Chloride-Induced Steel Corrosion in Concrete Under Service Loads / / by Hailong Ye, Chuanqing Fu, Ye Tian, Nanguo Jin |
Autore | Ye Hailong |
Edizione | [1st ed. 2020.] |
Pubbl/distr/stampa | Singapore : , : Springer Singapore : , : Imprint : Springer, , 2020 |
Descrizione fisica | 1 online resource (XXIV, 138 p. 166 illus., 129 illus. in color.) |
Disciplina | 620.13623 |
Soggetto topico |
Building materials
Structural materials Tribology Corrosion and anti-corrosives Coatings Fire prevention Buildings—Design and construction Building Construction Engineering, Architectural Building Materials Structural Materials Tribology, Corrosion and Coatings Fire Science, Hazard Control, Building Safety Building Construction and Design |
ISBN | 981-15-4108-6 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | Chapter 1. Introduction -- Chapter 2. Chloride ingress in stressed concrete -- Chapter 3. Chloride ingress in cracked concrete -- Chapter 4. Influence of environmental conditions on chloride ingress -- Chapter 5. Steel corrosion in concrete beams under service loads. |
Record Nr. | UNINA-9910383832903321 |
Ye Hailong
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Singapore : , : Springer Singapore : , : Imprint : Springer, , 2020 | ||
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Lo trovi qui: Univ. Federico II | ||
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Concrete Reinforcement Degradation and Rehabilitation : Damages, Corrosion and Prevention / / by Yuli Panca Asmara |
Autore | Asmara Yuli Panca |
Edizione | [1st ed. 2024.] |
Pubbl/distr/stampa | Singapore : , : Springer Nature Singapore : , : Imprint : Springer, , 2024 |
Descrizione fisica | 1 online resource (176 pages) |
Disciplina | 620.13623 |
Collana | Engineering Materials |
Soggetto topico |
Concrete
Mechanics, Applied Solids Continuum mechanics Solid Mechanics Continuum Mechanics |
ISBN | 981-9959-33-0 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | Introduction to Reinforced Concrete -- Concrete structures -- Types and Causes of Concrete Damage -- Corrosion Theory -- Corrosion of Steel Reinforcement -- Reinforced Concrete Corrosion Experiments -- Reinforced Concrete Protection -- Concrete Reinforcement Inhibitors -- Geopolymer Concrete -- Concrete Treatment -- Cathodic Protection of Steel Reinforcement. |
Record Nr. | UNINA-9910760259703321 |
Asmara Yuli Panca
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Singapore : , : Springer Nature Singapore : , : Imprint : Springer, , 2024 | ||
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Lo trovi qui: Univ. Federico II | ||
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Seismic Performance of Corroded Reinforced Concrete Structures Retrofitted with FRP |
Autore | Shen Dejian |
Edizione | [1st ed.] |
Pubbl/distr/stampa | Singapore : , : Springer Singapore Pte. Limited, , 2024 |
Descrizione fisica | 1 online resource (394 pages) |
Disciplina | 620.13623 |
ISBN |
9789819979844
9789819979837 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Intro -- Foreword -- Preface -- Contents -- Abbreviations -- 1 Introduction -- 1.1 Corrosion and Retrofitting of Structures -- 1.1.1 Seismic Performance of Corrosion-Damaged Structures -- 1.1.2 Retrofitting of Structures -- 1.2 State-of-the-Art of Retrofitting of Structures -- 1.2.1 Bond Stress-Slip Relationship Between FRP Sheets and Concrete -- 1.2.2 Behavior of Beams Retrofitted with FRP -- 1.2.3 Seismic Performance of Columns Retrofitted with FRP -- 1.2.4 Seismic Performance of Beam-Column Joints Retrofitted with FRP -- 1.2.5 Seismic