ebook img

Structural behavior of fiber reinforced mortar related to material fracture resistance PDF

158 Pages·2016·8.96 MB·English
by  
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Structural behavior of fiber reinforced mortar related to material fracture resistance

STRUCTURAL BEHAVIOR OF FIBER REINFORCED MORTAR RELATED 'IO MATERIAL FRACTURE RESISTANCE by ROBERT JAMES WARD B.E. University College Galway, Ireland (1986) SUBMITTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE IN CIVIL ENGINEERING at the MASSACHUSETTS INSTITUTE OF TECHNOLOGY June 1989 0 Massachusetts Institute of Technology 1989 All rights reserved Signature redacted Signature of Author Department of Civil Engineering Signature redacted Certified by Victor C. Li Associate Professor of Civil Engineering Thesis Supervisor Signature redacted Accepted by ------- J Ole S. Madsen Chairman, Departmental Committee on Graduate Students Department of Civil Engineering NSS. JIST. TECd JU 1 '89 ARCHIVES U C) STRUCTURAL BEHAVIOR OF FIBER REINFORCED MORTAR RELATED TO MATERIAL FRACTURE RESISTANCE by ROBERT JAMES WARD Submitted to the Department of Civil Engineering on May 11, 1989, in partial fulfillment of the requirements for the Degree of Master of Science in Civil Engineering ABSTRACT An indirect J-integral technique for measuring the tension softening curve of non-yielding materials like concrete is presented and is applied to mortars reinforced with various short fiber types (steel and synthetic). The tension softening curve serves to characterize and measure material fracture resistance. The dependence of structural behavior on material fracture resistance is investigated through third-point loading tests on unreinforced fiber mortar beams which fail in flexure and through center-point loading tests on longitudinally reinforced fiber mortar beams without shear stirrups which fail in shear. Conclusive evidence, relating improved structural performance directly to improvements in material fracture resistance due to fiber reinforcement, is presented. Semi-empirical formulae are proposed which relate flexural toughness indices directly to parameters involving just the flexural strength, the splitting tensile strength and the fiber length. Also, semi-empirical design formulae are proposed which relate the ultimate shear strength of longitudinally reinforced beams with fibers as shear reinforcement, to the material fracture resistance (represented by a combination of flexural and splitting tensile strengths), the shear span/effective depth ratio, the longitudinal reinforcement ratio and the beam depth. All proposed formulae are suitable for the purposes of design and quality control. Thesis Supervisor: Dr. Victor C. Li Title: Associate Professor of Civil Engineering 2 A I'DGD ENT I wish to thank the following people: Professor Victor Li for introducing me to the subjects of fracture mechanics and fiber reinforced concrete, and for overseeing my entire research program. He provided me with invaluable guidance, support and encouragement and above all I thank him for making my stay at M.I.T. a truly enjoyable experience. My fellow graduate students who so often offered their advice and help, especially in the laboratory. Professor Stanley Backer who always ensured that I had a large and varied supply of synthetic fibers with which to work. Mr. Rick Smith of Ribbon Technology Corporation, Ohio, who provided me with all the steel fibers. Mr. Kevin Grogan of W. R. Grace and Co., Cambridge, Mass., who provided me with the superplasticiser. The U.S. National Science Foundation and the Shimizu Corporation of Japan who both provided vital funding which made this research program possible. Miss Irene Uesato, who took time out of her very busy schedule, to type this thesis. 