Numerical Investigation of Fluid-Ablation Interactions in a Mach 5.3 Boundary Layer
ORAL
Abstract
Performing fully-coupled simulations of a transitional boundary layer flowing over an ablative
material is still a difficult task. Most ablation problems of interest evolve over a time scale
of O(10) seconds. With explicit time integration, a tractable direct numerical simulation
(DNS) solution of the fluid can be obtained for only O(10−3) seconds of physical time. This
work attempts to use tight coupling between the two sets of physics in order to simulate
boundary layer transition to turbulence over an ablating flat plate. Of chief interest is the
concurrent influences of unsteady fluid motion on the material response and the material
response on the unsteady fluid motion. Also to be investigated is the legitimacy of various
techniques to maintain tight solver couplings while accelerating the ablation process.
This work has been funded by a CAREER grant by the National Science Foundation under
award CBET-2146100 with Dr. R. Joslin as Program Manager. The authors would also
like to thank Dr. J. McQuaid and Dr. A. Zibitsker for their development of the fluid and
material response codes used in this work, respectively.
material is still a difficult task. Most ablation problems of interest evolve over a time scale
of O(10) seconds. With explicit time integration, a tractable direct numerical simulation
(DNS) solution of the fluid can be obtained for only O(10−3) seconds of physical time. This
work attempts to use tight coupling between the two sets of physics in order to simulate
boundary layer transition to turbulence over an ablating flat plate. Of chief interest is the
concurrent influences of unsteady fluid motion on the material response and the material
response on the unsteady fluid motion. Also to be investigated is the legitimacy of various
techniques to maintain tight solver couplings while accelerating the ablation process.
This work has been funded by a CAREER grant by the National Science Foundation under
award CBET-2146100 with Dr. R. Joslin as Program Manager. The authors would also
like to thank Dr. J. McQuaid and Dr. A. Zibitsker for their development of the fluid and
material response codes used in this work, respectively.
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Presenters
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Sean D Dungan, MS
University of Maryland, College Park, University of Maryland College Park
Authors
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Sean D Dungan, MS
University of Maryland, College Park, University of Maryland College Park
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Christoph Brehm
University of Maryland College Park, University of Maryland