Performance of Shear Walls Retrofitted with FRP -- 1.2.6 Bond Behavior Between FRP Bars and Concrete -- 1.3 Objectives and Scope -- References -- 2 Bond Stress-Slip Relationship Between BFRP Sheets and Concrete Under Dynamic Loading -- 2.1 Effective Bond Length of BFRP Sheets Bonded to Concrete Under Dynamic Loading -- 2.1.1 Experimental Program -- 2.1.2 Failure Modes -- 2.1.3 Relationship Between Load and Displacement -- 2.1.4 Bond Strain and Bond Stress -- 2.1.5 Dynamic Effective Bond Length -- 2.2 Bond Stress-Slip Relationship Between BFRP Sheets and Concrete Under Dynamic Loading -- 2.2.1 Experimental Program -- 2.2.2 Bond Stress Under Dynamic Loading -- 2.2.3 Ultimate Load Under Dynamic Loading -- 2.2.4 Bond-Slip Relationship Under Dynamic Loading -- 2.3 Dynamic Bond Stress-Slip Relationship Between BFRP Sheets and Concrete Under Initial Static Loading -- 2.3.1 Experimental Program -- 2.3.2 Failure Modes -- 2.3.3 Maximum Dynamic Bond Stress -- 2.3.4 Dynamic Effective Bond Length -- 2.3.5 Dynamic Ultimate Load -- 2.3.6 Dynamic Bond-Slip Relationship -- 2.4 Summary -- References -- 3 Retrofitting of Reinforced Concrete Beam with BFRP Sheets -- 3.1 Influence of Initial Cracks on the Frequency of RC Box Beam -- 3.1.1 Experimental Program -- 3.1.2 Test Result of Natural Frequency.
3.1.3 Theoretical Analysis on Natural Frequency -- 3.1.4 Comparison on the Analytical Results and Test Data of Natural Frequency -- 3.1.5 Test Result of Deflection -- 3.1.6 Comparison on the Analytical Result and Test Data of Deflection -- 3.2 Behavior of RC Box Beam with Initial Cracks Retrofitted with BFRP Sheets -- 3.2.1 Experimental Program -- 3.2.2 Load-Bearing Capacity -- 3.2.3 Cracking Characteristics -- 3.2.4 Stiffness of Specimens -- 3.2.5 Strain Distribution in BFRP Sheets -- 3.3 Behavior of Reinforced Concrete Box Beam Retrofitted with BFRP Using End Anchorage in Grooving -- 3.3.1 Experimental Program -- 3.3.2 Failure Mode and Cracking Characteristics -- 3.3.3 Ductility of Specimens -- 3.3.4 Load-Bearing Capacity of Specimens -- 3.3.5 Stiffness and Natural Frequency -- 3.3.6 Relationship Between Load and Strain -- 3.4 Behavior of Reinforced Concrete Box Beam Retrofitted with BFRPs Using Steel Plate Anchorage -- 3.4.1 Experimental Program -- 3.4.2 Analysis on Cracking Characteristics -- 3.4.3 Analysis on Ductility -- 3.4.4 Analysis on Load-Bearing Capacity -- 3.4.5 Stiffness and Natural Frequency -- 3.4.6 Relationship Between Load and Strain -- 3.5 Summary -- References -- 4 Retrofitting of Corrosion-Damaged Reinforced Concrete Columns with BFRPs -- 4.1 Seismic Performance of Corrosion-Damaged Columns -- 4.1.1 Experimental Program -- 4.1.2 Failure Modes -- 4.1.3 Hysteretic Capacity -- 4.1.4 Skeleton Curves -- 4.1.5 Ductility and Load-Bearing Capacity -- 4.2 Seismic Performance of Corrosion-Damaged Columns Retrofitted with BFRP Sheets -- 4.2.1 Specimen Design and Fabrication -- 4.2.2 Failure Modes -- 4.2.3 Hysteretic Response -- 4.2.4 Skeleton Curves -- 4.2.5 Ductility and Load-Bearing Capacity -- 4.3 Summary -- References -- 5 Retrofitting of Corrosion-Damaged Reinforced Concrete Beam-Column Joints with BFRP Sheets. 