Engineering Conferences International ECI Digital Archives BioEnergy IV: Innovations in Biomass Conversion for Heat, Power, Fuels and Chemicals Proceedings Spring 6-11-2013 External superheating in biomass power plants with pebble bed regenerators Robert Daschner Fraunhofer UMSICHT Follow this and additional works at: http://dc.engconfintl.org/bioenergy_iv Part of the Chemical Engineering Commons Recommended Citation Robert Daschner, "External superheating in biomass power plants with pebble bed regenerators" in "BioEnergy IV: Innovations in Biomass Conversion for Heat, Power, Fuels and Chemicals", Manuel Garcia-Perez,Washington State University, USA Dietrich Meier, Thünen Institute of Wood Research, Germany Raffaella Ocone, Heriot-Watt University, United Kingdom Paul de Wild, Biomass & Energy Efficiency, ECN, The Netherlands Eds, ECI Symposium Series, (2013). http://dc.engconfintl.org/bioenergy_iv/23 This Conference Proceeding is brought to you for free and open access by the Proceedings at ECI Digital Archives. It has been accepted for inclusion in BioEnergy IV: Innovations in Biomass Conversion for Heat, Power, Fuels and Chemicals by an authorized administrator of ECI Digital Archives. For more information, please contact franco@bepress.com.
BioEnergy IV 11 June 2013 Otranto, Italy EXTERNAL SUPERHEATING IN BIOMASS POWER PLANTS WITH PEBBLE BED REGENERATOR Robert Daschner Fraunhofer UMSICHT
OUTLINE 1. Background 2. Principle 3. Pebble Bed Regenerator 4. Thermodynamic Model 5. Results 6. Conclusion and Outlook Fraunhofer
Our motivation Energy conversion and storage Raw- and functional materials Folie 3
External Superheating in Biomass Power Plants Background Biomass power plant Folie 4 Image Sources: www.bildarchiv-hamburg.de, www.muellverbrennung-delitzsch-nein.de
External Superheating in Biomass Power Plants Background Feedstock Feedstock Considered fuels: biomass (except wood), domestic waste, sewage sludge, RDF Limited efficiency due to corrosion High temperature chloride corrosion: Limited steam parameters of ca. 450 C at 50-70 bars (Biomass) ca. 400 C at 40 bar (WtE) Still high costs for maintenance due to corrosion effects Boiler Flue gas Folie 5
External Superheating in Biomass Power Plants Principle Diversion of hot flue gas out of the boiler (ca. 700 800 C) Regenerative heat transfer to ambient air Superheating of steam with the generated hot air Reduction of corrosion problematic in the air/steam superheater Pebble- Heater Increase in electrical efficiency and flexibility Folie 6
Pebble Bed Regenerator Pebble-Heater Set-Up Flue gas outlet / Air inlet Outer grid / Cold grid Bulk material / Pebble bed Inner grid / Hot grid Flue gas inlet / Air outlet Bulk material outlet Folie 7 Quelle: ATZ
Pebble Bed Regenerator Pebble-Heater Functionality Cooled down Flue gas Hot Flue gas Folie 8 Quelle: ATZ
Pebble Bed Regenerator Pebble-Heater Functionality Ambient air Cooled down Flue gas Hot, clean air Hot Flue gas Folie 9 Quelle: ATZ
Pebble Bed Regenerator Pebble-Heater Bulk Materials Overview Alumina Oxide Diabase Vulcanic rock Basalt Folie 10 Quelle: ATZ
Bulk density [kg m -3 ], Heat capacity [kj (kg*k) -1 ] Cost / Volume [ m -3 ], Cost / Weigth [ Mg -1 ] ~ 6.300 ~ 2.700 Pebble Bed Regenerator Pebble-Heater Bulk Materials Physical conditions and prices 2.500 2.000 1.500 1.000 500 0 Bulk density [kg m -3 ] Heat capacity [kj (kg*k) -1 ] Cost/Volume [ m -3 ] Cost/Weigth [ Mg -1 ] Al 2 O 3 Vulcanic Rock Basalt Diabas 100 90 80 70 60 50 40 30 20 10 0 Folie 11
Temperatur [K] Thermodynamic Model Goals of thermodynamic simulation Thermodynamic dimensioning of the process Design for superheater Turbine characterisation due to changed steam parameters 900 800 700 600 500 400 300 Increase of energy efficiency due to higher steam parameters 200-1 0 1 2 3 4 5 6 7 8 9 10 11 Spezifische Entropie [kj/kg*k] -1 Folie 12
Thermodynamic Model Implementation in Matlab Simulink Folie 13 Quelle: ATZ
Thermodynamic Model Implementation in Matlab Simulink Folie 14 Quelle: ATZ
Furnace Steam generator Feed water preheating Superheater Folie 15 Turbine Quelle: ATZ
Results of Thermodynamic Simulation Temperature Profile at Various Procedural Steps Folie 16
Results of Thermodynamic Simulation Overall Efficiency Folie 17
Use of Pebble-Heater in Integrated System Outlook Folie 18
Use of Pebble-Heater in Integrated System Outlook Char Oil Pyrolysis & Reforming Storage Gas Biogas plant CHP Pellets Digestate Heat Power Folie 19
Use of Pebble-Heater in Integrated System Outlook Pebble-Heater Char Oil Pyrolysis & Reforming Storage Gas Biogas plant CHP Pellets Digestate Heat Power Folie 20
External Superheating in Biomass Power Plants Conclusion Matlab model for simulation of different types of power plants different operation modes Verified in experimental test rigs η Increase in electrical efficiency Pebble-Heater usable as Heat Storage in integrated energy systems Folie 21
External Superheating in Biomass Power Plants with Pebble Bed Regenerator Thank you for your kind attention Contact Fraunhofer UMSICHT Fraunhofer-Instituts für Umwelt-, Sicherheitsund Energietechnik UMSICHT Instite Branch Sulzbach-Rosenberg An der Maxhütte 1 D-92237 Sulzbach-Rosenberg / Germany Samir Binder E-Mail: info-suro@umsicht.fraunhofer.de Tel.: 09661-908 410 Internet: http://www.umsicht-suro.fraunhofer.de E-Mail: samir.binder@umsicht.fraunhofer.de