|![[Search]](https://talks.cam.ac.uk/images/search.gif?1209136071)
|![[A-Z Index]](https://talks.cam.ac.uk/images/az.gif?1209136071)
|![[Contact]](https://talks.cam.ac.uk/images/contact.gif?1209136071)
||![[University of Cambridge]](https://talks.cam.ac.uk/images/identifier2.gif?1209136071){kind=small} |
COOKIES: By using this website you agree that we can place Google Analytics Cookies on your device for performance monitoring. | ![[Talks.cam]](https://talks.cam.ac.uk/images/talkslogosmall.gif?1209136071) |
University of Cambridge > Talks.cam > Engineering - Mechanics and Materials Seminar Series > On energy and momentum transfer to fully clamped flexible structures in underwater explosions and air blast
On energy and momentum transfer to fully clamped flexible structures in underwater explosions and air blastAdd to your list(s) Download to your calendar using vCal
If you have a question about this talk, please contact Ms Helen Gardner. This talk has been canceled/deleted The momentum transfer by a planar wave impinging upon a rigid, freestanding plate in water, a largely incompressible medium, is well understood [1]. Kambouchev et al. [2] extended the results of Taylor [1] to include the nonlinear effects of compressibility whilst Hutchinson [3] has addressed the issues of energy and momentum transfer to a rigid, freestanding plate. In this presentation, key conclusions from the aforementioned studies will be critically re-examined in the context of a flexible, `fully-clamped’ elasto-plastic beam both under water and in air. The dynamic response of the elasto-plastic beam will be modelled as an equivalent single-degree-of-freedom (SDOF) system. A numerical method based on a Lagrangian formulation of the Euler equations of compressible flow and conventional shock-capturing techniques, similar to that employed in [2, 3], are employed to solve numerically the interaction between the blast wave and beam. Particular emphasis will be placed on elucidating the energy and momentum transferred to the structure compared to its rigid, freestanding counterpart, and on whether enhancement in the beneficial effects of FSI remains, with or without fluid compressibility, and to what extent. References [1] G. I. Taylor, in: The pressure and impulse of submarine explosion waves on plates, edited by G.K. Batchelor, Vol.3 of The Scientific Papers of Sir Geoffrey Ingram Taylor, Cambridge University Press, Cambridge (1963) 287–303. [2] N. Kambouchev, L. Noels, R. Radovitzky, Nonlinear compressibility effects in fluid-structure interaction and their implications on the air-blast loading of structures, J. Appl. Phys. 100 (2006) 063519. [3] J. W. Hutchinson, Energy and momentum transfer in air shocks, ASME J . Appl. Mech. 76 (5) (2009) 051307. This talk is part of the Engineering - Mechanics and Materials Seminar Series series. This talk is included in these lists:This talk is not included in any other list Note that ex-directory lists are not shown. |
Other listsNeurons, Brains and Behaviour symposium Type the title of a new list here Asian Archaeology Group Cambridge University Expeditions Society Seminars at the Department of Biochemistry AlexOther talksProtein Folding, Evolution and Interactions Symposium On the climate change conversation A stochastic model for understanding PIN polarity in isolated cells Propagation of Very Low Frequency Emissions from Lightning Animal Migration Unbiased Estimation of the Eigenvalues of Large Implicit Matrices An approach to the four colour theorem via Donaldson- Floer theory Investigating the Functional Anatomy of Motion Processing Pathways in the Human Brain Direct measurements of dynamic granular compaction at the mesoscale using synchrotron X-ray radiography Chemical convection and stratification at the top of the Earth's outer core |
Dr P J Tan, University College London
Friday 29 November 2013, 14:00-15:00