5.1 Seismic Performance of Corrosion-Damaged Beam-Column Joints -- 5.1.1 Experimental Program -- 5.1.2 Crack Pattern and Failure Modes -- 5.1.3 Hysteretic Response and Load-Bearing Capacity -- 5.1.4 Relationship Between Half-Cell Potentials, Corrosion Rate, and Load-Bearing Capacity -- 5.1.5 Stiffness Degradation -- 5.1.6 Ductility -- 5.1.7 Energy Dissipation Capacity -- 5.1.8 Strains Profiles of Reinforcing Bars -- 5.2 Seismic Performance of Corrosion-Damaged Beam-Column Joints Retrofitted with BFRP Sheets -- 5.2.1 Experimental Program -- 5.2.2 Crack Pattern and Failure Modes -- 5.2.3 Hysteretic Response and Load-Bearing Capacity -- 5.2.4 Stiffness Degradation -- 5.2.5 Ductility -- 5.2.6 Energy Dissipation Capacity -- 5.2.7 Strains Profiles of Reinforcing Bars -- 5.3 Retrofitting of Seismic-Damaged Beam-Column Joints Under Different Corrosion Rates with BFRP Sheets -- 5.3.1 Experimental Program -- 5.3.2 Crack Pattern and Failure Modes -- 5.3.3 Hysteretic Response and Skeleton Curves -- 5.3.4 Displacement Ductility -- 5.3.5 Stiffness Degradation -- 5.3.6 Energy Dissipation Capacity -- 5.3.7 Analysis of Shear Strength -- 5.4 Seismic Performance of Beam-Column Joints Retrofitted with BFRP Sheets in Different Methods -- 5.4.1 Experimental Program -- 5.4.2 Crack Pattern and Failure Modes -- 5.4.3 Hysteretic Response and Load-Displacement Curves -- 5.4.4 Ductility -- 5.4.5 Stiffness Degradation -- 5.4.6 Energy Dissipation Capacity -- 5.4.7 Shear Deformation of Core Area -- 5.4.8 Strains of Reinforcements, Stirrups, and BFRP Sheets -- 5.5 Summary -- References -- 6 Retrofitting of Corrosion-Damaged Reinforced Concrete Shear Walls with BFRP Sheets -- 6.1 Seismic Performance of Corrosion-Damaged Shear Walls -- 6.1.1 Experimental Program -- 6.1.2 Relationship Between Half-Cell Potentials, Corrosion Rate, and Load-Bearing Capacity -- 6.1.3 Crack Pattern. 6.1.4 Hysteretic Response and Skeleton Curves -- 6.1.5 Stiffness Degradation -- 6.1.6 Ductility and Energy Dissipation Capacity -- 6.1.7 Analysis of Shear Strength -- 6.1.8 Simulation Analysis on Shear Wall -- 6.2 Seismic Performance of Corrosion-Damaged Shear Walls Retrofitted with BFRP Sheets -- 6.2.1 Experimental Program -- 6.2.2 Crack Patterns and Failure Modes -- 6.2.3 Hysteretic Response and Load-Displacement Curves -- 6.2.4 Stiffness Degradation -- 6.2.5 Ductility and Energy Dissipation Capacity -- 6.2.6 Theoretical Modeling -- 6.3 Seismic Performance of Shear Walls Retrofitted with BFRP Sheets in Different Methods -- 6.3.1 Experimental Program -- 6.3.2 Crack Patterns and Failure Modes -- 6.3.3 Hysteretic Behavior -- 6.3.4 Ductility -- 6.3.5 Stiffness Characteristic -- 6.3.6 Energy Dissipation Capacity -- 6.3.7 Calculation on Load-Bearing Capacity -- 6.4 Summary -- References -- 7 Bond Behavior Between BFRP Bars and Concrete Under Static and Dynamic Loading -- 7.1 Bond Stress-Slip Relationship Between BFRP Bars and Concrete Under Static Loading -- 7.1.1 Experimental Program -- 7.1.2 Failure Modes -- 7.1.3 Bond Stress-Slip Relationship Between BFRP Bar and Concrete -- 7.1.4 Bond Strength with Different BFRP Bar Diameters -- 7.1.5 Effect of BFRP Bar Diameter and Concrete Strength on Slip Corresponding to the Bond Strength -- 7.1.6 Bond Strength with Different Concrete Strengths -- 7.1.7 Prediction Model for Bond Stress-Slip Relationship -- 7.2 Bond Behavior of Concrete Members Reinforced with BFRP Bars Under Cyclic Loading -- 7.2.1 Experimental Program -- 7.2.2 Failure Modes -- 7.2.3 Bond Stress-Slip Relationship of Concrete Members Reinforced with BFRP Bars -- 7.2.4 Bond Strength Under Cyclic Loading -- 7.2.5 Slip Corresponding to Bond Strength Under Cyclic Loading. 7.2.6 Prediction Model for Bond Stress-Slip Relationship Under Dynamic Loading -- 7.3 Bond Behavior Between BFRP Bars and Concrete Under Cyclic Loading -- 7.3.1 Experimental Program -- 7.3.2 Failure Modes -- 7.3.3 Bond Stress-Slip Relationship Between BFRP Bars and Concrete Under Cyclic Loading -- 7.3.4 Bond Strength Under Number of Cycles Loading -- 7.3.5 Slip Corresponding to Bond Strength Under Number of Cycles Loading -- 7.3.6 Hysteretic Curve Area Under Number of Cycles Loading -- 7.3.7 Comparisons on Bond Strength and Corresponding Slip Under Static and Cyclic Loading -- 7.4 Summary -- References. |
