Reinforced concrete : a fundamental approach

For one-semester, junior/senior-level and graduate courses in Reinforced Concrete in the department of civil engineering. Now reflecting the new 2008 ACI 318-08 Code and the new International Building Code (IBC-2006), the Sixth Edition of this cutting-edge text has been extensively revised to present state-of-the-art developments in reinforced concrete. It analyzes the design of reinforced concrete members through a unique and practical step-by-step trial and adjustment procedure. The narrative is supplemented with flowcharts to guide students logically through the learning process. Ample photographs of instructional testing of concrete members decreases the need for actual laboratory testing.

PREFACE 1 INTRODUCTION 1.1 Historical Development of Structural Concrete 1.2 Basic Hypothesis of Reinforced Concrete 1.3 Analysis versus Design of Sections 2 CONCRETE-PRODUCING MATERIALS 2.1 Introduction 2.2 Portland Cement 2.3 Water and Air 2.4 Aggregates 2.5 Admixtures Selected References 3 CONCRETE 3.1 Introduction 3.2 Proportioning Theory-Normal Strength Concrete 3.3 High-Strength High-Performance Concrete Mixtures Design 3.4 PCA Method of Mixture Design 3.5 Estimating Compressive Strength of a Trial Mixture Using the Specified Compressive Strength 3.6 Mixture Designs for Nuclear-Shielding Concrete 3.7 Quality Tests on Concrete 3.8 Placing and Curing of Concrete 3.9 Properties of Hardened Concrete 3.10 High-Strength Concrete Selected References Problems for Solution 4 REINFORCED CONCRETE 4.1 Introduction 4.2 Types and Properties of Steel Reinforcement 4.3 Bar Spacing and Concrete Cover for Steel Reinforcement 4.4 Concrete Structural Systems 4.5 Reliability and Structural Safety of Concrete Components 4.6 ACI Load Factors and Safety Margins 4.7 Design Strength versus Nominal Strength: Strength Reduction Factor 4.8 Quality Control and Quality Assurance Selected References 5 FLEXURE IN BEAMS 5.1 Introduction 5.2 The Equivalent Rectangular Block 5.3 Strain Limits Method for Analysis and Design 5.4 Analysis of Singly Reinforced Rectangular Beams for Flexure 5.5 Trial-and-Adjustment Procedures for the Design of Singly Reinforced Beams 5.6 One-Way Slabs 5.7 Doubly Reinforced Sections 5.8 Nonrectangular Sections 5.9 Analysis of T and L Beams 5.10 Trial-and-Adjustment Procedure for the Design of Flanged Sections 5.11 Concrete Joist Construction 5.12 SI Expressions and Example for Flexural Design of Beams Selected References Problems for Solution 6 SHEAR AND DIAGONAL TENSION IN BEAMS 6.1 Introduction 6.2 Behavior of Homogeneous Beams 6.3 Behavior of Reinforced Concrete Beams as Nonhomogeneous Sections 6.4 Reinforced Concrete Beams without Diagonal Tension Reinforcement 6.5 Diagonal Tension Analysis of Slender and Intermediate Beams 6.6 Web Steel Planar Truss Analogy 6.7 Web Reinforcement Design Procedure for Shear 6.8 Examples of the Design of Web Steel for Shear 6.9 Deep Beams: Non-Linear Approach 6.10 Brackets or Corbels 6.11 Strut and Tie Model Analysis and Design of Concrete Elements 6.12 SI Design Expressions and Example for Shear Design Selected References Problems for Solution 7 TORSION 7.1 Introduction 7.2 Pure Torsion in Plain Concrete Elements 7.3 Torsion in Reinforced Concrete Elements 7.4 Shear-Torsion-Bending Interaction 7.5 ACI Design of Reinforced Concrete Beams Subjected to Combined Torsion, Bending, and Shear 7.6 SI Metric Torsion Expressions and Example for Torsion Design Selected References Problems for Solution 8 SERVICEABILITY OF BEAMS AND ONE-WAY SLABS 8.1 Introduction 8.2 Significance of Deflection Observation 8.3 Deflection Behavior of Beams 8.4 Long-Term Deflection 8.5 Permissible Deflections in Beams and One-Way Slabs 8.6 Computation of Deflections 8.7 Deflection of Continuous Beams 8.8 Operational Deflection Calculation Procedure and Flowchart 8.9 Deflection Control in One-Way Slabs 8.10 Flexural Cracking in Beams and One-Way Slabs 8.11 Tolerable Crack Widths 8.12 ACI 318 Code Provisions for Control of Flexural Cracking 8.13 SI Conversion Expressions and Example of Deflection Evaluation Selected References Problems for Solution 9 COMBINED COMPRESSION AND BENDING: COLUMNS 9.1 Introduction 9.2 Types of Columns 9.3 Strength of Non-Slender Concentrically Loaded Columns 9.4 Strength of Eccentrically Loaded Columns: Axial Load and Bending 9.5 Strain Limits Method to Establish Reliability Factor and Analysis and Design of Compression Members 9.6 Whitney's Approximate Solution in Lieu of Exact Solutions 9.7 Column Strength Reduction Factor 9.8 Load-Moment Strength Interaction Diagrams (P-M Diagrams) for Columns Controlled by Material Failure 9.9 Practical Design Considerations 