Title:
Shear-Reinforced Concrete Breakout Failure in Tension-Loaded Anchor Groups
Author(s):
Benjamin L. Worsfold, Dara Karac, and Jack P. Moehle
Publication:
Structural Journal
Volume:
122
Issue:
6
Appears on pages(s):
169-181
Keywords:
anchor reinforcement; anchoring to concrete; concrete breakout; foundations; shear reinforcement; supplementary reinforcement
DOI:
10.14359/51746720
Date:
9/1/2025
Abstract:
Steel columns are commonly attached to concrete foundations with groups of cast-in-place headed anchors. Recent physical tests and simulations have shown that the strength of these connections can be limited by concrete breakout failure. Four full-scale physical specimens of axially loaded columns attached to a foundation slab were tested, varying the shear reinforcement configuration in the slab. All specimens were governed by concrete breakout failure. The tests suggest that adequately placed distributed shear reinforcement can increase connection strength and displacement capacity. Steep cone failures were observed to limit the beneficial effect of shear reinforcement. Calibrated finite element models were used to investigate critical parameters such as the extent of the shear-reinforced region and bar spacing. A design approach is proposed to calculate connection strength by adding the strength of the concrete and the distributed shear reinforcement. Design detailing is discussed.
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