Numerical study on blast flowfields induced by supersonic projectiles discharged from shock tubes

Jiang, Zonglin; Takayama, K.; Skews, B. W.

doi:10.1063/1.869566

Cited by 43 publications

(33 citation statements)

References 5 publications

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“…The same fluid conditions cited in [35] forms in front of the projectile, which interacts with the initial shock from the tube. Eventually, the projectile travels through the shock front that emerged from the tube.…”

Section: D Projectile From a Shock Tubementioning

confidence: 92%

“…We present results for the 2D projectile problem posed by Jiang et al [35]. Here, a square projectile traveling at Mach 4 is ejected from a shock tube.…”

Section: D Projectile From a Shock Tubementioning

confidence: 98%

“…Here, a square projectile traveling at Mach 4 is ejected from a shock tube. The computational domain used here is similar to that used in [35] and is shown in Figure 31. This domain is meshed with 319 000 4-node quadrilateral elements.…”

Section: D Projectile From a Shock Tubementioning

confidence: 99%

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Coupled fluid–solid interaction under shock wave loading

Tipton

Christon

Ingber

2010

Numerical Methods in Fluids

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SUMMARYThis paper considers the treatment of fluid-solid interaction problems under shock wave loading, where the solid experiences large bulk Lagrangian displacements. This work addresses the issues associated with using a level set as a generalized interface for fluid-solid coupling where the fluid-solid interface is embedded in an unstructured fluid grid. We outline the formulation used for the edge-based unstructuredgrid Euler solver. The identification of the fluid-solid interface on the unstructured fluid mesh uses a super-sampled L 2 projection technique, which in conjunction with a Lagrangian interface position, permits fast identification of the interface and the concomitant imposition of boundary conditions. The use of a narrow-band approach for the identification of the wetted interface is presented with the details of the construction of interface conditions. A series of two and three-dimensional shock-body computations are presented to demonstrate the validity of the current approach on problems with static and dynamic interfaces, including projectile/shock interaction simulations.

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Section: D Projectile From a Shock Tubementioning

confidence: 92%

“…We present results for the 2D projectile problem posed by Jiang et al [35]. Here, a square projectile traveling at Mach 4 is ejected from a shock tube.…”

Section: D Projectile From a Shock Tubementioning

confidence: 98%

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Coupled fluid–solid interaction under shock wave loading

Tipton

Christon

Ingber

2010

Numerical Methods in Fluids

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“…The present schlieren photography confirms the previous explanation. The aerodynamics of a supersonic projectile overtaking a gun muzzle blast wave can be seen in the work of Jiang et al (1998).…”

Section: Resultsmentioning

confidence: 99%

Comparison-speed liquid jets

Shi

Satō

2003

Experiments in Fluids

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The performance of a small high-speed liquid jet apparatus is described. Water jets with velocities from 200 to 700 m/s were obtained by firing a deformable lead slug from an air rifle into a stainless steel nozzle containing water sealed with a rubber diaphragm. Nozzle devices using the impact extrusion (IE) and cumulation (CU) methods were designed to generate the jets. The effect of the nozzle diameter and the downstream distance on the jet velocity is examined. The injection sequences are visualized using both shadowgraphy and schlieren photography. The difference between the IE and CU methods of jet generation is found.

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“…These interactions affect the aerodynamic characteristics drastically. The unsteady flow-field of a projectile launch has been studied by many investigators [7][8][9][10][11] . Chand and Panda 12 studied the projectile trajectory using simplified point mass approach which considered only the drag force and the gravity force.…”

Section: Introductionmentioning

confidence: 99%

Flow Around a Conical Nose with Rounded Tail Projectile for Subsonic, Transonic, and Supersonic Flow Regimes : A Numerical Study

Kumar

Panda

Biswal

et al. 2014

DSJ

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Flow around a conical nose with rounded tail projectile has been studied numerically for subsonic, transonic and supersonic flow regimes. The conic angle of the projectile is 10°. The inflow Mach numbers are 0.5, 0.9, and 1.5. Axisymmetric Euler's equations are solved for predicting the drag coefficient. It has been observed that even for a subsonic flow regime, the Mach number distribution is not uniform owing to the non-symmetric shape of the projectile. The predicted drag coefficients for subsonic, transonic, and supersonic cases are 0.018, 0.089, and 0.395, respectively. It was observed that rounded tail is a better option than boat tail so far drag force is concerned.

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Numerical study on blast flowfields induced by supersonic projectiles discharged from shock tubes

Cited by 43 publications

References 5 publications

Coupled fluid–solid interaction under shock wave loading

Coupled fluid–solid interaction under shock wave loading

Comparison-speed liquid jets

Flow Around a Conical Nose with Rounded Tail Projectile for Subsonic, Transonic, and Supersonic Flow Regimes : A Numerical Study

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