Record Nr. | UNINA-9910872192903321 |
Shen Dejian
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Singapore : , : Springer Singapore Pte. Limited, , 2024 | ||
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Lo trovi qui: Univ. Federico II | ||
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Service Life and Durability of Reinforced Concrete Structures : Selected Papers of the 8th International RILEM PhD Workshop held in Marne-la-Vallée, France, September 26-27, 2016 / / edited by Carmen Andrade, Joost Gulikers, Elisabeth Marie-Victoire |
Edizione | [1st ed. 2019.] |
Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019 |
Descrizione fisica | 1 online resource (XX, 172 p. 116 illus., 93 illus. in color.) |
Disciplina | 620.13623 |
Collana | RILEM Bookseries |
Soggetto topico |
Building materials
Structural materials Mechanics Mechanics, Applied Building Materials Structural Materials Theoretical and Applied Mechanics |
ISBN | 3-319-90236-9 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | Part 1: Concrete properties and initiation period processes -- Effect of LDH nano-flakes on the mechanical and transport properties of lightweight concrete, by Z. Y. Qu, Q.L. Yu, and H.J.H. Brouwers -- Using thymolphthalein for accelerated carbonation testing of high volume fly ash cementitious blends, by Rui Reis, Aires Camões, and Manuel Ribeiro -- Durability and Mechanical Properties of CNT Cement Composites, by Carmen Camacho-Ballesta, Óscar Galao, Francisco Javier Baeza, Emilio Zornoza, and Pedro Garcés -- Advances in coal bottom ash use as a new common Portland cement constituent, by Cristina Argiz, Esperanza Menéndez, and Amparo Moragues -- Part 2: Techniques of characterization of corrosion and degradation -- Numerical Simulations for the detection of leakages in bridge deck membranes through resistivity measurements, by Carla Driessen and Michael Raupach -- Numerical and experimental development of gradient potential measurement for corrosion detection in reinforced concrete, by S. Garcia and F. Deby -- Advances in Characterization of Gas Transport in Concrete: Determination of Oxygen Diffusion Coefficient from Permeability Coefficient and Porosity, by P. Linares, C. Andrade, and D. Baza -- Petrographic Study of Siliceous Aggregates. Parametric Calculus of the Reactivity With the Alkalis, by R. García-Rovés Loza, E. Méndez, and N. Prendes Rubiera -- Part 3: Behaviour of corroded structures -- Corrosion-Induced Degradation of Reinforced Concrete Elements: Preliminary Results, by O. Loukil, L. Adelaide, V. Bouteiller, M. Quiertant, T. Chaussadent, F.Ragueneau, X. Bourbon, and L. Trenty -- Part 4: Corrosion prevention and repair techniques -- Development of a test Method for the Durability of Carbon Textiles under Anodic Polarisation, by Amir Asgharzadeh and Michael Raupach -- Corrosion processes of carbonated chloride-contaminated reinforced concrete and electrochemical chloride extraction (ECE) efficiency, by Yolaine Tissier, Véronique Bouteiller, Elisabeth Marie Victoire, Suzanne Joiret, and Thierry Chaussadent. . |
Record Nr. | UNINA-9910337466603321 |
Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019 | ||
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Lo trovi qui: Univ. Federico II | ||
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