Experimental studies of elliptical concrete-filled tube columns

Jamaluddin, N., Lam, Dennis, Ye, J.

January 2010

No

Elliptical

Concrete-filled tube columns

Finite element analysis on the capacity of circular concrete-filled double-skin steel tubular (CFDST) stub columns

Pagoulatou, M., Sheehan, Therese, Dai, Xianghe, Lam, Dennis

09 May 2014

Yes / This paper presents the behaviour of circular concrete-filled double-skin steel tubular (CFDST) stub columns compressed under concentric axial loads. To predict the performance of such columns, a finite element analysis is conducted. Herein, for the accurate modelling of the double-skin specimens, the identification of suitable material properties for both the concrete infill and steel tubes is crucial. The applied methodology is validated through comparisons of the results obtained from the finite element analysis with those from past experiments. Aiming to examine the effect of various diameter-to-thickness (D/t) ratios, concrete cube strengths and steel yield strengths on the overall behaviour and ultimate resistance of the double-skin columns, a total of twenty-five models are created to conduct the parametric study. In addition, four circular concrete-filled steel tubes (CFST) are included to check the dissimilarities, in terms of their behaviour and weight, when compared with identical double-skin tubes. A new formula based on Eurocode 4 is proposed to evaluate the strength of the double-skin specimens. Based on the comparison between the results derived from the analysis, the proposed formulae for the concrete filled double-skin would appear to be satisfactory.

Buckling behaviour of concrete-filled elliptical steel columns

Lam, Dennis, Jamaluddin, N., Ye, J., Dai, Xianghe

January 2011

No / This paper presents the buckling behaviour and design of axially loaded concrete filled steel elliptical hollow sections. The experimental investigation was conducted using normal and high strength concrete of 30, 60 and 100 MPa. The current study includes both the stub and slender column tests. Based on the existing design guidance in Eurocode 4 for composite columns, the proposed design equations were found to provide an accurate and consistent prediction of the cross section and buckling capacity of the composite concrete filled steel elliptical hollow sections in axial compression.

Buckling

Concrete-filled columns

Steel columns

Elliptical

Fire performance of unprotected and protected concrete filled steel hollow structural sections

Rush, David Ian

January 2013

Concrete filled steel hollow structural (CFS) sections are increasingly used to support large compressive loads in buildings, with the concrete infill and the steel tube working together to yield several benefits both at ambient temperature and during a fire. These members are now widely applied in the design of highly optimized multi-storey and high rise buildings where fire resistance ratings of two or more hours may be required. Whilst the response and design of these sections at ambient temperatures is reasonably well understood, their response in fire, and thus their fire resistance design, is less well established. Structural fire resistance design guidance is available but has been developed based on tests of predominantly short, concentrically-loaded, small-diameter columns in braced frames using normal strength concrete. The current prescriptive guidance is limited and the design of CFS columns is thus often based on a detailed performance based approach, which can be time consuming and expensive and which is generally not well supported by a deep understanding of CFS columns’ behaviour in real fires. This thesis aims to understand the fundamental thermal and mechanical factors at play within these sections so as to provide guidance on how to improve their design for fire resistance when applied either as unprotected or protected sections. A meta-analysis of available furnace test data is used to demonstrate that current guidance fails to capture the relevant mechanics and thus poorly predicts fire resistance. It is also demonstrated that the predictive abilities of the available design standards vary with physical characteristics of the CFS section such as shape and size. A factor which has been observed in furnace tests on CFS sections but which is not accounted for in available guidance is the formation of an air gap between the steel tube and the concrete core due to differential expansion; this affects their structural response in fire. The insulating effect of air gap formation has not previously been addressed in literature and an experimental program is presented to systematically assess the effects of a gap on the heat transfer through the section; showing that the presence of even a 1 mm gap is important. To explicitly assess the heat transfer response within both unprotected and fire protected (i.e. insulated) CFS sections, 34 large scale standard furnace tests were performed in partnership with an industry sponsor. Fourteen tests on large scale unloaded unprotected CFS sections are presented to assess current capability to predict the thermal response and to assess the effects of different sectional and material parameters on heating. New best practice thermal modelling guidance is suggested based on comparison between the models and observed temperatures from the tests. Twenty CFS specimens of varying size and shape, protected with different types and thicknesses of intumescent paint fire insulation, were also tested unloaded in a furnace to understand the thermal evolution within protected CFS sections and to develop design guidance to support application of intumescent coatings in performance based fire resistance design of CFS sections. These tests demonstrate that the intumescent coatings were far more effective than expected when applied to CFS sections, and that current methods of designing the coatings’ thickness are overly conservative. The reason for this appears to be that the calculation of effective section factor which is used in the prescription of intumescent coating thicknesses is based on the thermal response of unprotected CFS sections which display fundamentally different heating characteristics from protected sections due to the development of a thermal gradient in the concrete core. It is also demonstrated (by calculation supported by the testing presented herein) that the steel failure temperature (i.e. limiting temperature) of an unprotected CFS column in fire is significantly higher than one which is protected; procedures to determine the limiting temperature of protected sections are suggested. Finally, the residual strength of fire-exposed CFS columns is examined through structural testing of 19 of the 34 fire tested columns along with unheated control specimens. The results provide insights into the residual response of unprotected and protected CFS section exposed to fire, and demonstrate a reasonable ability to calculate their residual structural capacity. The work presented in this thesis has shed light on the ability of available guidance to rationally predict the thermal and structural response to fire of CFS columns, has improved the understanding of the thermal evolution within protected and unprotected CFS sections in fire, has provided best-practice guidance and material input parameters for both thermal and structural modelling of CFS sections, and has improved understanding of the residual capacity of CFS sections after a fire.

