SHEAR CAPACITY AND CONFINEMENT REINFORCEMENT REQUIREMENTS ANALYSIS OF HOLLOW REINFORCED CONCRETE SQUARE COLUMNS
Columns play a crucial role in resisting axial compressive forces in structural systems, exemplified by their use as bridge piers. To mitigate shrinkage, hollow reinforced concrete columns (HRCC) emerge as a promising solution. HRCC effectively reduce self-weight, leading to a diminished seismic...
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| Format: | Final Project |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/82588 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Columns play a crucial role in resisting axial compressive forces in structural
systems, exemplified by their use as bridge piers. To mitigate shrinkage, hollow
reinforced concrete columns (HRCC) emerge as a promising solution. HRCC effectively
reduce self-weight, leading to a diminished seismic responsse. This aligns with
sustainable construction principles by minimizing concrete consumption. However, a
significant challenge arises from the lack of well-defined references pertaining to the
accurate calculation of shear capacity and confinement reinforcement requirements for
HRCC. This research addresses this gap by investigating the shear behavior of HRCC and
finding the key parameters for calculating their shear capacity. The research methodology
involves defining key parameters including cross-sectional width, effective height,
transverse reinforcement area, and effective confinement area. These parameters are
evaluated using analytical models from SNI 2847:2019, ACI 318-19, Ascheim et al.
(1992), Shin et al. (2013), AASHTO LRFD 2020, UCSD modified (2017), and
CALTRANS 2003. The calculated values are then compared with experimental data
obtained from literature. The findings demonstrate that employing an effective concrete
area definition that accounts for the hollow section (i.e., reduced area) yields more
accurate results. The Effective depth is the distance from the outermost compressive
concrete to the center of the tensile reinforcement. |
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