel combustion,” in Conference Proceedings: Impacts of Fuel Quality on Power Production Conference, 26.-31.10.2014, Snowbird, Utah, USA, 2014.
  5. L. P. Belo et al., “High-Temperature Conversion of SO2 to SO3: Homogeneous Experiments and Catalytic Effect of Fly Ash from Air and Oxy-fuel Firing,” Energy & Fuels, vol. 28, pp. 7243–7251, DOI: 10.1021/ef5020346, 2014.
  6. L. P. Belo et al., “High-Temperature Conversion of SO2 to SO3: Homogeneous Experiments and Catalytic Effect of Fly Ash from Air and Oxy-fuel Firing,” Energy & Fuels, vol. 28, pp. 7243–7251, DOI: 10.1021/ef5020346, 2014.
  7. L. P. Belo et al., “Sulfur Capture by Fly Ash in Air and Oxy-fuel Pulverized Fuel Combustion,” Energy & Fuels, vol. 28, no. 8, pp. 5472–5479, DOI: 10.1021/ef500855w, 2014.
  8. A. Fuller, J. Maier, and G. Scheffknecht, “Fly ash characteristics and potential utilization in construction applications from wood co-firing and pure combustion in an industrial scale pulverized fuel boiler,” in Conference Proceedings: 39th International Technical Conference on Clean Coal & Fuel Systems 2014, Clearwater, Florida, USA, 1 - 5 June 2014, 2014.
  9. M. Lipiska-Chwaek, G. Stein-Brzozowska, B. Rutkowski, A. Gil, J. Maier, and A. Czyrska-Filemonowicz, “The fireside corrosion of HR6W and Sanicro 25 austenitic alloys,” in Conference Proceedings: 10th Liège Conference on Materials for Advanced Power Engineering, 14.-17.09.2014, Liège, Belgium, 2014.
  10. E. Miller et al., “Research into co-combustion on European level: RECOMBIO, FP7 project,” VGB PowerTech, no. 11, pp. 32–38, 2014.
  11. C. Ndibe, M. Paneru, J. Maier, and G. Scheffknecht, “Experimental study on cofiring high shares of torrified biomass in a 500 kW pulverized coal boiler,” in Conference Proceedings: 10th European Conference on Coal Research and Its Applications, 15.-17.09.2014, Hull, UK, 2014.
  12. C. Ndibe, J. Maier, and G. Scheffknecht, “Experimental investigation of combusiton performance and co-firing characteristics of torrefied biomasses in a pulverized coal furnace,” in Conference Proceedings: 22nd European Biomass Conference and Exhibition, 23 - 26  June 2014, Hamburg, 2014.
  13. C. Ndibe, M. Paneru, J. Maier, and G. Scheffknecht, “Emissions reduction and operational issues during cofiring of high shares of torrified biomass in a 500 kW pulverized coal boiler,” in Conference Proceedings: 4th IEA CCC Workshop on Cofiring Biomass with Coal, 05.-06.11.2014, State College, PA, USA, 2014.
  14. R. Spörl et al., “SO3 emissions and removal by ash in coal-fired oxy-fuel combustion,” Energy & Fuels, vol. 28, no. 8, pp. 5296–5306, DOI: 10.1021/ef500806p, 2014.
  15. R. Spörl et al., “Mercury and SO3 emissions in oxy-fuel combustion,” Energy procedia, vol. 63, pp. 386–402, DOI: 10.1016/j.egypro.2014.11.041, 2014.
  16. R. Spörl et al., “Fly ash and deposit transformations in air and oxy-fuel combustion,” in Conference Proceedings: Impact of Fuel Quality on Power Production, 26-31 October 2014, Snowbird, Utah, USA, 2014.
  17. R. Spörl et al., “Mercury emissions and removal by ash in coal-fired oxy-fuel combustion,” Energy & Fuels, vol. 28, no. 1, pp. 123–135, DOI: 10.1021/ef4014604, 2014.
  18. G. Stein-Brzozowska, R. Norling, P. Viklund, J. Maier, and G. Scheffknecht, “Fireside corrosion during oxyfuel combustion considering various SO2 contents,” Energy procedia, vol. 51, pp. 234–246, DOI: 10.1016/j.egypro.2014.07.027, 2014.

