Structural steel semirigid connections : theory, design and software

Although the semirigidity concept was introduced many years ago, steel structures are usually designed by assuming that beam-to-column joints are either pinned or rigid. Theses assumptions allow a great simplification in structural analysis and design-but they neglect the true behavior of joints. The economic and structural benefits of semirigid joints are well known and much has been written about their use in braced frames. However, they are seldom used by designers, because most semirigid connections have highly nonlinear behavior, so that the analysis and design of frames using them is difficult. In fact, the design problem becomes more difficult as soon as the true rotational behavior of beam-to-column joints is accounted for-the design problem requires many attempts to achieve a safe and economical solution. Structural Steel Semirigid Connections provides a comprehensive source of information on the design of semirigid frames, up to the complete detailing of beam-to-column connections, and focuses on the prediction of the moment-rotation curve of connections. This is the first work that contains procedures for predicting the connection plastic rotation supply-necessary for performing the local ductility control in nonlinear static and dynamic analyses. Extensive numerical examples clarify the practical application of the theoretical background. This exhaustive reference and the awareness it provides of the influence of joint rotational behavior on the elastic and inelastic responses of structures will greatly benefit researchers, professionals, and specification writing bodies devoted to structural steel.

Behavior of Semirigid Frames Introduction Frame Classification. Influence of Joint Behavior on Unbraced Frame Response Influence of Joint Behavior on Brace Frame Response Classification of Joints Modeling of Joint Behavior Introduction Methods for Modeling Rotational Behavior Mathematical Representation of Moment-Rotation Curves Methods for Predicting Moment-Rotation Curves Welded Connections Introduction Column Web in Shear Column Web in Compression Column Web in Tension Considerations on Local Stress Interaction Column Flange in Bending Beam Flange and Web in Compression Comparison with Experimental Data Influence of Strain-Hardening Worked Examples Basic Component of Bolted Connections Introduction Axial Strength Bolted T-Stubs Axial Stiffness of Bolted T-Stubs Bolted End-Plate Connections Introduction Prediction of Flexural Resistance Prediction of Initial Rotational Stiffness Moment Rotation Curve Worked Examples Bolted Connections with Angles Introduction Prediction of Flexural Resistance Operative Steps Comparison with Experimental Data Simplified Procedure Prediction of Rotational Stiffness Worked Example JMRC: A Computer Program for Evaluating Joint Moment Rotation Curve Analyzed Joint Typologies Description of Input Data Examples of Input Data Files Adopted Formulations Design of Extended End Plate Connections for Braced Frames Introduction Behavior and Design of End Plate Connections Design Procedure for Braced Frames Applications Ductility of Connections Introduction Plastic Rotation Supply of the Beam-Joint System Welded Connections Bolted Connections Parameters Affecting Ductility Ultimate Plastic Rotation of Connections with Angles Ultimate Plastic Rotation of End-Plate Connections Cyclic Behavior of Beam-to-Column Joints Introduction Experimental Evidence Low Cycle Fatigue Modeling of Cyclic Response Seismic Design of Semirigid Frames Introduction Connection and Panel Zone Design Second-Order Plastic Design of Moment Resisting Frames The Influence of Beam-to-Column Joints Parametric Analysis Dynamic Inelastic Analyses