Design and implementation of a rammed infill adobe and plastic bottle wall system in Honduras

Enns, Garry

31 July 2015

A new wall construction technique utilizing concrete filled PVC tubes, adobe, polyethylene terephthalate (PET) plastic bottles and cabling was designed, analyzed and implemented. The system was designed as an alternative to traditional earthen buildings in Honduras that are vulnerable to hurricane winds and seismic activity. Six prototype panels were constructed at the Alternative Village located at the University of Manitoba to evaluate the wall system for racking and transverse load capacity. A kitchen was then constructed at an elementary school in western Honduras. / October 2015

alternative building

sustainable building

PET plastic bottles

concrete filled tubes

Experimental study on concrete filled square hollow sections

Lam, Dennis, Williams, C.A.

January 2004

A series of tests was performed to consider the behaviour of short composite columns under axial compressive loading, covering a range of S275 and S355 grade steel square hollow section filled with normal and high strength concrete. The interaction between the steel and the concrete component is considered and the results show that concrete shrinkage has an effect on the axial strength of the column. Comparisons between Eurocode 4, ACI-318 and the Australian Standards with the findings of this research were made. Result showed the equation used by the ACI-318 and the proposed Australian Standards gave better predication for the axial capacity of concrete filled SHS columns than the Eurocode 4.

Composite column

Concrete filled

Square hollow sections

Axial strength

Confinement

Modelling the Confinement Effect of Composite Concrete-Filled Elliptical Steel Columns

Dai, Xianghe, Lam, Dennis

January 2009

No

Confinement Effect

Composite Steel Columns

Concrete-Filled Columns

Elliptical

Finite Element Modelling Of Slender Concrete Filled Elliptical Steel Columns

Lam, Dennis, Dai, Xianghe, Jamaluddin, N., Ye, J.

January 2011

No

Finite Element Modelling

Slender Columns

Concrete-Filled Columns

Elliptical

Structural Behaviour of Concrete filled Elliptical Steel Hollow Sections

Lam, Dennis, Dai, Xianghe, Jamaluddin, N.

January 2012

No

Structural Behaviour

Concrete-Filled Sections

Elliptical

Steel Hollow Sections

Axial capacity of concrete filled stainless steel circular columns

Lam, Dennis, Roach, C.

January 2006

No description available.

Axial capacity

; Concrete filled columns

; Stainless steel

; Circular columns