Dynamics of pulse-loaded circular Föppl-von Kármán thin plates- Analytical and numerical studies

•Large-amplitude elastic vibration of pulse loaded circular thin plates is studied.•Exact solutions were derived for static loading using the Frobenius method.•An approximate MDoF model was developed using the FVK energy functional.•Theoretical results agreed with numerical ones with and without inc...

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Bibliographic Details
Published in:Journal of sound and vibration 2021-11, Vol.513, p.116413, Article 116413
Main Authors: Mehreganian, N., Toolabi, M., Zhuk, Y.A., Etminan Moghadam, F., Louca, L.A., Fallah, A.S.
Format: Article
Language:English
Subjects:
Catastrophic failure analysis
Circular plates
Closed form solutions
closed-form solution
Deformation
Degrees of freedom
Differential equations
Dynamic loads
Elastic deformation
Energy dissipation
Energy storage
Exact solutions
Fluid-structure interaction
Frobenius method
FSI
FVK plate
Materials
Nonlinear response
Perturbation methods
PL perturbation method
Polynomials
pulse loading
Steel
Storage capacity
Tensors
Thin plates
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Summary:•Large-amplitude elastic vibration of pulse loaded circular thin plates is studied.•Exact solutions were derived for static loading using the Frobenius method.•An approximate MDoF model was developed using the FVK energy functional.•Theoretical results agreed with numerical ones with and without inclusion of FSI. Materials such as modern armour steel, benefit from appreciably high elastic energy storage capacity prior to failure. Such a capacity contributes to absorption of the impulse generated during an extreme pulse pressure loading event such as a localised blast. As the plate deforms within the bounds of the elastic region without plastic dissipation, the probability of catastrophic failure is mitigated while large deformations compared to conventional metallic panels are encountered. No studies have proposed, to date, a closed-form solution for nonlinear elastic response of thin circular plates subject to localised pulse loads. The present work aims at deducing, from the minimization of the Föppl-von Kármán (FVK) energy functional, explicit solutions for the response of dynamically (pulse) loaded thin clamped circular plates undergoing large deformations. The solutions were derived from a presumed kinematically admissible displacement field together with an associated stress tensor potential as an infinite polynomial series, which was truncated into a multiplicative decomposition of temporal parts and spatial parts, representative of a Multiple Degrees-of-Freedom (MDOF's) system. In the case of static loading, using the Frobenius method, an exact recursive solution to each mode of defamation was obtained. In the event of dynamic loading, useful expressions for stress tensor components were delineated, corresponding to a multimode multiplicative product, and a series of coupled Ordinary Differential Equations (ODE's) were derived, using the Ritz-Galerkin variational method. The explicit solutions were sought using the Poincaré-Lindstedt (PL) perturbation method. The closed-form solutions obtained were corroborated with FE results including the Fluid-Structure Interaction (FSI) effects and showed convergence when the first few modes were considered. The influence of higher modes, however, on the peak deformation was negligible and the solution with 3 DOF's conveniently estimated the blast response to a satisfactory level of precision. The influence of element type on the response was also examined and discussed in the context of the problem. [Display o
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2021.116413