Buckling of light-gauge aluminum flexural members

Fabien, Yves.

January 1975

No description available.

Engineering, General.

Buckling (Mechanics)

Thin-walled tubular connections under fatigue loading

Mashiri, Fidelis Rutendo, 1968-

January 2001

Abstract not available

Thin-walled structures -- Fatigue

Tubular steel structures -- Fatigue

Welded joints -- Fatigue

Welded steel structures -- Fatigue

Fracture of ductile polymers

Beh, Henry,1970-

January 2001

Abstract not available

Polymers -- Ductility

Polymers -- Fracture

Polymers -- Fatigue

Thin-walled structures

Deformations (Mechanics)

Studies of a full-scale horizontally curved steel I-girder bridge system under self-weight

Linzell, Daniel Gattner

07 1900

No description available.

Steel I-beams

Steel, Structural

Thin-walled structures

Elasto-plastic torsion of thin-walled members

Desautels, Pierre.

January 1980

No description available.

Thin-walled structures.

Elastoplasticity.

Torsion.

Elastic analysis (Engineering)

Plastic analysis (Engineering)

Crashworthiness modelling of thin-walled composite structures.

Morozov, Konstantin E.

January 2003

This thesis is concerned with the study of the crashworthiness of thin-walled composite structures. Composites are being used more and more in different fields of engineering, particularly, in aerospace and automotive industries because of their high strength-to-weight and stiffness-to-weight ratios, quality and cost advantages. More and more metal parts in cars for instance become or are already replaced by new advanced materials. Composite materials are included in these new advanced materials with the following advantages: weight reduction, corrosion resistance, aesthetics and style, isolation and the ability to integrate several parts into one single structural component. The introduction of new composite structural components (body panels, bumpers, crash absorbers, etc.) requires the development and implementation of new approaches to structural analysis and design. Crashworthiness is one of the foremost goals of aircraft and automotive design. It depends very much on the response of various components which absorb the energy of the crash. In order to design components for crashworthy structures, it is necessary to understand the effects of loading conditions, material behaviour, and structural response. Due to the complexity of the material structure (matrix reinforced with fibres) and specific mechanical properties the nature of transforming the collision kinetic energy into material deformation energy differs from that of conventional metal alloys. The energy absorption mechanics are different for the advanced composites and depend on the material structure (type of reinforcement) and structural design. The primary function of the energy absorption for the composites belongs to the progressive crushing of the materials themselves and structural components (beams, tubes, etc.) made of such materials. Since the mechanics of composite materials and structural components differs substantially from the conventional applications there is a need to develop an appropriate way of modelling and analysis relevant to this problem. Currently there are a large variety of design approaches, test results, and research investigations into the problem under consideration depending on the type of composite material and design geometry of the parts. It has been found that in general an application of fibre reinforced plastics (FRP) to vehicle compartments can satisfy the structural requirements of the passenger compartment including high strength and light weight. Implementation of new advanced composite materials provides the opportunity to develop designs of reliable structural composite parts in high volume for improved automotive fuel economy. Structural optimisation and crashworthiness of composite components should be incorporated into design calculations to control the mechanical performance. The introduction which follows describes the aims of the present study of the crashworthiness modelling and simulation of the structural response of thin-walled composite components which are subjected to various loading conditions relevant to vehicle design. The research programme undertaken within the framework of this project includes development and validation of the modelling and simulation methodology applicable to the crashworthiness analysis of thin-walled composite structures. Development of computerised dynamic modelling of structural components offers the capability of investigating the design parameters without building the actual physical prototypes. In this approach, the dynamic behaviour of the structure is simulated for specified external inputs, and from the corresponding response data the designer is able to determine its dynamic response characteristics, and estimate the crashworthiness of the structure in vehicle engineering applications. / Thesis (Ph.D.)-University of Natal, Durban, 2003.

Composite materials--Testing.

Composite materials--Fracture.

Thin-walled structures--Testing.

Theses--Mechanical engineering.

Determination of wall thickness and height limits when cutting various materials with wire electric discharge machining processes /

Kim, Sangseop,

January 2005

Thesis (M.S.)--Brigham Young University. School of Technology, 2005. / Includes bibliographical references (p. 77-79).

Origami Inspired Design of Thin Walled Tubular Structures for Impact Loading

Shinde, Shantanu R.

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Thin-walled structures find wide applications in the automotive industry as energy absorption devices. A great deal of research has been conducted to design thin-walled structures, where the main objective is to reduce peak crushing forces and increase energy absorption capacity. With the advancement of computers and mathematics, it has been possible to develop 2D patterns which when folded turn into complex 3D structures. This technology can be used to develop patterns for getting structures with desired properties. In this study, square origami tubes with folding pattern (Yoshimura pattern) is designed and studied extensively using numerical analysis. An accurate Finite Element Model (FEM) is developed to conduct the numerical analysis. A parametric study was conducted to study the influence of geometric parameters on the mechanical properties like peak crushing force, mean crushing force, load uniformity and maximum intrusion, when subjected to dynamic loading. The results from this analysis are studied and various conclusions are drawn. It is found that, when the tube is folded with the pattern having specific dimensions, the performance is enhanced significantly, with predictable and stable collapse. It is also found that the stiffness of the module varies with geometrical parameters. With a proper study it is possible to develop origami structures with functionally graded stiffness, the performance of which can be tuned as per requirement, hence, showing promising capabilities as an energy absorption device where progressive collapse from near to end impact end is desired.

Crashworthiness

Non-linear FEM

Origami

Thin-walled Structures

Structures with graded stiffness

Automating Parametric Redesign of Structural Thin-Walled Frames Based On Topology Optimized Structure

Wang, Lyang Suan

January 2019

No description available.

Mechanical Engineering

Elasto-plastic torsion of thin-walled members

Desautels, Pierre.

January 1980

No description available.

Elastoplasticity.

Thin-walled structures.

Torsion.

Elastic analysis (Engineering)

Plastic analysis (Engineering)