Analysis and Description of Concrete Cracking Mechanisms

Henaff, Xavier Le

January 2013

Note:

Concrete Cracking Mechanisms

Flange effectiveness in the resistance of shear on RC T-beams subjected to point loads

Giaccio, Craig, 1974-

January 2003

Abstract not available

Reinforced concrete

Concrete beams

Shear (Mechanics)

Concrete beams -- Fatigue

Concrete -- Cracking

Numerical modelling of time-dependent cracking and deformation of reinforced concrete structures

Chong, Kak Tien, Civil & Environmental Engineering, Faculty of Engineering, UNSW

January 2004

For a structure to remain serviceable, crack widths must be small enough to be acceptable from an aesthetic point of view, small enough to avoid waterproofing problems and small enough to prevent the ingress of water that may lead to corrosion of the reinforcement. Crack control is therefore an important aspect of the design of reinforced concrete structures at the serviceability limit state. Despite its importance, code methods for crack control have been developed, in the main, from laboratory observations of the instantaneous behaviour of reinforced concrete members under load and fail to account adequately for the time-dependent development of cracking. In this study numerical models have been developed to investigate timedependent cracking of reinforced concrete structures. Two approaches were adopted to simulate cracking in reinforced concrete members. The first approach is the distributed cracking approach. In this approach, steel reinforcement is smeared through the concrete elements and bond-slip between steel and concrete is accounted for indirectly by including the tension stiffening effect. The second approach is the localized cracking approach, in which concrete fracture models are used in conjunction with bond-slip interface elements to model stress transfer between concrete and steel. Creep of concrete has been incorporated into the models by adopting the principle of superposition and the time-dependent development of shrinkage strain of concrete is modelled using an approximating function. Both creep and shrinkage were treated as inelastic pre-strains and applied to the discretized structure as equivalent nodal forces. Apart from material non-linearity, non-linearity arising from large deformation was also accounted for using the updated Lagrangian formulation. The numerical models were used to simulate a series of laboratory tests for verification purposes. The models were assessed critically by comparing the numerical results with the test data and the numerical results are shown to have good correlations with the test results. In addition, a comparison was undertaken among the numerical models and the pros and cons of each model were evaluated. A series of controlled parametric numerical experiments was devised and carried out using one of the numerical models. Various parameters were identified and investigated in the parametric study. The effects of the parameters were thoroughly examined and the interactions between the parameters were discussed in detail.

ConcreteCracking

Reinforced concrete.

Strength and ductility of fibre reinforced high strength concrete columns

Zaina, Mazen Said, Civil & Environmental Engineering, Faculty of Engineering, UNSW

January 2005

The main structural objectives in column design are strength and ductility. For higher strength concretes these design objectives are offset by generally poor concrete ductility and early spalling of the concrete cover. When fibres are added to the concrete the post peak characteristics are enhanced, both in tension and in compression. Most of the available experimental data, on fibre reinforced concrete and fibre reinforced high strength concrete columns, suggest that an improvement in both ductility and load carrying capacity due to the inclusion of the fibres. In this thesis the ductility and strength of fibre reinforced high strength concrete are investigated to evaluate the effect of the different parameters on the performance of columns. The investigation includes both experimental and the numerical approaches with 56 high strength fibre reinforced concrete columns being tested. The concrete strength ranged between 80 and 100 MPa and the columns were reinforced with 1, 2 or 2.6 percent, by weight, of end hooked steel fibres. The effect of corrugated Polypropylene fibres on the column performance was also examined. No early spalling of the cover was observed in any of the steel fibre reinforced column tested in this study. A numerical model was developed for analysis of fibre and non-fibre reinforced eccentrically loaded columns. The column is modelled as finite layers of reinforced concrete. Two types of layers are used, one to represent the hinged zone and the second the unloading portion of the column. As the concrete in the hinged layers goes beyond the peak for the stress verus strain in the concrete the section will continue to deform leading to a localised region within a column. The numerical model is compared with the test data and generally shows good correlation. Using the developed model, the parameters that affect ductility in fibre-reinforced high strength concrete columns are investigated and evaluated. A design model relating column ductility with confining pressure is proposed that includes the effects of the longitudinal reinforcement ratio, the loading eccentricity and the fibre properties and content and design recommendations are given.

Columns Concrete

Testing

Reinforced concrete Fiber

High strength concrete

Reinforced concrete construction

fiber

spalling

Intermediate crack debonding of plated reinforced concrete beams

Liu, Irene S. T.

