Maximilian Dammann

  • Engler-Bunte-Institut, EBI ceb
    Chemische Energieträger – Brennstofftechnologie

    Engler-Bunte-Ring 1
    76131 Karlsruhe

Numerical Modelling and Simulation of High Temperature Processes

Temperatur- und Strömungsverteilung in bioliq EFG Maximilian Dammann, M.Sc.
Temperature and flow field distribution in bioliq EFG
Validierung der numerischen Ergebnisse mit experimentellen Ergebnissen Maximilian Dammann, M.Sc.
Temperature and dry volume distribution in REGA at a burner distance of 680 mm and for two operating conditions including validation of two developed global reaction mechanisms for the gasification of ethylene glycol (HVI1 and eJL)

The Research on numerical modelling and simulation has become an important element for developing of validated models and for the design and the scale-up of reactors. In collaboration with the Institute for Technical Chemistry (ITC vgt) at Karlsruhe Institute for Technology and the Institute for Energy Process Engineering and Fuel Technology (IEVB) at Clausthal University of Technology, in particular, we are investigating and improving the description of sub-processes in entrained flow gasification :

  • vaporisation of liquid biomass fuels,
  • decomposition and heterogeneous gasification of both liquid and solid biomass fuels,
  • homogeneous gasification,
  • radiation,
  • slagging.

Using numerical models of an atmospheric entrained flow gasifier (REGA) and of a high-pressurised entrained flow gasifier (bioliq EFG), we are testing and validating new models for entrained flow gasification of biomass fuels.

Research topics

  • Numerical modelling and simulation of gasification processes in entrained flow gasifiers
  • Numerical modelling and simulation of steady-state and transient slagging
  • Numerical modelling and simulation of radiation using LBL, WSGGM and Mie theory
  • Numerical modelling and simulation of heterogeneous gasification reactions
  • Numerical modelling and simulation of combustion processes in high pressure combustion chambers using hydrogen
Open final theses
type title time

Publications


Entrained flow gasification: Pilot-scale experimental, balancing and equilibrium data for model validation
Dammann, M.; Santo, U.; Böning, D.; Knoch, H.; Eberhard, M.; Kolb, T.
2024. Fuel. doi:10.1016/j.fuel.2024.132809
Entrained flow gasification: Experiments and mathematical modelling based on RANS
Dammann, M.; Mancini, M.; Fleck, S.; Weber, R.; Kolb, T.
2018, May. Joint Meeting of the German and Italian Sections of the Combustion Institute (2018), Sorrento, Italy, May 23–26, 2018
Devolatilisation of beech wood char: Kinetics from thermogravimetric analyses and drop-tube reactor experiments
Dammann, M.; Walker, S. C.; Mancini, M.; Kolb, T.
2024. Fuel, 375, Art.-Nr.: 131967. doi:10.1016/j.fuel.2024.131967
Thermal radiation at high-temperature and high-pressure conditions: Validation of HITEMP-2010 for carbon dioxide
Dammann, M.; Weber, R.; Fateev, A.; Clausen, S.; Alberti, M.; Kolb, T.; Mancini, M.
2024. Journal of Quantitative Spectroscopy and Radiative Transfer, 329, 109121. doi:10.1016/j.jqsrt.2024.109121
Numerical modelling and simulation of atmospheric entrained flow gasification of surrogate fuels. PhD dissertation
Dammann, M.
2024, October 8. Karlsruher Institut für Technologie (KIT). doi:10.5445/IR/1000172116
Thermal radiation at high-temperature and high-pressure conditions: Comparison of models for design and scale-up of entrained flow gasification processes
Dammann, M.; Mancini, M.; Kolb, T.; Weber, R.
2023. Thermal Science and Engineering Progress, 42, Art.-Nr.: 101772. doi:10.1016/j.tsep.2023.101772
Entrained flow gasification: Impact of fuel spray distribution on reaction zone structure
Haas, M.; Dammann, M.; Fleck, S.; Kolb, T.
2023. Fuel, 334 (2), Art.-Nr.: 126572. doi:10.1016/j.fuel.2022.126572
Entrained flow gasification: Experiments and mathematical modelling based on RANS
Dammann, M.; Mancini, M.; Fleck, S.; Weber, R.; Kolb, T.
2019, September. 29. Deutscher Flammentag (2019), Bochum, Germany, September 17–18, 2019
Thermal radiation at high-temperature and high-pressure conditions: Comparison of models for design and scale-up of entrained flow gasification processes
Dammann, M.; Mancini, M.; Kolb, T.; Weber, R.
2022, April. 13th European Conference on Industrial Furnaces and Boilers (INFUB 2022), Albufeira, Portugal, April 19–22, 2022
Thermal radiation at high-temperature and high-pressure conditions: Comparison of models for design and scale-up of entrained flow gasification processes
Dammann, M.; Mancini, M.; Kolb, T.; Weber, R.
2022. Conference proceedings der 13. European Conference on Industrial Furnaces and Boilers (INFUB-13), 19.04.2022-22.04.2022, Algarve, Portugal, Centro de Energia e Tecnologia (CENERTEC)
Entrained flow gasification: Mathematical modelling based on RANS for design and scale-up
Dammann, M.; Mancini, M.; Weber, R.; Kolb, T.
2021. Conference proceedings des 30. Deutschen Flammentag (2021), 28.09.2021 – 29.09.2021, Hannover, Deutschland, Deutsche Vereinigung für Verbrennungsforschung e.V
Entrained flow gasification: Mathematical modelling based on RANS for design and scale-up
Dammann, M.; Mancini, M.; Weber, R.; Kolb, T.
2021, September. 30. Deutscher Flammentag (2021), Hanover, Germany, September 28–29, 2021
Entrained flow gasification: Experiments and mathematical modelling based on RANS
Dammann, M.; Mancini, M.; Fleck, S.; Weber, R.; Kolb, T.
2019. Conference proceedings des 29. Deutschen Flammentag (2019), 17.09.2019 – 18.09.2019, Bochum, Deutschland
Entrained flow gasification: Experiments and mathematical modelling based on RANS
Dammann, M.; Mancini, M.; Fleck, S.; Weber, R.; Kolb, T.
2018. Conference proceedings of the Joint Meeting of The German and Italian Sections of The Combustion Institute - 41st Meeting of the Italian Section of the Combustion Institute
Entrained flow gasification. Part 2: Mathematical modeling of the gasifier using RANS method
Mancini, M.; Alberti, M.; Dammann, M.; Santo, U.; Eckel, G.; Kolb, T.; Weber, R.
2018. Fuel, 225, 596–611. doi:10.1016/j.fuel.2018.03.100