Brennstoffe und Rauchgasreinigung

  1. S. Farr, B. Heidel, M. Hilber, and G. Scheffknecht, “Untersuchungen zur Abscheidung von Schwefeldioxid und Quecksilber in der nassen Rauchgasentschwefelung,” in Fachtagung mit Begleitender Fachausstellung Emissionsminderung 2014, 20.-21.05.2014, Nürnberg, VDI-Berichte 2214, 2014.
  2. B. Heidel, S. Farr, G. Scheffknecht, and M. Hilber, “The behaviour of mercury in dual-loop flue-gas desulphurization systems,” in Conference Proceedings: VGB Workshop Flue Gas Cleaning 2014, 21.-22.05.2014, Marseille, France, 2014.
  3. B. Heidel, B. Klein, K. Raab, and G. Scheffknecht, “Innovative technologies for the decentralized upgrade of biogas,” in Conference Proceedings: Grand Renewable Energy 2014, 27.07.-01.08.2014, Tokyo, Japan, 2014.
  4. B. Heidel, M. Hilber, and G. Scheffknecht, “Impact of additives for enhanced sulfur dioxide removal on re-emissions of mercury in wet flue gas desulfurization,” Applied Energy, vol. 114, pp. 485–491, DOI: 10.1016/j.apenergy.2013.09.059, 2014.
  5. B. Heidel, T. Rogge, and G. Scheffknecht, “Controlled Re-emission of Mercury in Waste Water Treatment,” Energy Procedia, vol. 61, pp. 2307–2310, DOI: 10.1016/j.egypro.2014.11.1190, 2014.
  6. T. Schwämmle, S. Farr, B. Heidel, and G. Scheffknecht, “Mass balance of mercury in air pollution control devices while co-firing biomass at a lab-scale firing system,” VGB PowerTech, no. 3, pp. 57–63, 2014.
  7. O. Seyboth, S. Zimmermann, B. Heidel, and G. Scheffknecht, “Development of a spray scrubbing process for post combustion CO2 capture with amine based solvents,” Energy procedia, vol. 63, pp. 1667–1677, DOI: 10.1016/j.egypro.2014.11.176, 2014.

Feuerungs- und Dampferzeugersimulation

  1. T. G. Baquet, D. Wu, D. Steiner, U. Schnell, and H. Jung, “Mikro-Kraft-Wärme-Kopplungsmodul bestehend aus schadstoffarmem Pelletbrenner und wartungsfreiem Freikolben-Stirlingmotor,” in Schriftenreihe des BMU-Förderprogramms “Energetische Biomassenutzung,” vol. 2, no. 17, D. Thrän, Ed. Leipzig: DBFZ, Deutsches Biomasseforschungszentrum, 2014.

Reinhaltung der Luft

  1. G. Baumbach and O. A. Norena Trigos, “Formaldehydmessung mit FTIR am Abgas eines Biogasmotors - Ergebnisse eines Feldtests,” in Tagungsband: Zweite VDI-Fachtagung „Anlagenbezogenes Monitoring“, 14.-15. Oktober 2014, Karlsruhe. VDI-Berichte 2215, 2014, pp. 279–305.
  2. G. Baumbach et al., “Effects of wood combustion emissions on the air quality in residential areas - measurements and modelling,” in Conference Proceedings: 9th International Conference on Air Quality - Science and Application, 24-28 March 2014, Garmisch-Partenkirchen, 2014.
  3. I. Düring, A. Moldenhauer, U. Vogt, G. Baumbach, D. Straub, and P. Fleischer, “Ermittlung von PM10-Emissionen aus einem Steinbruch,” Gefahrstoffe - Reinhaltung der Luft, no. 1/2, pp. 49–55, 2014.

