Shear behavior of short studs in steel-thin ultrahigh-performance concrete composite structures

Steel-concrete composite structures gradually tend to be thinner and lighter in modern bridge engineering. Ultrahigh-performance concrete (UHPC) as an innovative solution has been used to upgrade the behavior of composite structures and accelerate construction, and short stud connectors are the key elements to guarantee the effective connection of steel and concrete components. This study conducted push-out test to explore the failure modes and load-slip relationships of short studs in steel-thin UHPC composite structures (STUCs). The experimental findings revealed that the fracture of the stud shank and local concrete crushing dominated the failure modes of all specimens. Increasing stud diameter could enhance shear strength, while arranging short studs densely and decreasing stud height could result in the reduction of shear capacity of a single stud. The experiment data were employed for the construction and verification of the finite element models. The impact of several parameters on the shear strength was investigated via the validated numerical models. The shear strength increased approximately linearly with stud diameter for short studs in thin UHPC layers, but the cover thickness and UHPC strength had a slight impact. The shear capacity of short studs couldn't be negatively impacted by reducing the aspect ratio to 3.16. In addition, the ultimate shear capacity significantly decreased due to the grouped stud effect for grouped short studs when the spacing between the studs was less than 70 mm. The shear capacity was conservatively predicted by these specifications for short studs in thin UHPC layer, according to the comparison of the simulated data with the existing construction specifications. Finally, a new equation considering multiple parameters was proposed and validated by the test data, which could precisely predict the shear strength of short studs in STUCs.