Analytical reconsideration of the von Neumann paradox in the reflection of a shock wave over a wedge

Vasil'ev, E. I.; Elperin, T.; Ben‐Dor, G.

doi:10.1063/1.2896286

Cited by 29 publications

(34 citation statements)

References 18 publications

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“…The secondary shock polar 5 corresponding to δ i = 10 • intersects the initial shock polar 1 at a point with δ t = δ i + δ r > δ i on the right of the point corresponding to δ t = δ i . It is also known that the interaction of shocks in the latter case has to correspond to an irregular triple-shock configuration of the same type that occurs under the conditions of the von Neumann paradox (see [12,13]). The case δ t = δ i is transitional between the Mach and von Neumann reflections.…”

Section: On Possible Patterns Of Interaction Of the Incident Longitudmentioning

confidence: 99%

“…There are a considerable number of publications on experimental and theoretical studies of the von Neumann paradox in the 2D flows; a detailed review is presented in [13]. Numerical simulations were made to refine theoretical views of this subject in the framework of the ideal gas dynamic model.…”

Section: On Possible Patterns Of Interaction Of the Incident Longitudmentioning

confidence: 99%

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Patterns of steady axisymmetric supersonic compression flows with a Mach disk

Gounko

2016

Shock Waves

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Results of a numerical simulation of steady axisymmetric supersonic flows in convergent conical ducts and in overexpanded jets are presented. The characteristic feature of these compression flows is the formation of an initial longitudinally curved shock wave with intensity increasing downstream and toward the flow axis, which is finalized by the generation of a central Mach disk. Computations have demonstrated patterns of an irregular interaction of these shocks followed by the formation of a triple-shock configuration, including a reflected shock and a shear layer with entropy varying across the layer. The formation of triple-shock configurations is analogous to the configurations known for the steady inviscid two-dimensional flows where the irregular reflection of a wedge-generated shock from a wall with Mach stem formation occurs. Either a single triple-shock Mach configuration occurs or a triple-shock configuration corresponding to the von Neumann paradox condition is formed at the considered flow Mach numbers and initial angles of deflection to the axis of the flow behind the longitudinally curved shock wave.

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Section: On Possible Patterns Of Interaction Of the Incident Longitudmentioning

confidence: 99%

Section: On Possible Patterns Of Interaction Of the Incident Longitudmentioning

confidence: 99%

Patterns of steady axisymmetric supersonic compression flows with a Mach disk

Gounko

2016

Shock Waves

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“…Either the leading-reflected wave is significantly weaker than that or there is a more complicated structure at the triple point that significantly reduces the pressure rise; notably, for the measured trajectory angle the triple-point configuration would be, according to Vasilev et al (2008), a Guderley reflection. The N2.5 case results are shown in table 5.…”

Section: Inflow Photographsmentioning

confidence: 99%

“…Additionally, Vasilev, Elperin & Ben-Dor (2008) have recently provided a detailed analysis of three-and four-wave solutions at the triple point, given the triple-point trajectory and the incident shock Mach number. The fourwave solution structures typically consist of a leading reflected shock followed by an attached expansion fan; this might be expected to result in a lower pressure rise (and a Mach stem/an incident shock kink angle) than a simple reflected shock of the same Mach number.…”

Section: Introductionmentioning

confidence: 99%

Shock focusing in a planar convergent geometry: experiment and simulation

et al. 2009

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The behaviour of an initially planar shock wave propagating into a linearly convergent wedge is investigated experimentally and numerically. In the experiment, a 25• internal wedge is mounted asymmetrically in a pressure-driven shock tube. Shock waves with incident Mach numbers in the ranges of 1.4-1.6 and 2.4-2.6 are generated in nitrogen and carbon dioxide. During each run, the full pressure history is recorded at fourteen locations along the wedge faces and schlieren images are produced. Numerical simulations performed based on the compressible Euler equations are validated against the experiment. The simulations are then used as an additional tool in the investigation.The linearly convergent geometry strengthens the incoming shock repeatedly, as waves reflected from the wedge faces cross the interior of the wedge. This investigation shows that aspects of this structure persist through multiple reflections and influence the nature of the shock-wave focusing. The shock focusing resulting from the distributed reflected waves of the Mach 1.5 case is distinctly different from the stepwise focusing at the higher incoming shock Mach number. Further experiments using CO 2 instead of N 2 elucidate some relevant real-gas effects and suggest that the presence or absence of a weak leading shock on the distributed reflections is not a controlling factor for focusing.

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“…1. The Mach reflection type can be further subdivided into different regimes of reflections which have recently been classified by Semenov et al [22,23] and Vasilev et al [24]. The isentropic exponent γ, the geometry (angle of the wall), and the Mach number of the incident shock M i = D/c 0 uniquely define the problem; the type of reflection is subject to change with any of those variables.…”

Section: Introductionmentioning

confidence: 99%

Non-uniqueness of solutions in asymptotically self-similar shock reflections

Lau-Chapdelaine

Radulescu

2013

Shock Waves

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The present study addresses the self-similar problem of unsteady shock reflection on an inclined wedge. The start-up conditions are studied by modifying the wedge corner and allowing for a finite radius of curvature. It is found that the type of shock reflection observed far from the corner, namely regular or Mach reflection, depends intimately on the start-up condition, as the flow "remembers" how it was started. Substantial differences were found. For example, the type of shock reflection for an incident shock Mach number M = 6.6 and an isentropic exponent γ = 1.2 changes from regular to Mach reflection between 44 • and 45 • when a straight wedge tip is used, while the transition for an initially curved wedge occurs between 57 • and 58 • .

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Analytical reconsideration of the von Neumann paradox in the reflection of a shock wave over a wedge

Cited by 29 publications

References 18 publications

Patterns of steady axisymmetric supersonic compression flows with a Mach disk

Patterns of steady axisymmetric supersonic compression flows with a Mach disk

Shock focusing in a planar convergent geometry: experiment and simulation

Non-uniqueness of solutions in asymptotically self-similar shock reflections

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