9.10 Operational Procedure for the Design of Nonslender Columns 9.11 Numerical Examples for Analysis and Design of Nonslender Columns 9.12 Limit State at Buckling Failure (Slender or Long Columns) 9.13 Moment Magnification: First-Order Analysis 9.14 Second-Order Frame Analysis and the P- effect 9.15 Operational Procedure and Flowchart for the Design of Slender Columns 9.16 Compression Members in Biaxial Bending 9.17 SI Expressions and Example for the Design of Compression Members Selected References Problems for Solution 10 BOND DEVELOPMENT OF REINFORCING BARS 10.1 Introduction 10.2 Bond Stress Development 10.3 Basic Development Length 10.4 Development of Flexural Reinforcement in Continuous Beams 10.5 Splicing of Reinforcement 10.6 Examples of Embedment Length and Splice Design for Beam Reinforcement 10.7 Typical Detailing of Reinforcement and Bar Scheduling Selected References Problems for Solution 11 DESIGN OF TWO-WAY SLABS AND PLATES 11.1 Introduction: Review of Methods 11.2 Flexural Behavior of Two-Way Slabs and Plates 11.3 The Direct Design Method 11.4 Distributed Factored Moments and Slab Reinforcement by the Direct Design Method 11.5 Design and Analysis Procedure: Direct Design Method 11.6 Equivalent Frame Method for Floor Slab Design 11.7 SI Two-Way Slab Design Expressions and Example 11.8 Direct Method of Deflection Evaluation 11.9 Cracking Behavior and Crack Control in Two-Way-Action Slabs and Plates 11.10 Yield-Line Theory for Two-Way Action Plates Selected References Problems for Solution 12 FOOTINGS 12.1 Introduction 12.2 Types of Foundations 12.3 Shear and Flexural Behavior of Footings 12.4 Soil Bearing Pressure at Base of Footings 12.5 Design Considerations in Flexure 12.6 Design Considerations in Shear 12.7 Operational Procedure for the Design of Footings 12.8 Examples of Footing Design 12.9 Structural Design of Other Types of Foundations Selected References Problems for Solution 13 CONTINUOUS REINFORCED CONCRETE STRUCTURES 13.1 Introduction 13.2 Longhand Displacement Methods 13.3 Force Method of Analysis 13.4 Displacement Method of Analysis 13.5 Finite-Element Methods and Computer Usage 13.6 Approximate Analysis of Continuous Beams and Frames 13.7 Limit Design (Analysis) of Indeterminate Beams and Frames Selected References Problems for Solution 14 INTRODUCTION TO PRESTRESSED CONCRETE 14.1 Basic Concepts of Prestressing 14.2 Partial Loss of Prestress 14.3 Flexural Design of Prestressed Concrete Elements 14.4 Serviceability Requirements in Prestressed Concrete Members 14.5 Ultimate-Strength Flexural Design of Prestressed Beams 14.6 Example 14.5: Ultimate-Strength Design of Prestressed Simply Supported Beam by Strain Compatibility 14.7 Web Reinforcement Design Procedure for Shear Selected References Problems for Solution 15 LRFD AASHTO DESIGN OF CONCRETE BRIDGE STRUCTURES 15.1 LRFD Truck Load Specifications 15.2 Flexural Design Considerations 15.3 Shear Design Considerations 15.4 Horizontal Interface Shear 15.5 Combined Shear and Torsion 15.6 Step-by-Step LRFD Design Procedures 15.7 LRFD Design of Bulb-Tee Bridge Deck: Example 15.1 15.8 LRFD Shear and Deflection Design: Example 15.2 Selected References Problems for Solution 16 SEISMIC DESIGN OF CONCRETE STRUCTURES 16.1 Introduction: Mechanism of Earthquakes 16.2 Spectral Response Method 16.3 Equivalent Lateral Force Method 16.4 Simplified Analysis Procedure for Seismic Design of Buildings 16.5 Other Aspects in Seismic Design 16.6 Flexural Design of Beams and Columns 16.7 Seismic Detailing Requirements for Beams and Columns 16.8 Horizontal Shear in Beam-Column Connections (Joints) 16.9 Design of Shear Walls 16.10 Design Procedure for Earthquake-Resistant Structures 16.11 Example 16.1: Seismic Base Shear and Lateral Forces and Moments by the International Building Code (IBC) Approach 16.12 Example 16.2: Design of Confining Reinforcement for Beam-Column Connections 16.13 Example 16.3: Transverse Reinforcement in a Beam Potential Hinge Region 16.14 Example 16.4: Probable Shear Strength of Monolithic Beam-Column Joint 16.15 Example 16.5: Seismic Shear Wall Design and Detailing Selected References Problems for Solution 17 STRENGTH DESIGN OF MASONRY STRUCTURES 17.1 Introduction 17.2 Design Principles 17.3 Strength Reduction Factors 17.4 Flexural Strength 17.5 Shear Strength 17.6 Axial Compression Strength 17.7 Anchorage of Masonry Reinforcement 17.8 Prestressed Masonry 17.9 Deflection 17.10 Example 17.9: Detailed Design of CMU Lintel in Seismic Zone 17.11 Example 17.10: Design of Grouted CMU Wall Supporting Beam Lintel of Example 17.9 17.12 Example 17.11: Tension Anchor Design Selected References Problems for Solution APPENDIX A TABLES AND NOMOGRAMS INDEX