Full-range axisymmetric elasto-plastic large deflection of circular and annular plates under transverse, in-plane and combined loading

Drinali, Hayat

January 1989

No description available.

624.1

Thin-walled structures

Form-finding of thin shell structures

Asmaljee, Zaahir

12 February 2014

The outstanding characteristics of structural efficiency, durability and aesthetic beauty make the thin shell structure a much more viable structural design solution as compared to the more traditional methods of design. However, the manifestation of these outstanding characteristics is directly related to the form of the structure. This makes the form of the structure a key factor in ensuring the success of the design. The correct form of the structure is not known in advance and requires a process known as form-finding or shape-finding. Hence, the focus of this research is to enhance this form-finding process, through the development of a computer design tool that is capable of accurately predicting the form of a pure compression thin shell structure, quickly and easily, in a manner that ensures that the desired characteristics are obtained within the structure. The analyses show that the computer model only corresponded to the shape of the physical chain model in two out of the six cases analyzed. The results suggest that the shapes produced by the computer model corresponded more closely to the shapes produced by the square slabs of yield-line analysis or the physical models developed using the hanging fabric modelling technique. In conclusion, the physical hanging chain models did not provide a correct representation of the shapes produced by the computer model.

Thin-walled structures.

The Optimal Design and Manufacture of Thin-Walled Polystyrene Structures

Unwin, A.P., Ugail, Hassan, Bloor, M.I.G., Wilson, M.J.

January 2005

No

Thin-Walled Structures

Polystyrene

Analysis of thin walled structures in tall buildings

古國紀, Koo, Kwok-kee.

January 1986

published_or_final_version / Civil and Structural Engineering / Doctoral / Doctor of Philosophy

Thin-walled structures.

Tall buildings.

Analysis of thin walled structures in tall buildings /

Koo, Kwok-kee.

January 1986

Thesis (Ph. D.)--University of Hong Kong, 1987.

Thin-walled structures. Tall buildings.

A photoelastic investigation of light-gauge aluminum compression and members in the post-buckling range /

Dellar, Michael, 1951-

January 1980

No description available.

Thin-walled structures.

Structural engineering.

Nonlinear analysis of imperfect, laminated, thin wall cylindrical shells

Shaw, Dein

05 1900

No description available.

Nonlinear mechanics

Thin-walled structures

Capacity assessment of cold-formed wall systems in residential construction /

Pham, Maria Minh-Ha.

Unknown Date

In Australia, the standard structural system for residential construction is brick veneer where the stud wall (whether timber or cold-formed steel) is the load-bearing element and an external skin of brickwork is used for weatherproofing, insulation and aesthetic reasons. The stud wall framed structure has plasterboard interior cladding attached (commonly known as lining), brick-veneer exterior cladding, with terracotta or concrete roof tiles or steel sheet roofing. Therefore, the stud frame is lined on only one side with plasterboard material. This differs from the standard practice used in North America where both sides where both sides of the stud frame are usually lined, one with internal plasterboard material and the other with insulated external cladding material and a brick skin is not used. / Thesis (PhD)--University of South Australia, 2006.

Steel

Thin-walled structures.

Dwellings

A photoelastic investigation of light-gauge aluminum compression and members in the post-buckling range /

Dellar, Michael, 1951-

January 1980

No description available.

Thin-walled structures.

Structural engineering.

Stability of thin-walled metal tubes with elastic uni-lateral internal restraint.

Roufegarinejad, Ali, Civil & Environmental Engineering, Faculty of Engineering, UNSW

January 2007

This thesis presents a theoretical study into the behaviour of thin-walled metal tubes that are filled with elastic material. The study has considered the behaviour and design of concrete-filled steel columns by analysing the effect of the combined actions of axial compression and bending on closed stainless steel cross-sections with a concrete infill as well as the elastic buckling of square, circular and elliptical thin-walled steel tubes, when filled with elastic material. The elastic local buckling of a rectangular plate having four edges clamped and subjected to in-plane linearly varying uniaxial loading with and without juxtaposition with a rigid infill has also been studied. Concrete-filled composite columns find widespread use globally in engineering structures because of their optimal strength and ease of construction. Enhancing the strength of filled columns by utilising newer materials such as stainless steel or shape memory alloys for the skin of the cross-section of the column will increase the construction cost of the column. In order to circumvent this increased construction cost, or to minimise it, the metal skin should be as thin as possible. Members with thin-walled cross-section are prone to lateral torsional buckling, and in particular they are prone to local buckling, with the latter buckling mode playing an important role in the strength of a composite column with a concrete infill. The local buckling coefficient is enhanced by the provision of a rigid concrete infill, and efficient design must make use of this fact to minimise the cost of the skin. The initial portions of this thesis demonstrate the beneficial effects that the rigid concrete core has on the overall strength, and also on the local buckling behaviour of thin-walled metal tubes. The local buckling of the metal skin has been modelled in this thesis by using a Ritz-based energy method. In bi-lateral and uni-lateral buckling studies of rectangular plates, a more general trigonometric function has been selected by application of boundary conditions to the chosen shape function, with these boundary conditions being implemented to make the chosen shape function satisfy the edge conditions for the problem under consideration. The restraining medium is modelled as a tensionless foundation and this restraint condition is introduced through a penalty method formulation. Extensive comparative, convergence, and parametric studies have been carried out by considering a wide range of uni-laterally constrained plates. Following a concise review of the available literature, techniques for analysing the elastic local buckling of thin-walled square tubes, fully filled with elastic materials and subjected to concentric uni-axial compression, are formulated by means of a simple stiffness approach and a proper Ritz-based technique. This method is then extended to account for the local buckling of thin-walled circular and elliptical cylinders with elastic infill. By representation of a proper trigonometric displacement function in the formulation which is capable of incorporating the effects of the penetration zone in a harmonic form, in addition to satisfying all the necessary boundary conditions, it is shown that the buckling solution reduces to a dimensionless representation for which the relevant geometrical and material properties that govern the local buckling coefficient can be identified. It was found that the provision of lightweight and low density infill is functional and attractive with respect to an increase in the efficacy of the restraint. A comparison was made, and good agreement was found to exist, between the results obtained from this study and results that are available in the literature. Finally, a strength to weight index is introduced that quantifies the enhancement in the local buckling coefficient for a number of materials with a wide range of stiffness and density. This index has potential applications for optimal design in aerospace and other specialized engineering applications.

Thin-walled structures.