Open AccessLarge Deflection Elastic-Plastic Dynamic Response of Stiffened Shells of Revolution
Author(s) -
J. A. Stricklin,
W. E. Haisler,
W.A. von Riesemann
Publication year - 1974
Publication title -
journal of pressure vessel technology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.407
H-Index - 49
eISSN - 0094-9930
pISSN - 1528-8978
DOI - 10.1115/1.3454157
Subject(s) - deflection (physics) , finite element method , conical surface , discretization , structural engineering , hydrostatic pressure , hydrostatic equilibrium , missile , engineering , mechanics , mathematics , physics , mechanical engineering , classical mechanics , mathematical analysis , quantum mechanics , aerospace engineering
This paper presents the formulation and check-out problems for a computer code DYNAPLAS, which analyzes the large deflection elastic-plastic dynamic response of stiffened shells of revolution. The formulation for spacial discretization is by the finite element method with finite differences being used for the evaluation of the pseudo forces due to material and geometric nonlinearities. Time integration is by the Houbolt method or central differences. The stiffeners may be due to concentrated or distributed eccentric rings and spring supports at arbitrary angles around the circumference of the elements. Check-out problems include the comparison of solutions from DYNAPLAS with experimental and other computer solutions for rings and conical and cylindrical shells. A hypothetical submarine including stiffeners and missile tube is studied under a combination of hydrostatic and dynamically applied asymmetrical pressure loadings.
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