Trajectory of the triple point of an unsteady shock wave reflection on a straight wall
Abstract
This is a numerical study on the trajectory of the triple point that occurs as a result of the interaction of a shock wave with variable velocity on a straight surface, generating an unsteady reflection process. The cylindrical shock wave is produced from a sudden release of energy. Numerical results are compared with pseudo-stationary theoretical results and experimental data. Simulations
are conducted using the Kurganov, Noelle, and Petrova (KNP) scheme, employing the rhoCentralFoam solver of the OpenFOAM software. A proper correlation of the obtained results with the simulation is observed, achieving a correct description of the process evolution and observing differences in the trajectory when x > 3.5 m.
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