Underwater explosion in centrifuge Part II: Dynamic responses of defensive steel plate

Rajendran R, Narasimhan K. Linear elastic shock response of plane plates subjected to underwater explosion. Int J Impact Eng, 2001, 25: 493–506

Rajendran R, Narasimhan K. Damage prediction of clamped circular plates subjected to contact underwater explosion. Int J Impact Eng, 2001, 25: 373–386

Rajendran R. Effective shock factors for the inelastic damage prediction of clamped plane plates subjected to non-contact underwater explosion. J Strain Anal Eng Des, 2009, 44: 211–220

Ramajeyathilagam K, Vendhan C P. Deformation and rupture of thin rectangular plates subjected to underwater shock. Int J Impact Eng, 2004, 30: 699–719

Taylor G I. The pressure and impulse of submarine explosion waves on plates. In: The Scientific Papers of Sir Geoffrey Ingram Taylor, Vol 3. New York: Cambridge University Press, 1963. 287–303

Anderson J. Fundamentals of Aerodynamics. New York: McGraw-Hill, 2001

Ghoshal R, Mitra N. Non-contact near-field underwater explosion in-duced shock-wave loading of submerged rigid structures: Nonlinear compressibility effects in fluid structure interaction. J Appl Phys, 2012, 112: 024911–024911

Huang H. Transient bending of a large elastic plate by an incident spherical pressure wave. J Appl Mech, 1974, 41: 772

Jiang J, Olson M D. Rigid-plastic analysis of underwater blast loaded stiffened plates. Int J Mech Sci, 1995, 37: 843–859

Vernon T A. Whipping response of ship hulls from underwater explosion bubble loading. DTIC Document, 1986

Geers T L, Hunter K S. An integrated wave-effects model for an underwater explosion bubble. J Acoust Soc Am, 2002, 111: 1584–1601

Zhang X, Li Y, Zhao B. Pressure field and dynamic effect of ship structure produced by underwater shock and explosion bubble (in Chinese). Shipbuild China, 1997, 4: 61–68

Zong Z. Dynamic plastic response of a submerged free-free beam to an underwater gas bubble. Acta Mech, 2003, 161: 179–194

Yao X L, Chen J P, Ren H L. The analysis of dynamic response of ship hull subjected to gas bubble impulsive pressure of underwater explosions (in Chinese). J Harbin Eng Univ, 2000, 21: 1–5

Yao X L, Chen J. A study on anti-underwater-explosion performance of ship subjected to gas bubble impulsive pressure (in Chinese). Shipbuild China, 2001, 42: 48–55

Chen J, Liu X, Xu Q. Numerical simulation analysis of damage mode of concrete gravity dam under close-in explosion. KSCE J Civ Eng, 2017, 21: 397–407

Yu T T. Dynamical response simulation of concrete dam subjected to under water contact explosion load. In: 2009 World Congress on Computer Science and Information Engineering. Los Angeles, 2009. 767–774

Zhu F, Zhu W, Zhu X X, et al. Numerical simulation of arch dam withstand underwater explosion. In: 2012 Proceedings of International Conference on Modelling, Identification & Control (ICMIC). IEEE, 2012. 1034–1039

Zhang S, Wang G, Wang C, et al. Numerical simulation of failure modes of concrete gravity dams subjected to underwater explosion. Eng Failure Anal, 2014, 36: 49–64

Wang G, Zhang S, Kong Y, et al. Comparative study of the dynamic response of concrete gravity dams subjected to underwater and air explosions. J Perform Constr Facil, 2014, 29: 04014092

Wang G, Zhang S. Damage prediction of concrete gravity dams subjected to underwater explosion shock loading. Eng Failure Anal, 2014, 39: 72–91

Lu L, Li X, Zhou J. Study of damage to a high concrete dam subjected to underwater shock waves. Earthq Eng Eng Vib, 2014, 13: 337–346

Lu L, Li X, Zhou J, et al. Numerical simulation of shock response and dynamic fracture of a concrete dam subjected to impact load. Earth Sci Res J, 2016, 20: 1–6

Lu L, Kong X, Dong Y, et al. Similarity relationship for brittle failure dynamic model experiment and its application to a concrete dam subjected to explosive load. Int J Geomech, 2017, 17: 04017027

Vanadit-Ellis W, Davis L K. Physical modeling of concrete gravity dam vulnerability to explosions. In: 2010 International Waterside Security Conference (WSS). IEEE, 2010. 1–11

Song G, Chen Z Y, Long Y, et al. Experimental and numerical investigation of the centrifugal model for underwater explosion shock wave and bubble pulsation. Ocean Eng, 2017, 142: 523–531

Brandt A. Noise and Vibration Analysis: Signal Analysis and Experimental Procedures. Chichester: John Wiley & Sons, Ltd, 2011

Niu J, Shi Y, Cai M, et al. Detection of sputum by interpreting the time-frequency distribution of respiratory sound signal using image processing techniques. Bioinformatics, 2017

Li Z, Escoffier S, Kotronis P. Using centrifuge tests data to identify the dynamic soil properties: Application to Fontainebleau sand. Soil Dyn Earthq Eng, 2013, 52: 77–87

Chopra A K. Dynamics of Structures. New Jersey: Prentice Hall, 1995

Hallquist J O. LS-DYNA3D theoretical manual. Livermore: Livermore Software Technology Corporation, 1993

Stenberg D J. Spherical explosions and the equation of state of water, UCID-2097. Livermore: Lawrence Livermore National Laboratory, 1987

Li X J, Zhang C J, Wang X H, et al. Numerical study on the effect of equations of state of water on underwater explosions (in Chinese). Eng Mech, 2014, 31: 46–52

Lee E, Finger M, Collins W. JWL equation of state coefficients for high explosives. Rept-UCID-16189, Lawrence Livermore National Laboratory, 1973

Cole R H. Underwater Explosions. New Jersey: Princeton University Press, 1948