Nonlinear analysis of laminated composite shells using a micromechanics-based progressive damage model /

Averill, Ronald C.,

January 1992

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1992. / Vita. Abstract. Includes bibliographical references (leaves 165-171). Also available via the Internet.

Shells (Engineering) Laminated materials

Active control of coupled wave propagation in fluid-filled elastic cylindrical shells /

Brévart, Bertrand J.,

January 1994

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1994. / Vita. Abstract. Includes bibliographical references (leaves 202-209). Also available via the Internet.

Elastic waves. Shells (Engineering)

Nonlinear probabilistic finite element modeling of composite shells /

Engelstad, Stephen Phillip,

January 1990

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1990. / Vita. Abstract. Includes bibliographical references (leaves 180-188). Also available via the Internet.

Optimal design of geodesically stiffened composite cylindrical shells /

Gendron, Guy,

January 1991

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1991. / Vita. Abstract. Includes bibliographical references (leaves 169-170). Also available via the Internet.

Buckling of circular cylindrical shell by displacement function

Chang, Ching-kuo,

January 1971

Thesis (Ph. D.)--University of Wisconsin--Madison, 1970. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Shells (Engineering) Buckling

Finite element analysis of geodesically stiffened cylindrical composite shells using a layerwise theory /

Gerhard, Craig Steven,

January 1994

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1994. / Vita. Abstract. Includes bibliographical references (leaves 241-254). Also available via the Internet.

Elementary morphing shells

Loukaides, Evripides George

January 2014

Multistable shells are not yet completely understood. Even under the widespread Uniform Curvature (UC) assumption, the limits of this behaviour have not been established and the influence of individual material and geometric parameters has not been described conclusively; this research explores these open questions. In addition, this project was motivated by the need for practical design guidelines and the pursuit of alternative construction and actuation methods for multistable shells. Our analysis is based on an expression for the strain energy of a shell under a set of simplifying assumptions— primarily the aforementioned UC assumption. We extend this concept beyond the work of previous authors by admitting a more diverse range of anisotropic materials. Furthermore, we take advantage of some aspects of the mathematical field of Catastrophe Theory (CT) to maximise the generality of available results. When appropriate, we examine aspects of our predictions by constructing relevant shell structures, with particular focus on material considerations. A commercial Finite Element Analysis package provides additional means of analysis and comparison. On the theoretical front, the influence of certain control parameters on the availability of multistability is described in closed-form while a unique graphical overview of the limits of this behaviour is provided. In the lab, a novel tristable shell is constructed from a laminate and the use of specialized materials is scrutinised. In a subsequent project, a bistable spherical cap made from a customized material is actuated by a magnetic field—the ensuing snap-through event is recorded with a high-speed camera, leading to valuable insights on the transition geometry. Furthermore, we confirm the possibility of bistability for developable, non-prestressed shells, composed of a single material, using grid shells and thin honeycomb shells.

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Shells (Engineering)

Stiffness matrix solution for folded plates

Payne, Carl Allan

January 1966

A general analysis for a simply supported prismatic folded plate structure is presented. A stiffness matrix method is used with the individual plates taken as structural elements. When loads are applied to the structure the solution yields joint deflections and internal plate forces. The exact elasticity theory is used for the in plane or membrane solution and the classical thin plate theory is used for the out of plane or bending solution. By modifying a computer program used for stiffness matrix frame analysis, it is possible to solve a folded plate structure with more than two plates connected at the same joint. This is demonstrated by the solution of an I beam torsion problem, which also provides a check of existing torsion theories. Cylindrical barrel vaults of circular and other sections are analysed as folded plate structures. A study is made of the effect of the shape of the cross section on the shell stress distribution for long, short, thick and thin shells. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate

Plates (Engineering)

Shells (Engineering)

Analysis of elastic shells of revolution with membrane and flexure stresses under arbitrary loading using trapezoidal finite elements

Agrawal, Krishna Murari

January 1969

Analysis of a general shell of revolution with arbitrary loading and boundary conditions using the Finite Element approach, well-suited for use with the electronic computer, is presented. The shell is approximated by an assemblage of flat, equilateral trapezoids and isosceles triangles connected to each other at the corners. The assumptions involved in transforming a piece of plate into a finite element are defined. Uncoupled plane stress and flexure stiffness matrices for the above-mentioned shapes of the finite elements are derived from considerations of (i) statics, and (ii) virtual work (energy). Statics matrices are asymmetric with the exception of the triangle plane stress stiffness matrix. However, it is important to note that irrespective of the size of the trapezoid element, in conditions of uniform stress the nodal forces satisfy Betti's reciprocal theorem. When a trapezoid reduces to a rectangle, the asymmetry of plane stress and flexure stiffness matrices disappears. Asymmetry of the Statics matrix is removed by averaging the matrix and its transpose. This process corresponds to introducing self-equilibrating nodal forces which disappear in conditions of uniform stress. Suitable direction cosine matrices are derived to transform the displacements and forces from the element coordinate system to the shell coordinate system. The accuracy of the formulation is demonstrated in several examples by comparing the finite element solution with the elasticity solution. The comparison suggests convergence of the results to the correct solution on reduction of the element size. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate

Shells (Engineering)

Strains and stresses

A new eighteen parameter triangular element for general plate and shell analysis

Bearden, Terrance William

January 1976

The purpose of this investigation was to develop an eighteen parameter flat triangular finite element for analyzing plate and shell structures. The development of the element was accomplished by combining a plate bending element with a new plane stress element. The well known nine parameter triangle using the normal displacement and two slopes at each vertex was used for the plate bending element. This element contains an incomplete cubic for the normal displacement. For the in-plane element, complete cubics were used initially for the displacements and then various constraints were imposed to reduce the number of generalized co-ordinates to nine, namely the two in-plane displacements and an in-plane rotation at each vertex. One of the constraints, namely that the included angle at each vertex was invariant, destroyed the completeness of the element. However, the element was compatible in the plane. A patch-type test of the in-plane element showed that it could not represent all constant strain states exactly. However, the errors were small. The complete element was then tested on a plane stress cantilever beam, a square plate subjected to membrane stresses only, a cylindrical shell, a spherical shell and a non-prismatic folded plate structure. In all cases, reasonable engineering accuracy was achieved with modest grids of elements. Thus it was concluded that the incompleteness of the in-plane element was not too important. Finally, a compatible beam element was formulated and tested to supplement the triangular element. The beam element formulation included unsymmetric crosssections. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate

Plates (Engineering)

Shells (Engineering)