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Impact of Scalar Dissipation Rate on Turbulent Spray Combustion Investigated by DNS

  • A. AbdelsamieEmail author
  • D. Thévenin
Conference paper
Part of the ERCOFTAC Series book series (ERCO, volume 25)

Abstract

Spray combustion includes a lot of physical processes that occur simultaneously, most prominently injection, atomization, dispersion, evaporation, and combustion. Therefore, it is not sufficient to rely only on experimental techniques for understanding this problem. As a complementary source of information, highly accurate numerical models can be used to perform such investigations. Using high-performance computers (HPC), even parametric studies become possible.

Notes

Acknowledgements

The computer resources provided by the Gauss Center for Supercomputing/Leibniz Supercomputing Center Munich under grant pro84qo have been essential to obtain the DNS results presented in this work.

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Copyright information

© Springer Nature Switzerland AG 2019

Authors and Affiliations

  1. 1.Laboratory of Fluid Dynamics and Technical Flows (LSS/ISUT)University of Magdeburg “Otto von Guericke”MagdeburgGermany

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