Time-Dependent Behaviour of Concrete Structures

Serviceability failures of concrete structures involving excessive cracking or deflection are relatively common, even in structures that comply with code requirements. This is often as a result of a failure to adequately account for the time-dependent deformations of concrete in the design of the structure. The serviceability provisions embodied in codes of practice are relatively crude and, in some situations, unreliable and do not adequately model the in-service behaviour of structures. In particular, they fail to adequately account for the effects of creep and shrinkage of the concrete. Design for serviceability is complicated by the non-linear and inelastic behaviour of concrete at service loads. Providing detailed information, this book helps engineers to rationally predict the time-varying deformation of concrete structures under typical in-service conditions. It gives analytical methods to help anticipate time-dependent cracking, the gradual change in tension stiffening with time, creep induced deformations and the load independent strains caused by shrinkage and temperature changes. The calculation procedures are illustrated with many worked examples. A vital guide for practising engineers and advanced students of structural engineering on the design of concrete structures for serviceability and provides a penetrating insight into the time-dependent behaviour of reinforced and prestressed concrete structures.

Time-Dependent DeformationBackgroundCreep of ConcreteShrinkage of ConcreteTime-Analysis – The Basic ProblemMaterial PropertiesConcreteSteep ReinforcementReferences Design for Serviceability – Deflection and Crack ControlIntroductionDesign Objectives and CriteriaDesign ActionsDesign Criteria for ServicabilityMaximum Span-to-Depth Ration Minimum ThicknessDeflection Control by Simplified CalculationCrack ControlReferencesUncracked Sections – Axial LoadingPreambleThe Effective Modulus MethodThe Principle of Superposition – Step-by-Step MethodThe Age-Adjusted Effect Modulus Method (AEMM)The Rate of Creep Method (RCM)Comparison of Methods of AnalysisUncracked Sections – Axial Force and Uniaxial BendingUncracked Sections – Axial Force and Biaxial BendingIntroductory RemarksOverview of Cross-Sectional AnalysisShort-Term Analysis of Reinforced or Prestressed Concrete Cross SectionsLong-Term Analysis of Reinforced or Prestressed Concrete Cross Sections Using the Age Adjusted Effective ModulusLong-Term Analysis of Reinforced Prestressed Concrete Cross Section Using the Step-by-Step ProcedureComposite Steel-Concrete Cross SectionsReferencesCracked SectionsIntroductory RemarksShort-Term AnalysisTime-Dependent Analysis (AEMM)Short- and Long-Term Analysis Using the Step-by-Step MethodReferencesMembers and StructuresIntroductory RemarksDeflection of Statically Determinate BeamsStatically Indeterminate Beams and SlabsTwo-Way Slab SystemsSlender Reinforced Concrete ColumnsTemperature EffectsConcluding RemarksReferencesStiffness Method and Finite Element ModellingIntroductionOverview of the Stiffness MethodMember LoadsTime Analysis Using AEMMTime Analysis Using SSMTime Analysis Using the Finite Element MethodAnalysis of Cracked MembersReferencesAppendix: Analytical Formulations – Euler-Bernoulli Beam Model

Raymond Ian Gilbert is Professor of Civil Engineering at the University of New South Wales and currently holds an Australian Research Council Australian Professorial Fellowships. He has over 35 years experience in structural design and is a specialist in the analysis and design of reinforced and prestressed concrete structures. GianlucaRanzi is a Senior Lecturer of structural engineering at the University of Sydney, specialising in the analysis and design of concrete and composite steel-concrete structures.