Dezentrale Energieumwandlung

  1. S. K. Antiohos, H. Dieter, G. Duelli, F. Montagnaro, F. Scala, and D. Fragoulis, “Low embodied carbon cement using Ca-looping purged sorbent in clinker making process,” in Conference Proceedings: 1st Concrete Innovation Conference, 11.-13.06.2014, Oslo, Norway, 2014.
  2. N. Armbrust, A. Bidwe, H. Dieter, and G. Scheffknecht, “Cold model investigation of a triple fluidized bed gasification Process,” in Conference Proceedings: 11th International Conference on Fluidized Bed Technology, 14.-17.05.2014, Beijing, China, 2014.
  3. M. C. Balfe et al., “Model development, validation and transition to CFD simulation - a case study using the example of Alstom’s regenerative calcium cycle,” in Conference Proceedings: 3rd International Conference on Chemical Looping, 09.-11-09.2014, Göteborg, Sweden, 2014.
  4. T. Beisheim, G. Hofbauer, H. Dieter, and G. Scheffknecht, “In-situ desulfurization performance of limestone purge from the calcium looping process during circulating fluidized bed combustion of coal in a 150kWth pilot plant,” in Conference Proceedings: 39th International Technical Conference on Clean Coal & Fuel Systems, June 1 to 5, 2014, Clearwater, Florida, USA, 2014, pp. 284–292.
  5. A. Bidwe, C. Hawthorne, X. Yu, H. Dieter, and G. Scheffknecht, “Cold model study of a dual fluidized bed system for the gasification of solid fuels,” Fuel, vol. 127, pp. 151–160, DOI: 10.1016/j.fuel.2013.12.020, 2014.
  6. A. Bidwe, C. Hawthorne, H. Dieter, A. Dominguez-Mendoza, M. Zieba, and G. Scheffknecht, “Cold model hydrodynamic studies of a 200 kWth dual fluidized bed pilot plant of calcium looping process for CO2 Capture,” Powder technology, vol. 253, pp. 116–128, DOI: 10.1016/j.apenergy.2013.04.056, 2014.
  7. H. Dieter, A. R. Bidwe, G. Varela-Duelli, A. Charitos, C. Hawthorne, and G. Scheffknecht, “Development of the calcium looping CO2 capture technology from lab to pilot scale at IFK, University of Stuttgart,” Fuel, vol. 127, pp. 23–37, DOI: 10.1016/j.fuel.2014.01.063, 2014.
  8. A. Gredinger, D. Schweitzer, H. Dieter, and G. Scheffknecht, “Online tar monitoring via FID - laboratory and pilot plant experiments of an advanced online tar analyzer prototype,” in Conference Proceedings: 22nd European Biomass Conference and Exhibition, 23.-26. Juni 2014, Hamburg, 2014.
  9. G. Hofbauer, T. Beisheim, H. Dieter, and G. Scheffknecht, “Experiences from Oxy-fuel Combustion of Bituminous Coal in a 150 kWth Circulating Fluidized Bed Pilot Facility,” Energy Procedia, vol. 51, pp. 24–30, DOI: 10.1016/j.egypro.2014.07.003, 2014.
  10. F. Mayer, A. Bidwe, A. Schopf, K. Taheri, M. Zieba, and G. Scheffknecht, “Comparison of a new micaceous iron oxide and ilmenite as oxygen carrier for chemical looping combustion with respect to syngas conversion,” Applied energy, vol. 113, January 2014, pp. 1863–1868, DOI: 10.1016/j.apenergy.2013.04.056, 2014.
  11. T. Methling et al., “Power generation based on biomass by combined fermentation and gasification : a new concept derived from experiments and modelling,” Bioresource technology, vol. 169, October 2014, pp. 510–517, DOI: 10.1016/j.biortech.2014.07.036, 2014.
  12. N. Poboss and G. Scheffknecht, “Anlagentechnik zur Energiebereitstellung,” in Leitfaden feste Biobrennstoffe, 4th ed., Gülzow-Prüzen: FNR, 2014.
  13. D. Schweitzer et al., “Dual fluidized bed steam gasification of dried sewage sludge,” in Conference Proceedings: 4th International Symposium on Gasification and its Applications, 05.09.2014, Wien, 2014.
  14. D. Schweitzer, V. A. Stack Lara, A. Gredinger, N. Poboss, H. Dieter, and G. Scheffknecht, “Gasification and combustion of fermentation residues,” in Conference Proceedings: 12th European Gasification Conference 2014, 10.-13.03.2014, Rotterdam, 2014.
  15. D. Schweitzer, N. Poboß, V. Stack-Lara, and H. Dieter, “Brennstoffe aus Biomasse - Teilprojekt III: Verbrennung von Ersatzbrennstoffen,” DVGW energie|wasser-praxis, no. 1, pp. 57–59, 2014.
  16. D. Schweitzer, V. A. Stack-Lara, A. Gredinger, M. Lorenz, H. Dieter, and G. Scheffknecht, “Dual fluidized bed steam gasification of dried sewage sludge,” in Conference Proceedings: 5th International Symposium on Energy from Biomass and Waste, 17.-20.11.2014, Venice, 2014.
  17. S. Steiert, D. Schweitzer, J. Brellochs, M. Specht, N. Armbrust, and H. Dieter, “Brennstoffe aus Biomasse - Teilprojekt IV: Brennstoff-Flexibilisierung AERVergasung,” DVGW energie|wasser-praxis, no. 1, pp. 60–62, 2014.
  18. A. Telesca et al., “Spent limestone sorbent from calcium looping cycle as a raw material for the cement industry,” Fuel, vol. 118, pp. 202–205, DOI: 10.1016/j.fuel.2013.10.060, 2014.
  19. M. Weidmann, S. Grathwohl, H. Dieter, G. Boutin, D. Honoré, and G. Scheffknecht, “Progress in flameless pulverized coal burner design (300 kWth) based on CFD simulations and experimental investigations,” in Conference Proceedings: 39th International Technical Conference on Clean Coal & Fuel Systems 2014, Clearwater, Florida, USA, 1 - 5 June 2014, 2014, pp. 579–586.

