An analysis of the general instability of eccentrically stiffened complete spherical shells under uniform pressure

Cole, Robert Thurman

08 1900

No description available.

Shells (Engineering) Testing

CRITICAL BUCKLING LOADS FOR FUNICULAR SHELLS

Salmons, John Robert, 1932-

January 1966

No description available.

Shells (Engineering) -- Testing.

Buckling (Mechanics)

DEVELOPMENT OF A LOCAL BUCKLING THEORY FOR UNIFORMLY LOADED SPHERICAL CAPS

Milks, Donald Earle, 1932-

January 1966

No description available.

Buckling (Mechanics)

Shells (Engineering) -- Testing.

High velocity impact of cylindrical shells

Oline, Larry Ward

08 1900

No description available.

Cylinders

Shells (Engineering) Testing

Impact

Free vibration and response to random pressure field of non-uniform cylindrical shells.

Lakis, Aouni A., 1937-

January 1971

No description available.

Elastic plates and shells

Shells (Engineering) -- Testing

An experimental study of impact effects on spherical shells

Simonis, John Charles

12 1900

No description available.

Shells (Engineering) Testing

Strains and stresses

Cylinders testing

An experimental investigation of impact effects on open ended steel cylindrical shells

Passman, Stephen Lee

08 1900

No description available.

Strains and stresses

Shells (Engineering) Testing

Cylinders

Free vibration and response to random pressure field of non-uniform cylindrical shells.

Lakis, Aouni A., 1937-

January 1971

No description available.

Shells (Engineering) -- Testing

Elastic plates and shells

An analytical model of strength loss in filament wound spherical vessels

Leavesley, Peter Joseph

January 1983

The ability to predict potential strength degradation of a filament wound sphere was developed using an incremental finite element model of the composite during fabrication. The sphere was modeled taking into account the winding/loading pattern and the resulting internal layer boundaries. The thickness profile of the sphere's layers were computed using a thickness profile/pattern simulation program. This thickness profile was used by the mesh generating program to ensure that the elements generated did not cross , layer boundaries. The elements used were four noded isoparametric quadrilateral elements and these were collapsed to triangular elements for transitions. The input to the finite element program was prepared by an interface program which combines the mesh generator output with the loading and option control data. The main feature of the finite element program was the incremental construction and loading of the model. Strength degradation definitely occurs when the average fiber layer strain is negative. The negative strain means that all the winding tension has been lost from the layer and the fibers in uncured resin will buckle when they try to support compressive loading. Then when the resin cures the buckled region of fibers are degraded in strength. This model gives a layer-by-layer analysis of the potential strength loss of the composite. / Ph. D.

LD5655.V856 1983.L428

Fibrous composites -- Fatigue

Shells (Engineering) -- Testing

Geometrically nonlinear analysis of layered anisotropic plates and shells

Chao, Wai-Cheng

January 1983

A degenerated three-dimensional finite element based on the total Lagrangian, incremental, formulation of a three-dimensional layered anisotropic medium is developed, and its use in the geometrically nonlinear, static as well as dynamic, analysis of layered composite plates and shells is demonstrated via several example problems. For comparison purposes, a two-dimensional finite element based on the Sanders shell theory with the von Karman (nonlinear) strains is also presented. The elements have the following features: • Geometrically linear and nonlinear analysis • Static and transient analyses • Natural vibration (linear) analyses • Plates and shell elements • Arbitrary loading and boundary conditions • Arbitrary lamination scheme and lamina properties The element can be used, with minor changes, in any existing general purpose programs. The 3-D dimensional degenerated element has computational simplicity over a fully three-dimensional element, and the element accounts for full geometric nonlinearities in contrast to the 2-dimensional elements based on the Sanders shell theory. As demonstrated via numerical examples, the deflections obtained by the 2-D shell element deviate from those obtained by the 3-D element for deep shells. Further, the 3-D element can be used to model general shells that are not necessarily doubly-curved. For example, the twisted plates can not be modeled using the 2-D shell element. Of course, the 3-D degenerated element is computationally more demanding than the 2-D shell theory element for a given problem. In summary, the present 3-D element is an efficient element for the analysis of layered composite plates and shells undergoing large displacements and transient motion. / Ph. D.

LD5655.V856 1983.C526

Plates (Engineering) -- Testing

Shells (Engineering) -- Testing