January 2006

With increasing number of structures reaching their designed life or capacities everyday, retrofitting has become an important area in civil engineering. A popular method of strengthening and stiffening reinforced concrete ( RC ) beams is by adhesively bonding steel or FRP plates to the external surfaces. This technique has been proven to be efficient, inexpensive, unobtrusive and can be applied while the structure is in use. However, it has been found that adhesively bonded plates are prone to premature debonding prior to reaching their designed capacities, which restricts the use of existing design rules and guidelines for retrofitting RC beams using this relatively new form of structure. There are various forms of debonding including : plate end ( PE ) debonding ; critical diagonal crack ( CDC ) debonding ; and intermediate crack ( IC ) debonding. IC debonding is an especially important mechanism as it will occur at plated hinges of continuous members, and unlike other premature debonding mechanisms, IC debonding is very difficult to prevent. This debonding mechanism is associated with the formation of flexural or flexural - shear cracks in the vicinity of the plates, which causes slip to occur at the plate / concrete as well as the bar / concrete interfaces. Most research to date has been focusing on the bond - slip relationship at the plate / concrete interface, while little attention has been given to the IC debonding behaviour of flexural members. To allow safe and effective use of plated structures, it is necessary to model the debonding behaviours at the plate / concrete interface as premature debonding will affect both the strength and ductility of the members, and hence the ability of continuous structures to redistribute moment. Despite the importance of moment redistribution, very limited research has been carried out on the moment redistribution of continuous plated members. Since IC debonding is likely to occur at plated hinges of continuous members hence affecting the ductility of the hinges, the existing approaches for determining moment redistribution of reinforced concrete beams cannot be applied to plated members. In this research a numerical model based on discrete cracking and partial interaction theory has been developed which models the IC debonding of plated beams, taking into account the slips at all interfaces. This model will allow a better understanding of the IC debonding behaviour of plated members, and also from the model, the rotation capacity of both plated and unplated hinges in continuous reinforced concrete beams can be determined. Mathematical models and design rules have been developed for analysing critical diagonal crack debonding, which is dependent on the IC debonding behaviour of the plated members. Moment redistribution of beams with externally bonded and near surface mounted plates is studied through a series of tests and a mathematical model based on variation in flexural rigidity is proposed. Through the tests carried out on continuous plated beams, much moment redistribution is evident as oppose to that suggested by the existing design guidelines for plated members, where no moment redistribution is allowed for members plated with FRP. From the models proposed for IC and CDC debonding in this research, together with the existing PE debonding models available, all debonding mechanisms can now be modelled. Furthermore from the research on continuous plated beams, moment redistribution of plated beams can be analysed, allowing safe, effective and economic use of this retrofitting technique. This thesis is presented in the form of a collection of journal papers published or submitted for publication as a result of the research performed by the author. A selection of ten publications have been included in the following context, together with literature reviews performed on the related areas of studies, as well as further discussions on the papers, which consist of any additional information or work that was carried out in this research but not presented in the papers. / Thesis (Ph.D.)--School of Civil and Environmental Engineering, 2006.

Concrete beams Strains and stresses.

Reinforced concrete Testing.

Concrete Cracking

Torsion in concrete framed structures

Shepherd, Peter Noel.

January 1975

No description available.

Concrete beams Testing

Shear capacity assessment of corrosion-damaged reinforced concrete beams

Farrow, William C.

19 November 2002

The research presented here is a study to determine the effect of shear reinforcement corrosion on the shear capacity in conventionally reinforced concrete (CRC) bridge elements. A total of 14 CRC beams were tested using three stirrup spacings (8, 10, and 12-inch). Six of the beams included the influence of a 4-inch thick deck, and both positive and negative moment regions were considered. The CRC beams were subjected to an accelerated corrosion process to produce the damage states. Inspection techniques were used to visually correlate corrosion damage with actual structural performance. Severe corrosion damage was shown to have significant effect on the shear performance of the CRC beams. Findings indicate that current inspection ratings for corrosion damage may not adequately identify the extent of structural deterioration. / Graduation date: 2003

Reinforced concrete -- Testing

Reinforced concrete -- Corrosion

Concrete beams -- Testing

Concrete beams -- Corrosion

Interpretation of hydration process of concrete based on electrical resistivity measurement /

Xiao, Lianzhen.

January 2007

Thesis (Ph.D.)--Hong Kong University of Science and Technology, 2007. / Includes bibliographical references (leaves 178-191). Also available in electronic version.

Concrete Electric resistance

Non-linear analysis of concrete fracture /

Jeang, Fure Lin.

January 1985

Thesis (Ph. D.)--University of Washington, 1985. / Vita. Bibliography: leaves [274]-283.

Fracture mechanics. Concrete

Behavior and modeling of reinforced concrete slab-column connections

28 August 2008

Not available

Concrete construction--Hinges--Testing

Concrete construction--Hinges--Models

Load factor design

Columns, Concrete

Concrete slabs