3 TABLE OF CONTENTS Title Page 1 Abstract 2 Acknowledgements 3 Table of Contents 4 List of Figures 6 List of Tables 10 Chapter 1: INTRODUCTION 11 Chapter 2: TENSION SOFTENING CURVE BY J-INTEGRAL TECHNIQUE 17 2.1 Introduction 17 2.2 Theoretical Basis of J-Integral Technique 18 2.3 Numerical Verification of Test Technique 21 2.4 Experimental Procedure 22 2.4.1 Specimen preparation 22 2.4.2 Testing procedure 24 2.5 Results and Data Analysis 25 2.6 Calculation of GF 27 2.7 Discussion and Recommendations for the J-Integral Test. 28 2.8 Current Status of J-Integral Test Technique 30 Chapter 3: FLEXURAL BEHAVIOR OF FIBER REINFORCED MORTAR 40 3.1 Introduction 40 3.2 General Behavior of Fiber Concrete in Flexure 42 3.3 Experimental Program 46 3.3.1 Specimen preparation 46 3.3.2 Testing procedure 47 3.4 Compressive Strength 48 3.5 Splitting Tensile Strength 49 3.6 Flexural Strength 50 3.6.1 Size dependence of flexural strength 51 3.6.2 Flexural strength related to fracture resistance 52 57 3.7 Flexural Load-Deflection Curves 4 3.7.1 Effect of fiber type and volume fraction on the flexural load-deflection curve 57 3.7.2 Effect of beam size on the flexural load-deflection curve 60 3.8 Flexural Toughness Indices 62 3.8.1 15' 10' 3 and 150 indices 62 3.8.2 Tmaxp T and T indices 65 50 10 3.9 Simple Flexural Toughness Estimates 68 Appendix 3.1 Comparison of Size-Effect Predicted by the Weibull and Fictitious Crack Models 73 Chapter 4: FIBERS AS SHEAR REINFORCEMENT IN LONGITUDINALLY REINFORCED BEAMS 102 4.1 Introduction 102 4.2 Advantages of Fibers as Shear Reinforcement 104 4.3 Experimental Program 107 4.3.1 Specimen preparation 107 4.3.2 Testing procedure 110 4.4 Observed Failure Modes 111 4.4.1 Beam-action (a/d > 2.5) 111 4.4.2 Arch-action (a/d < 2.5) 113 4.5 Test Results and Discussion 115 4.5.1 First crack strength 115 4.5.2 Shear span/effective depth ratio 118 4.5.3 Reinforcement ratio 121 4.5.4 Beam depth 122 4.6 Simple Design Formulae for the Shear Strength of Reinforced Mortar Beams with Fibers 124 Chapter 5: CONCLUSION 144 Chapter 6: RECOMMENDED FUTURE RESEARCH 147 References 154 5 List of Figures Fig. 2.1 Cohesive Zone Ahead of the Crack Tip Fig. 2.2 Specimen Configurations used with J-Integral Test Fig. 2.3 Inside of Omni-mixer Fig. 2.4 Specimens covered in Plastic just after Casting Fig. 2.5 Notched Beam ready for Testing Fig. 2.6 Loading Machine Used for J-Integral Test Program Fig. 2.7 Average Load versus Load Point Displacement Curves Fig. 2.8 Average Load Point Displacement versus Crack Opening Curves Fig. 2.9 J-Integral versus Crack Opening Curve Fig. 2.10 Deduced Tension Softening Curve Fig. 2.11 Comparison Between Deduced and Directly Measured Tension Softening Curves Fig. 2.12 Flexural Load Deflection Curve Corrected to Account for Energy Supplied by Beam Self-Weight Fig. 2.13 Tension Softening Curves Deduced by Indirect J-Integral Technique Fig. 3.1 Specimen Geometry and Loading Configuration for Flexural Test Fig. 3.2 Wooden Mold for 228 mm Deep Beam Fig. 3.3 Beams Covered with Plastic Just After Casting Fig. 3.4 Cylinders in Plastic Molds and Covered with Plastic Just After Casting Fig. 3.5 228 mm Deep Beam ready for Testing Under Third Point Loading Fig. 3.6 Cylinder with LVDTs on either side ready for Compression Test Fig. 3.7 Cylinder ready for Splitting Tension Test Fig. 3.8 Effect of Fiber Reinforcement on Compressive Strength Fig. 3.9 Effect of Fiber Reinforcement on the First Crack Splitting Tensile Strength Fig. 3.10 Influence of Beam Size on Flexural Strength Fig. 3.11 Average Normalized Flexural Strength Values as a Function of Beam Depth Fig. 3.12 Theoretical Curves Relating the ff/ft Ratio to the d/lch Ratio Calculated Using the Fictitious Crack Model [101 6 Fig. 3.13 Empirical Relationship Between the Flexural/Tensile Strength Ratio and the Compressive Strength for Plain Concrete [401 Fig. 3.14 Empirical Relationship Between the Flexural/Tensile Strength Ratio and the Material Characteristic Length for Plain Concrete [10] Fig. 3.15 Effect of Fiber Reinforcement on the Ratio Between Flexural and Splitting Tensile Strengths Fig. 3.16 Typical Tension Softening Curves of Mortars Reinforced with various Fibers Fig. 3.17 Flexural Load-Deflection Curves for Mortars Reinforced with various Fiber Types Fig. 3.18 Flexural Load-Deflection Curves for Kevlar Fiber Reinforced Mortar Beams Fig. 3.19 Flexural Load-Deflection