An adaptive high-order hybrid scheme for compressive, viscous flows with detailed chemistry

Ziegler, Jack; Deiterding, Ralf; Shepherd, Joseph E.; Pullin, D. I.

doi:10.1016/j.jcp.2011.06.016

Cited by 100 publications

(68 citation statements)

References 65 publications

(109 reference statements)

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“…In comparison, in Fig.4(b) irregular small-scale vortices are clearly visible both along the shear layer and underneath the upper wall. The results in Fig.4(b) are different from those in [17] where Euler equations are solved with a MUSCL-TVD scheme, which is due to the absence of not only physical viscosity in Euler equations but also numerical dissipation involved in the hybrid WENO-CD scheme. Compared with Fig.4(b) a more regular structure of the large-scale vortices can be observed in Fig.4(a).…”

Section: Viscosity Effectsmentioning

confidence: 71%

“…Here, the simplified chemistry model is selected and fitted to physical parameters of a H2/O2 detonation. The details of the governing equations and the thermodynamic parameters of the chemistry model can be found in [17], while the reaction model is discussed in depth in [26]. At the end of the ZND reaction zone, the temperature is about 2500 K and the pressure is about …”

Section: Governing Equationsmentioning

confidence: 99%

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Adaptive simulations of viscous detonations initiated by a hot jet using a high-order hybrid WENO–CD scheme

Cai

Deiterding

Liang

et al. 2017

Proceedings of the Combustion Institute

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Abstract:In the present work a sixth-order hybrid WENO-Centered Difference (CD) scheme with an adaptive mesh refinement method is employed to investigate gaseous detonation by injecting a hot jet into a hydrogen-oxygen combustible mixture flowing at supersonic speed. Two-dimensional reactive NavierStokes (NS) equations with one-step two-species chemistry model are solved numerically. The comparison between viscous and inviscid detonation structures shows that due to the absence of both the physical viscosity in Euler equations and minimization of numerical dissipation in the hybrid WENO-CD scheme, very small-scale vortices can be observed behind the detonation front. The diffusion effect in the NS equations suppresses the small-scale vortices, but it has negligible influence on the large-scale vortices generated by Richtmyer-Meshkov (RM) instability and those along the highly unstable shear layers induced by Kelvin-Helmholtz (KH) instability. When studying the same setup in an expanding channel and beyond the point of detonation initiation, it is found that because of the diffusion effect of detached shear layers, any unburned jet flow is consumed quickly and then additional energy is released periodically. Because of the formation of multiple secondary triple points and subsequent shear layers after the shutdown of the hot jet, a highly turbulent flow is produced behind the detonation front. Rather than the commonly known RM instability, the large-scale vortices involved in the highly unstable shear layers dominate the formation of the turbulent flow and the rapid turbulent mixing between the unburned jet flow and burned product. It is found that the size of unburned jets and vortices due to KH instability is growing for larger expansion angles. The further generated turbulent flow resulting from larger sized vortices, significantly enhances the mixing rate behind the Mach stem, leading to rapid consumption of the unburned reactants. Therefore, detonations propagate faster in channels with larger expansion angle and higher expansion ratio.

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Section: Viscosity Effectsmentioning

confidence: 71%

Section: Governing Equationsmentioning

confidence: 99%

Adaptive simulations of viscous detonations initiated by a hot jet using a high-order hybrid WENO–CD scheme

Cai

Deiterding

Liang

et al. 2017

Proceedings of the Combustion Institute

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“…Numerical approach As in Laurence & Deiterding (2011), we employ the Cartesian fluid solver framework AMROC (Deiterding 2005b;Deiterding et al 2005Deiterding et al , 2007Deiterding 2009Deiterding , 2011aZiegler et al 2011) to simulate numerically the fluid-structure interaction of the free-flying spherical bodies. The equations solved to model the inviscid compressible fluid are the Euler equations in conservation-law form…”

Section: Computational Modellingmentioning

confidence: 99%

Dynamical separation of spherical bodies in supersonic flow

2012

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An experimental and computational investigation of the unsteady separation behaviour of two spheres in Mach-4 flow is carried out. The spherical bodies, initially contiguous, are released with negligible relative velocity and thereafter fly freely according to the aerodynamic forces experienced. In experiments performed in a supersonic Ludwieg tube, nylon spheres are initially suspended in the test section by weak threads which are detached by the arrival of the flow. The subsequent sphere motions and unsteady flow structures are recorded using high-speed (13 kHz) focused shadowgraphy. The qualitative separation behaviour and the final lateral velocity of the smaller sphere are found to vary strongly with both the radius ratio and the initial alignment angle of the two spheres. More disparate radii and initial configurations in which the smaller sphere centre lies downstream of the larger sphere centre each increases the tendency for the smaller sphere to be entrained within the flow region bounded by the bow shock of the larger body, rather than expelled from this region. At a critical angle for a given radius ratio (or a critical radius ratio for a given angle), transition from entrainment to expulsion occurs; at this critical value, the final lateral velocity is close to maximum due to the same 'surfing' effect noted by Laurence & Deiterding (J. Fluid Mech., vol. 676, 2011, pp. 396-431) at hypersonic Mach numbers. A visualization-based tracking algorithm is used to provide quantitative comparisons between the experiments and high-resolution inviscid numerical simulations, with generally favourable agreement.

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“…Based on these ideas above, we conducted a series of numerical simulations on detonation initiation and propagation using a hot jet in supersonic combustible mixtures (Cai et al, 2015a;Liang et al, 2014;Cai et al, 2014;Cai et al, 2015b;Cai et al, 2016a;Cai et al, 2016b) with the open-source program AMROC (Deiterding, 2003;Liang et al, 2007;Deiterding, 2009;Deiterding, 2011;Ziegler et al, 2011) …”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation on Detonation Control Using a Pulse Hot Jet in Supersonic Combustible Mixture

Cai

Liang

Deiterding

2016

Combustion Science and Technology

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Abstract:To investigate the mechanism of detonation control using a pulse hot jet in the supersonic hydrogen-oxygen mixture, high-resolution simulations with a detailed reaction model were conducted using an adaptive mesh refinement method. After the successful detonation initiation, a contractive passway was generated between the hot jet and the main flow field behind the detonation front. Due to the contractive passway, the expansion of detonation products was prevented, hence resulting in overdriven detonation. By setting up various contractive passways through adjusting the width of the hot jet, the overdrive degree of overdriven detonation also changes. It is suggested that the width of the hot jet has approximately linear relation with the relative and absolute propagation velocities. When the contractive passway gradually disappeared after the shutdown of the hot jet, overdriven detonation attenuated to the dynamically stable Chapman-Jouguet (CJ) detonation. When the contractive passway was re-established once again after the re-injection of the hot jet, the CJ detonation developed to the same overdriven detonation, indicating that the contractive passway controlled by the pulse hot jet can indeed control detonation propagation in the A c c e p t e d M a n u s c r i p t 2 supersonic combustible mixture to some extent.

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An adaptive high-order hybrid scheme for compressive, viscous flows with detailed chemistry

Cited by 100 publications

References 65 publications

Adaptive simulations of viscous detonations initiated by a hot jet using a high-order hybrid WENO–CD scheme

Adaptive simulations of viscous detonations initiated by a hot jet using a high-order hybrid WENO–CD scheme

Dynamical separation of spherical bodies in supersonic flow

Numerical Investigation on Detonation Control Using a Pulse Hot Jet in Supersonic Combustible Mixture

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