Cyclic behavior of 3D moment connections subjected to bidirectional load: Experimental approach
Abstract
This paper presents an experimental research to assess the cyclic behavior of a bolted moment connection with the use of optimized end-plate connected to built-up box column subassemblies subjected to bidirectional and unidirectional loading. Seven real scale specimens were tested: three specimens with four beams connected to column as interior joint, two specimens with two beams connected as corner joint configuration and two specimens with two beams connected to column as interior joint, according the protocol established in AISC Seismic provisions. The seismic performance was evaluated in terms of hysteretic behavior, failure mechanism, stiffness and dissipated energy. The joints studied were manufactured from of hot-rolled I-beams and square built-up box columns. The elements of connection such as bolts, welding, outer stiffeners and end-plates were designed to remain in elastic range from the flexural expected capacity of beams. The results showed that the required minimum moment of 0.8Mp at 0.04 rad of drift angle was achieved for all specimens tested. However, a higher stiffness and resistance was reached in configuration with unidirectional load (interior joint) in comparison to joint subjected to bidirectional load (corner joint). The damage was concentrated uniquely in beams, while an elastic behavior in columns and connection components was reached for 0.04 rad of drift angle. Finally, this moment connection configuration can be used as an alternative to design buildings with special moment frames under bidirectional loading considering the cyclic behavior of joints evaluated.
Más información
Título según WOS: | Cyclic behavior of 3D moment connections subjected to bidirectional load: Experimental approach |
Título según SCOPUS: | ID SCOPUS_ID:85161510251 Not found in local SCOPUS DB |
Título de la Revista: | ENGINEERING STRUCTURES |
Volumen: | 291 |
Editorial: | ELSEVIER SCI LTD |
Fecha de publicación: | 2023 |
DOI: |
10.1016/J.ENGSTRUCT.2023.116392 |
Notas: | ISI, SCOPUS - WOS |