Curves for Steel Fiber (25 mm) Reinforced Mortar Beams Fig. 3.20 Flexural Stress versus Normalized Deflection for Different Beam Sizes of Kevlar Fiber Reinforced Mortar Fig. 3.21 Flexural Stress versus Normalized Deflection for Different Beam Sizes of Steel Fiber Reinforced Mortar Fig. 3.22 Calculation of Flexural Toughness Indices from Flexural Load-Deflection Diagram Fig. 3.23 Influence of Beam Size on Flexural Toughness Indices 5 I10' 130 and 150 Fig. 3.24 Influence of Beam size on Flexural Toughness Index Tmax Fig. 3.25 Influence of Beam Size on Flexural Toughness Index T 5m Fig. 3.26 Influence of Beam Size on Flexural Toughness Index T10 Fig. 3.27 Various Flexural Toughness Indices for Mortars Reinforced with each Fiber Type Fig. 3.28 Semi-Empirical Relationship Between the f /ft Ratio and the Flexural Toughness Index Tmax Fig. 3.29 Semi-Empirical Relationship Between the Flexural Toughness Index T and a Parameter involving the Flexural and Tensile 10 Strengths and the Fiber Length Fig. 3.30 Theoretical Curves Relating the f /ft Ratio to the d/lch Ratio Calculated Using the Fictitious Crack Model [38] Fig. 3.31 Comparison of Size Dependence of Flexural Strength Predicted by the Weibull and Fictitious Crack Models 7 Fig. 4.1 Specimen Geometry and Loading Configuration for Shear Beam Test Fig. 4.2 Rebars Fixed at Proper Spacing Using Short Steel Bars Fig. 4.3 Rebars Fixed in Mold Ready for Casting Fig. 4.4 Shear Beam Ready for Center Point Loading Fig. 4.5 Loading System for Large Shear Beams. Bottom Beam is just a Support Fig. 4.6 (a) Typical Crack Shape in Plain Mortar Beam with a/d > 2.5 (b) Typical Critical Crack Shape in Fiber Reinforced Beam with a/d > 2.5 Fig. 4.7 Force System in Reinforced Concrete Beam at a Diagonal Shear Crack Fig. 4.8 Failure Patterns for Shear Beams with a/d = 3.0 and d = 204 mm (a) = Plain Mortar (c) Kevlar 2% (b) = 25 mm Steel 1% (d) 25 mm Steel 2% Fig. 4.9 Shear Failure Patterns in Beams with a/d = 3.0, d = 204 mm and 25 mm Steel Fiber Reinforcement 2% Fig. 4.10 Typical Shear Failure Patterns in Beams with a/d < 2.5 (a) Splitting Failure (b) Shear Compression Failure (c) Flexural Tension Failure Under Eccentric Compression Fig. 4.11 Typical Splitting Tension Like Failures of Plain Mortar Beams with a Reinforcement Ratio of 2.2% and Loaded with a/d = 1.0 [18] Fig. 4.12 Typical Shear Compression Like Failures of Beams Reinforced with 2% Acrylic Fibers. The Reinforcement Ratio is 2.2% and a/d = 1.0 [18]. Fig. 4.13 Cracking and Ultimate Shear Strengths of various Fiber Reinforced Mortar Beams Fig. 4.14 Influence of the Shear Span/Effective Depth Ratio on Ultimate Shear Strength of Fiber Reinforced Mortar Beams Fig. 4.15 Influence of the Shear Span/Effective Depth Ratio on the Maximum Bending Moment in Fiber Reinforced Mortar Beams with Longitudinal Steel Fig. 4.16 Influence of the Longitudinal Reinforcement Ratio on the Ultimate Shear Strength of Fiber Reinforced Mortar Beams 8 Fig. 4.17 Influence of Beam Depth on the Ultimate Shear Strength of Fiber Reinforced Mortar Beams Fig. 4.18 Semi-Empirical Relationship Between Ultimate Shear Strength and the Material and Geometrical Properties for a/d > 2.5 Fig. 4.19 Semi-Empirical Relationship Between Ultimate Shear Strength and the Material and Geometrical Properties for a/d < 2.5 9 List of Tables Table 2.1 Summary of J-Integral Test Results Table 3.1 Fiber Properties Table 3.2 Flexural, Splitting Tensile and Compressive Strengths of Mortars Reinforced with various Fiber Types Table 3.3 Flexural Toughness Indices of Mortars Reinforced with various Fiber Types Table 3.4 Size Dependence of Flexural Strength Predicted by the Weibull and Fictitious Crack Models Table 4.1 First Crack and Ultimate Shear Strengths Table 4.2 Flexural, Splitting Tensile and Compressive Strengths 10

Description:
Galway, Ireland. SUBMITTED IN airman, Departmental Committee on Graduate Students . (b) Typical Critical Crack Shape in Fiber Reinforced Beam with a/d > .. required to obtain a completely stable load-deformation curve.
See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.