Stromerzeugung und Automatisierungstechnik

  1. F. Gutekunst and S. Remppis, “Auswirkungen erhöhter intermittierender Erzeugung auf den stationären und dynamischen Netzbetrieb,” VGB PowerTech, no. 8, pp. 42–46, 2014.
  2. L. Hanel and F. Gutekunst, “Flexibilisierung konventioneller Kraftwerksanlagen durch modellbasierte Steuerung am Beispiel eines Dampfkraftwerks,” in IEEE Power & Energy Student Summit 2014, 22.-24-01.2014, Stuttgart, 2014, pp. 44–48.
  3. L. Hanel, F. Gutekunst, and G. Scheffknecht, “Flexibilisierung des Betriebs von GuD-Anlagen durch flachheitsbasierte Steuerung: Kraftwerkstechnik 2014 - Strategien, Anlagentechnik und Betrieb,” in Tagungsband: 46. Kraftwerkstechnisches Kolloquium, 14.-15.10.2014, Dresden, 2014.
  4. L. Hanel, F. Gutekunst, and G. Scheffknecht, “Improved load tracking performance for combined cycle gas turbine plants through flatness based feedforward control,” in Conference Proceedings: 19th IFAC World Congress, 24.-29.08.2014, Cape Town, South Africa, 2014, pp. 1343–1348.
  5. M. Maurer, F. Gutekunst, and G. Scheffknecht, “Dynamic parameter estimation of inter-area oscillations in a power system by a combination of Kalman-filtering and wavelet transformation techniques,” in Conference Proceedings: 19th IFAC World Congress 2014, 24.-29.08.2014, Cape Town, South Africa, 2014, pp. 8196–8201.
  6. S. Remppis and F. Gutekunst, “Optimierte Betriebsweise von HGÜ-Systemen zur gezielten Entlastung unterlagerter Drehstromnetze am Beispiel einer Schwachlastsituation in Deutschland,” in IEEE Power & Energy Student Summit 2014, 22.-24. Januar 2014, Stuttgart, 2014.
  7. E. Welfonder, “Möglichkeiten einer dualen Energieversorgung nach 2020. Teil 2: Langzeitreserve,” ew, no. 1, pp. 32–39, 2014.
  8. E. Welfonder, “Opportunities for dual energy supply after 2020 even during calm wind conditions and minimal solar radiation,” VGB PowerTech, no. 4, pp. 36–44, 2014.