Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
A cast modular bracing system for steel special concentrically braced frames
Highlights ► Cast modular ductile bracing system is being developed as alternative to steel SBCFs. ► Capacity design factors have been developed to control the plastic mechanism. ► The system shows the potential for improved low-cycle fatigue life.
Abstract A Cast Modular Ductile Bracing System (CMDB) is under development as an alternative to special concentrically braced frames. The CMDB system introduces cast components at the ends and center of the brace in an attempt to produce a system with reliable strength, stiffness, and deformation capacity. A cruciform cross-section has been chosen for the cast component geometry, which is specially detailed to enhance energy dissipation and increase low cycle fatigue life thereby reducing the likelihood of fracture. In this paper, capacity design parameters are established that describe the axial strength and flexural strength of the cast components relative to the main hollow structural section member. These parameters are varied in 2D finite element models to understand the nature of the system and identify the best performing designs. 3D FE models of the CMDB system and a typical special concentrically braced frame, in combination with fracture indices, are used to compare the expected low cycle fatigue life of the two systems.
A cast modular bracing system for steel special concentrically braced frames
Highlights ► Cast modular ductile bracing system is being developed as alternative to steel SBCFs. ► Capacity design factors have been developed to control the plastic mechanism. ► The system shows the potential for improved low-cycle fatigue life.
Abstract A Cast Modular Ductile Bracing System (CMDB) is under development as an alternative to special concentrically braced frames. The CMDB system introduces cast components at the ends and center of the brace in an attempt to produce a system with reliable strength, stiffness, and deformation capacity. A cruciform cross-section has been chosen for the cast component geometry, which is specially detailed to enhance energy dissipation and increase low cycle fatigue life thereby reducing the likelihood of fracture. In this paper, capacity design parameters are established that describe the axial strength and flexural strength of the cast components relative to the main hollow structural section member. These parameters are varied in 2D finite element models to understand the nature of the system and identify the best performing designs. 3D FE models of the CMDB system and a typical special concentrically braced frame, in combination with fracture indices, are used to compare the expected low cycle fatigue life of the two systems.
A cast modular bracing system for steel special concentrically braced frames
Ward, K.M. (Autor:in) / Fleischman, R.B. (Autor:in) / Federico, G. (Autor:in)
Engineering Structures ; 45 ; 104-116
16.05.2012
13 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
A cast modular bracing system for steel special concentrically braced frames
| Online Contents | 2012
Fuse performance on bracing of concentrically steel braced frames under cyclic loading
| Online Contents | 2014