Study of dynamic underwater implosion mechanics using digital image correlation

Gupta, Sachin; Parameswaran, Venkitanarayanan; Sutton, Michael A.; Shukla, Arun

doi:10.1098/rspa.2014.0576

Cited by 52 publications

(20 citation statements)

References 17 publications

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“…Turner and Ambrico identified the key features of a typical mode-2 implosion process by correlating the important signatures of the pressure pulse with the structural deformation [3]. Farhat et al extended this work by comparing both mode-4 and mode-2 implosion, and showed that the higher mode of collapse generates a higher pressure peak but of smaller duration compared to that obtained in a lower mode collapse [13], Recently, Gupta et al uti lized a high speed digital image correlation technique to capture the real-time deformation of the implodable volumes, and showed that the time period and impulse of the positive pressure wave directly correlates to the time taken for the collapse to propagate along the length of the implodable volume [15].…”

Section: Introductionmentioning

confidence: 98%

Implosion of Longitudinally Off-Centered Cylindrical Volumes in a Confining Environment

Gupta

LeBlanc

Shukla

2015

Journal of Applied Mechanics

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A comprehensive experimental!numerical study on the implosion o f longitudinally offcentered cylindrical implodable volumes was conducted within a tubular confining space. In partic ular, the aim o f this study was to examine the changes in the implosion mechan ics and in the nature o f pressure waves, arising from the longitudinally off-centered loca tion o f the implodable volume. Experiments were conducted with 31.8 mm outer diameter, cylindrical aluminum 606I-T6 implodable volumes placed concentrically within the confining tube. Three longitudinal offset locations were chosen within the con fining tube, such that distance from the center o f the implodable volume to the center o f confining tube is equal to: (a) zero, (b) 317 o f the half-length o f confining tube (L), and (c) 5 U7. Pressure transducers mounted on the inner suiface o f the confining tube were used to capture the pressure waves released during the implosion event. Computational simulations were performed using a coupled Eulerian-Lagrangian scheme to explicitly model the implosion process o f the tubes along with the resulting compressible fluid flow. The experiments revealed that the longitudinal asymmetric placement o f the implodable volume enhances the strength o f hammer pressure waves generated during the implosion process. The off-centered location o f the implodable volume causes a pressure imbalance in the entire length o f the confining tube. Hence, the water particle velocity shifts toward the implodable volume producing high pressure region at the end-plate near the implod able volume, while the other end-plate experiences significantly longer cavitation due to low pressure. This fa r end-plate cavitation duration is also found to increase with increasing longitudinal offset, even though the total combined cavitation duration at both the end-plates is approximately same fo r all offset locations. With high correlation observed between the experiments and simulations, computation models were further used to correlate the longitudinal offset and the signature o f pressure waves at various interpolated locations. Simulations show that there is increase in both the peak pressure and the impulse o f the hammer wave with increasing longitudinal offset o f the implodable volume. Simulations also show that the collapse rate o f the implodable volume decreases with the increasing longitudinal offset.

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Section: Introductionmentioning

confidence: 98%

Implosion of Longitudinally Off-Centered Cylindrical Volumes in a Confining Environment

Gupta

LeBlanc

Shukla

2015

Journal of Applied Mechanics

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“…This implosion process is shown to be highly violent in nature with resulting high velocity water motion and strong shock waves [6]. There have been several investigations reported by researchers in naval and marine communities on the mechanics and fluid-structure interaction during an implosion process [2,[7][8][9][10][11][12][13][14][15][16][17][18][19]. Although the evolution of implosion pressure waves and its relation to structure geometry has been widely studied, there is a little information on the interaction of these pressure waves with the adjacent structures and on the potential of damage/sympathetic implosion.…”

Section: Introductionmentioning

confidence: 99%

Sympathetic underwater implosion in a confining environment

Gupta

LeBlanc

Shukla

2015

Extreme Mechanics Letters

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An experimental study is conducted to investigate the phenomenon of sympathetic underwater implosion of cylindrical metallic shells in a confining environment. Two aluminum 6061-T6 implodable volumes with different collapse pressures are placed inside a confining tube with one end open to the environment and are hydrostatically loaded upto the weaker implodable volumes' critical collapse pressure. Experiments show that implosion of the weaker implodable volume (critical pressure = c P ) inside the confining tube leads to the subsequent sympathetic implosion of the stronger implodable volume (critical pressure =1.2 c P ). Implosion of the weaker implodable volume produces strong oscillating water hammer waves with 1.6 c P peak over-pressure, which initiates the implosion of the stronger implodable volume. Pressure histories recorded within the confining tube indicate that the sympathetic implosion of the stronger implodable volume generates low pressure high frequency implosion waves. The superposition of the low pressure waves with the high pressure water hammer waves mitigate to a great extent the later cyclic water hammer loading within the confining tube.

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“…A coarse high contrast random pattern (bullet points of diameter approximately equal to mm) has been painted on a mock target plate such that the transition between black and white area corresponds to approximately four pixels [5]. After calibration, correlation was successful in the ROI 2 . Figure 2 shows the mock target in reference and rotated positions and its shape reconstruction by stereo-correlation.…”

Section: Preliminary Studymentioning

confidence: 99%

“…Deformations are often measured by strain gages [1] but particular attention has been paid recently to 3D digital image correlation (DIC) for HVI or blast [2]- [4] when region of interest (ROI) remains properly visible during test. The main challenge is to find a compromise between measurement accuracy and size of the ROI because of the lower resolution of high speed cameras.…”

Section: Introductionmentioning

confidence: 99%