The optimal design of laminated plates for maximum buckling load using finite element and analytical methods.

Walker, Mark.

January 1994

In the first part of the study, finite element solutions are presented for the optimal design of symmetrically laminated rectangular plates subject to a combination of simply supported, clamped and free boundary conditions. The design objective is the maximisation of the biaxial buckling load by determining the fibre orientations optimally with the effects of bending-twisting coupling taken into account. The finite element method coupled with an optimisation routine is employed in analysing and optimising the laminated plate designs. The effect of boundary conditions, the number of layers and bending-twisting coupling on the optimal ply angles and the buckling load are numerically studied. Optimal buckling designs of symmetrically laminated rectangular plates under in-plane uniaxial loads which have a nonuniform distribution along the edges are presented in the second part of the study. In particular, point loads, partial uniform loads and nonuniform loads are considered in addition to uniformly distributed in-plane loads which provide the benchmark solutions. Poisson's effect is taken into account when in-plane restraints are present along the unloaded edges. Restraints give rise to in-plane loads at unloaded edges which lead to biaxial loading, and may cause premature instability. The laminate behavior with respect to fiber orientation changes significantly in the presence of Poisson's effect as compared to that of a laminate where this effect is neglected. This change in behavior has significant implications for design optimisation as the optimal values of design variables with or without restraints differ substantially. In the present study, the design objective is the maximisation of the uniaxial buckling load by optimally determining the fiber orientations. Numerical results, determined using the finite element method, are given for a number of boundary conditions and for uniformly and non-uniformly distributed buckling loads. In the third part of the study, finite element solutions are presented for the optimal design of symmetrically laminated rectangular plates with central circular cut-outs subject to a combination of simply supported, clamped and free boundary conditions. The design objective is the maximisation of the biaxial buckling load by determining the fiber orientations optimally. The effect of boundary conditions and bending-twisting coupling on the optimal ply angles and the buckling load are numerically studied. The results are compared to those for laminates without holes. The fourth part of the present study gives optimal designs of symmetrically laminated angle-ply plates, which are obtained with the objective of maximising the initial post buckling stiffness. The design involves optimisation over the ply angles and the stacking sequence to obtain the best laminate configuration. The stacking sequence is chosen from amongst five candidate designs. It is shown that the best configuration depends on the ratio of the in-plane loads in the x and y directions. Results are also given for two additional configurations which do not exhibit bending-twisting coupling. The final section of the present study deals with the optimal design of uniaxially loaded laminated plates subject to elastic in-plane restraints along the unloaded edges for a maximum combination of prebuckling stiffness, postbuckling stiffness and buckling load. This multiobjective study illustrates that improved buckling and post buckling performance can be obtained from plates which are designed in this fashion. The multiobjective results are also compared to single objective design results. / Thesis (Ph.D.)-University of Natal, Durban, 1994.

Plates (Engineering)

Laminated materials.

Finite element method.

Theses--Mechanical engineering.

Numerical simulation of transient liquid phase bonding under temperature gradient

Ghobadi Bigvand, Arian

30 July 2013

Transient Liquid Phase bonding under Temperature Gradient (TG-TLP bonding) is a relatively new process of TLP diffusion bonding family for joining difficult-to-weld aerospace materials. Earlier studies have suggested that in contrast to the conventional TLP bonding process, liquid state diffusion drives joint solidification in TG-TLP bonding process. In the present work, a mass conservative numerical model that considers asymmetry in joint solidification is developed using finite element method to properly study the TG-TLP bonding process. The numerical results, which are experimentally verified, show that unlike what has been previously reported, solid state diffusion plays a major role in controlling the solidification behavior during TG-TLP bonding process. The newly developed model provides a vital tool for further elucidation of the TG-TLP bonding process.

Bonding

Simulation

Finite element method

TLP

TG-TLP

Thermo-elastoviscoplastic postbuckling behavior of shell-like structures

Song, Yuzhan

08 1900

No description available.

Shells (Engineering) Plastic properties

Deformations (Mechanics)

Finite element method

Application of finite element techniques in predicting the acoustic properties of turbofan inlets

Kariveerappa, Majjigi Rudramuni

05 1900

No description available.

Finite element method

Acoustical engineering

Airplanes Turbojet engines

Non-classical non-linear effects in thin-walled composite beams

Harursampath, Dineshkumar

12 1900

No description available.

Composite materials

Elasticity

Elasticity analysis (Engineering)

Finite element method

The analysis of numerical dispersion in the finite-element method using nodal and tangential-vector elements

Warren, Gregory S.

05 1900

No description available.

Dispersion

Vector analysis

Finite element method Numerical analysis

Vector finite elements for the solution of Maxwell's equations

Savage, Joe Scott

08 1900

No description available.

Maxwell equations Numerical solutions

Vector analysis

Finite element method

A new scalable parallel finite element approach for contact-impact problems

Har, Jason

05 1900

No description available.

Contact mechanics Mathematics

Surfaces (Technology)

Finite element method

Determination of effective thermal conductivity of media surrounding underground transmission cables

Wood, Sandra Jean

12 1900

No description available.

Underground electric lines

Heat Conduction

Conformal mapping

Finite element method

Parallel methods for high-performance finite element methods based on sparsity

Chuang, Shih-Chang

08 1900

No description available.

Finite element method

Engineering mathematics