Abstract
The bolted T-stub connection joining beam with column is being widely applied. To enhance the energy dissipation capacity of conventional T-stub connections, two rectangular plates are proposed to be inserted between the T-stub and column, so that the T-stub flange can yield both under tensile and compressive loads. This study put forward a mechanical model of a new T-stub connection with inserted plates and investigated important factors that could affect its mechanical behavior through experimental tests. Thirty specimens were designed with different configurations that differed according to the existence or absence of inserted plates, the fabrication method and the width of inserted plates. These configurations were tested under axial and cyclic loading conditions, and results showed that the proposal aiming to improve the energy dissipation capacity was feasible. The mechanical model presented coincided with the test observation and data. The advent of two inserted plates elevated the load bearing capacity, stiffness and ductility of connections under compression, whereas in tension the properties were not substantially enhanced. The welded T-stub connections outperformed those cut from standard section steel. The energy dissipated by connections with inserted plates was about 150% of that by traditional connections without inserted plates. Only within a reasonable range can the increment of plate width promote the energy dissipation capacity of T-stub connections. The optimum width of plates in terms of energy consumption accounted for around 31% of the overall width of connections.
Highlights
Beam-to-column joints are critical to ensuring that beams and columns work together to assemble whole building structures while resisting external loads
For evaluating the dissipative capacities of the T-stub connections with inserted plates and investigating the optimum width of plates, a total of 11 specimens were tested under the low-cycle loading conditions
All other specimens in group T-stub Connection (TC) and WA demonstrated the bidirectional deformation of tension and compression, and experienced uplift or depression alternately under hysteretic loads, which can be confirmed by the wave deformation on each flange and through the cracks adjacent to the flangeother specimens in group TC
Summary
Beam-to-column joints are critical to ensuring that beams and columns work together to assemble whole building structures while resisting external loads. The design principle of those improved beam-to-column joints is either to strengthen the end of the beam or to weaken the beam section, so that the location of a plastic hinge on the beam can be a certain distance from the column during an earthquake, which deepens the seismic understanding of strong joints and weak components. In these improved connections, it is the frame beams
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