Dissipation Elements at the Flame Surface in Methane Diffusion Flame (B. Hentschel and D. Denker)

Flame in Slotburner (S. Kruse)

Particle Charged Flow (E. Varea)

DNS of a scaled-up Diesel injector

Dissipation Element Analysis of Methane Diffusion Flame (D. Denker)

DNS of a scaled-up Diesel injector (M. Bode)

Quartz nozzle sampling in a methane counterflow flame (M. Baroncelli)

Oxyfuel coal combustion in a hot gas stream (D. Felsmann)

Turbulent/non-turbulent interface in high Reynolds number Jet (D. Denker and B. Hentschel)

Fabian Hennig, Dipl.-Ing.

E-Mail:  fhennig(at)itv.rwth-aachen.de

Adresse:
              Institut für Technische Verbrennung
              RWTH Aachen University
              Templergraben 64
              52056 Aachen

Telefon: +49 (0)241 80-94619
Telefax: +49 (0)241 80-92923

Büro:  217 (2. Etage)


Arbeitsgebiete

Forschung: Theoretische Untersuchung und numerische Simulation turbulenter Strömungen

Lehre: Technische Verbrennung II


Publikationen

  • Rubbert, A., Hennig, F., Klaas, M., Pitsch, H., Schröder, W. & Peters, N., Streamline segment scaling behavior in a turbulent wavy channel flow. Experiments in Fluids, 58(2), p.10. 2017.
     
  • Farazi, S., Sadr, M., Kang, S., Schiemann, M., Vorobiev, N., Scherer, V. & Pitsch, H., Resolved simulations of single char particle combustion in a laminar flow field. FUEL, 201, pp.15-28. 2017.
     
  • Boschung, J., Hennig, F., Denker, D., Pitsch, H. & Hill, R.J., Analysis of structure function equations up to the seventh order. Journal of Turbulence, p.1--32. 2017.
     
  • Boschung, J., Gauding, M., Hennig, F., Denker, D. & Pitsch, H., Corrections to the 4/5-law for decaying turbulence. In APS Meeting Abstracts. 2016.
     
  • Denker, D., Boschung, J., Hennig, F. & Pitsch, H., Dissipation Element Analysis of Reacting-and Non-Reacting Flows. In APS Meeting Abstracts. 2016.
     
  • Boschung, J., Gauding, M., Hennig, F., Denker, D. & Pitsch, H., Finite Reynolds number corrections of the 4/5 law for decaying turbulence. Phys. Rev. Fluids, 1(6), p.064403. 2016.
     
  • Hennig, F., Boschung, J. & Peters, N., Statistical Description of Streamline Segments in a Turbulent Channel Flow with a Wavy Wall. New Results in Numerical and Experimental Fluid Mechanics X, pp.135-143. 2016.
     
  • Boschung, J., Hennig, F., Gauding, M., Pitsch, H. & Peters, N., Generalised higher-order Kolmogorov scales. Journal of Fluid Mechanics, 794, pp.233-251. 2016.
     
  • Boschung, J., Gauding, M., Hennig, F., Peters, N. & Pitsch, H., An alternative definition of order dependent dissipation scales, 15th European Turbulence Conference, August 25th-28th, Delft, the Netherlands. 2015.
     
  • Schaefer, P., Gampert, M., Hennig, F. & Peters, N., Geometrical Features of Streamlines and Streamline Segments in Turbulent Flows. In Dillmann, A., Heller, G., Krämer, E., Kreplin, H. -P., Nitsche, W., & Rist, U., eds. New Results in Numerical and Experimental Fluid Mechanics IX. Notes on Numerical Fluid Mechanics and Multidisciplinary Design. pp. 85-92. 2014.
     
  • Boschung, J., Hennig, F. & Peters, N., Local behavior of streamlines in turbulent flows. In APS Meeting Abstracts. 2014.
     
  • Hennig, F., Boschung, J. & Peters, N., Properties of Streamline Segments in Turbulent Channel Flows with Wavy Walls. In APS Meeting Abstracts. 2014.
     
  • Gampert, M., Boschung, J., Hennig, F., Gauding, M. & Peters, N., The vorticity versus the scalar criterion for the detection of the turbulent/non-turbulent interface. Journal of Fluid Mechanics, 750, pp.578-596. 2014.
     
  • Hennig, F., Boschung, J., Gauding, M. & Peters, N., Direct Numerical Simulation of a Temporal Mixing Layer and Detection of the Turbulent/Non-Turbulent Interface. 66th Annual Meeting of the APS Division of Fluid Dynamics, November 24th-26th, Pittsburgh, USA. 2013.
     
  • Boschung, J., Hennig, F. & Peters, N., A Comparison of the Scalar and Vorticity Criterion defining the T/NT Interface. 66th Annual Meeting of the APS Division of Fluid Dynamics, November 24th-26th, Pittsburgh, USA. 2013.
     

Offene Stellen/Arbeiten

Bei Interesse an Projekt-, Bachelor-, Master-, Diplomarbeiten/Hiwistellen anrufen, eine E-Mail schicken oder persönlich vorbeikommen. Abhängig von den Interessen und Vorkenntnissen kann ein individueller Themenvorschlag gemacht werden.