Behavior of RC Beam–Column Joints Strengthened with Modified Reinforcement Techniques
Abstract
:1. Introduction
1.1. Interior Beam–Column Joint
1.2. Corner RC Beam–Column Joint
- Around the corner, the tension steel is persistent, i.e., there is no lapping in the joint;
- The tension bars have to be curved into a radius that prevents the bars from bending or breaking. Nominal transverse bars are placed beneath the bent bars;
- Only a certain quantity of tension reinforcement is allowed [32].
2. Detailing Recommendations for Joints
- Anchorage: Due to loss of bond at the inner face of an exterior joint, the development length of the beam reinforcement should be computed from the beginning of the 90° bend, rather than the face of the column. In wide columns, any portion of the beam bars within the outer third of the column could be considered for the computed development length. For shallow columns, the use of stub beams will be imperative. A large-diameter bearing bar fitted along the 90° bend of the beam bars should be beneficial in distributing bearing stresses. In deep columns, and whenever straight beam bars are preferred, mechanical anchorage could be advantageous. Joint ties should be so arranged that the critical outer-column bars and the bent-down portions of the bars are held against the core of the joint;
- Shear Strength: When the computed axial compression on the column is small, the contribution of the concrete shear resistance should be ignored, and shear reinforcement for the entire joint-shearing force should be provided. In exterior joints, only the ties that are situated in the outer two-thirds of the length of the potential diagonal failure crack, which runs from corner to corner of the joint, should be considered to be effective. The joint shear to be carried by the ties is calculated as:For preventing the excessive diagonal compression of core concrete, an upper bound for joint shear, usually stated as a nominal shearing force, must be imposed. The value between 10√f′c and 11.5√f′c (psi) is recommended for beams;
- Confinement: Horizontal tie legs are ineffectual for providing constraint against the concrete core volumetric expansion, while shear reinforcement restricts only the joint’s corner regions. As a result, extra confining bars at right angles to the shear reinforcement are required. The distance between these bars should not exceed 150 mm.
- Cl-7.4.1 Special confining reinforcement (lo) (unless shear strength considerations demand a larger amount of transverse reinforcement) should be provided across a span of every joint face, towards the mid-span, and on each side of any area where flexural yielding may occur owing to earthquake pressures. The length ‘lo’ should not be less than (a) the member’s greater lateral dimension at the section where yielding occurs, (b) 1/6 of the member’s clear span, and (c) 450 mm;
- Cl-8.1 Unless the joint is confined, the special confining reinforcement necessary at the column end must also be carried through the joint;
- Cl-8.2 A connection with beams framing all vertical sides, with each beam having a width of at least 3/4 of the column width, may be given half of the special restricting reinforcement needed at the column’s end. The hoops’ spacing shall not be more than 150 mm;
- In the joint region, diagonal cracking and concrete crushing can be managed by providing large column dimensions and densely packed closed-loop steel ties surrounding the column bars. The ties help resist the shear stress and hold the concrete in the joint, hence preventing concrete cracking and crushing;
- The transverse loop should continue around the joint region around the column bars. This is cultivated by setting up the instance of all bar supports (both longitudinal bars and stirrups) on top of the shaft formwork at that level and lower into the case;
- The building columns in seismic zones III, IV, and V are to be at least 300-mm wide in each direction of the cross-section when the column support beams are longer than 5 m or when these columns are taller than 4 m between floors;
- A piece of the top pillar bar is consolidated in the segment that is projected up to the soffit of the bar, and a piece of it overhangs in segments with short widths and huge-breadth shaft bars;
- Beam bars may not reach past the soffit of the pillar if the section width is extensive;
- Interior joints need the top and base bars to go through the intersection without being cut, and these bars should be set inside the section bars without any twists;
- The American Concrete Institute suggests a segment width that is no less than multiple times the distance across the longest longitudinal bar in the adjoining pillar.
