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Design and Analysis of Connections in Steel Structures : Fundamentals and Examples /

The book introduces all the aspects needed for the safe and economic design and analysis of connections using bolted joints in steel structures. This is not treated according to any specific standard but making comparison among the different norms and methodologies used in the engineering practice,...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Boracchini, Alfredo
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Newark : Wilhelm Ernst & Sohn Verlag fur Architektur und Technische, 2018.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover; Title Page; Copyright; Preface; About the Author; Contents; Acknowledgments; List of Abbreviations; Chapter 1 Fundamental Concepts of Joints in Design of Steel Structures; 1.1 Pin Connections and Moment Resisting Connections; 1.1.1 Safety, Performance, and Costs; 1.1.2 Lateral Load Resisting System; 1.1.3 Pins and Fully Restrained Joints in the Analysis Model; 1.2 Plastic Hinge; 1.2.1 Base Plates; 1.2.2 Trusses; References; Chapter 2 Fundamental Concepts of the Behavior of Steel Connections; 2.1 Joint Classifications; 2.2 Forces in the Calculation Model and for the Connection.
  • 2.3 Actions Proportional to Stiffness2.4 Ductility; 2.5 Load Path; 2.6 Ignorance of the Load Path; 2.7 Additional Restraints; 2.8 Methods to Define Ultimate Limit States in Joints; 2.9 Bolt Resistance; 2.10 Yield Line; 2.11 Eccentric Joints; 2.12 Economy, Repetitiveness, and Simplicity; 2.13 Man-hours and Material Weight; 2.14 Diffusion Angles; 2.15 Bolt Pretensioning and Effects on Resistance; 2.15.1 Is Resistance Affected by Pretensioning?; 2.15.2 Is Pretensioning Necessary?; 2.15.3 Which Pretensioning Method Should Be Used?; 2.16 Transfer Forces; 2.17 Behavior of a Bolted Shear Connection.
  • 2.18 Behavior of Bolted Joints Under TensionReferences; Chapter 3 Limit States for Connection Components; 3.1 Deformation Capacity (Rotation) and Stiffness; 3.1.1 Rotational Stiffness; 3.2 Inelastic Deformation due to Bolt Hole Clearance; 3.3 Bolt Shear Failure; 3.3.1 Threads Inside the Shear Plane; 3.3.2 Number of Shear Planes; 3.3.3 Packing Plates; 3.3.4 Long Joints; 3.3.5 Anchor Bolts; 3.3.6 Stiffness Coefficient; 3.4 Bolt Tension Failure; 3.4.1 Countersunk Bolts; 3.4.2 Stiffness Coefficient; 3.5 Bolt Failure in Combined Shear and Tension; 3.6 Slip-Resistant Bolted Connections.
  • 3.6.1 Combined Shear and Tension3.7 Bolt Bearing and Bolt Tearing; 3.7.1 Countersunk Bolts; 3.7.2 Stiffness Coefficients; 3.8 Block Shear (or Block Tearing); 3.9 Failure of Welds; 3.9.1 Weld Calculation Procedures; 3.9.1.1 Directional Method; 3.9.1.2 Simplified Method; 3.9.2 Tack Welding (Intermittent Fillet Welds); 3.9.3 Eccentricity; 3.9.4 Fillet Weld Groups; 3.9.5 Welding Methods; 3.9.6 Inspections; 3.9.6.1 Visual Testing; 3.9.6.2 Penetrant Testing; 3.9.6.3 Magnetic Particle Testing; 3.9.6.4 Radiographic Testing; 3.9.6.5 Ultrasonic Testing; 3.10 T-stub, Prying Action.
  • 3.10.1 T-stub with Prying Action3.10.2 Possible Simplified Approach According to AISC; 3.10.3 Backing Plates; 3.10.4 Length Limit for Prying Forces and T-stub without Prying; 3.10.5 T-stub Design Procedure for Various "Components" According to Eurocode; 3.10.5.1 Column Flange; 3.10.5.2 End Plate; 3.10.5.3 Angle Flange Cleat; 3.10.6 T-stub Design Procedure for Various "Components" According to the "Green Book"; 3.10.6.1 èff for Equivalent T-stubs for Bolt Row Acting Alone; 3.10.6.2 èff to Consider for a Bolt Row Acting Alone; 3.10.6.3 èff to Consider for Bolt Rows Acting in Group.