3. Experimental Program
Details of Specimens
4. Numerical Modeling and Analysis of Beam–Column Joints
5. Results Obtained by Numerical Modeling
5.1. Validation of Results
5.2. Load-Displacement Behaviour for Beam–Column Joints
6. Results and Discussions
6.1. Hysteretic Behavior of Corner and Interior Beam–Column Junctions
6.2. Shear Stress vs. Loading Cycle Behavior of Joints
6.3. Displacement Time History Curve for Beam–Column Joints
7. Conclusions
- Based on the present research, the most critical parameters influencing joint shear capacity are the stirrups quantity, the aspect ratio of the joint, the beam longitudinal reinforcement anchorage, and the compressive strength of concrete;
- The results obtained through the experimental studies were validated with numerical analysis in terms of load-deformation behavior, and the numerical results were in great concurrence with the experimental data;
- The findings of the finite-element model are compared to the controlled and strengthened specimens, and it is discovered that adding diagonal cross bars (modified reinforcing techniques) to beam–column joints exposed to cyclic loads enhances their performance more than using a controlled specimen in both interior and corner beam–column joints;
- The corner beam–column joint models for the controlled and strengthened specimens are analyzed for similar loadings with different reinforcement arrangements. The larger deformations and stresses, which are reported in the controlled specimen, are reduced in the strengthened specimens after employing modified reinforcement techniques;
- When the controlled and strengthened specimens for the interior beam–column joint are analyzed, it is found that the maximum stress and deformation caused in the joint are controlled by using additional diagonal cross bars at the joint region;
- Modified reinforcement techniques with the diagonal cross bar at the joint region is a viable option for enhancing the shear capacity of beam–column joints. The diagonal cross bars help to create an extra shear-transfer mechanism;
- A beam–column junction loses structural efficiency when it is exposed to large lateral stresses, such as high winds. Therefore, against such stresses, the specimens with a diagonal crossbar at the junction work best;
- In both upward- and downward-load situations, the introduction of cross-inclined bars at the junction area of a strengthened corner and an interior beam–column junction maximizes the joint’s stiffness, enhances its load-carrying capacity, as well as its ductility, according to an improved reinforcing approach.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
MRT | Modified reinforcement technique |
ICS | Controlled specimen of interior joint without MRT |
CCS | Controlled specimen of corner joint without MRT |
ISS | Strengthened specimen of interior joint with MRT |
CSS | Strengthened specimen of corner joint with MRT |
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Uniaxial Tensile Strength (MPa) | Poisson’s Ratio Value | Ultimate Uniaxial Compressive Strength (Mpa) | Modulus of Elasticity (Mpa) |
---|---|---|---|
0.62√fc | 0.2 | 25 | 5000√fc |
Poisson’s Ratio Value | Transverse Steel Yielding Stress (Mpa) | Longitudinal Steel Yielding Stress (Mpa) | Modulus of Elasticity (Mpa) |
---|---|---|---|
0.3 | 250 | 415 | 200,000 |
Parametric Specifications of Beam | Measurements (mm) | Parametric Specifications of Column | Measurements (mm) |
---|---|---|---|
Concrete cover | 30 | Concrete cover | 30 |
Span | 3000 | Column’s depth | 300 |
Depth | 400 | Width of column | 300 |
Width | 300 | Column height | 3500 |
Steel at bottom | 4–10 | Floor-to-floor height | 3250 |
Steel at top | 4–10 | Longitudinal steel | 4–12 |
Diameter of Transverse steel | 6 | Diameter of Transverse steel | 6 |
Spacing of Transverse steel | 220 | Spacing of Transverse steel | 200 |
Measured Parameter | Highest Value with No MRT | Highest Value Using MRT | Variation in% |
---|---|---|---|
Overall deformation (mm) | 0.87369 | 0.09106 | 89.5 |
Maximum Shear stress (MPa) | 19.92 | 9.0418 | 79.3 |
Maximum Shear strain (mm/mm) | 0.0065 | 0.00062 | 90.4 |
Measured Parameter | Highest Value with No MRT | Highest Value Using MRT | Variation in% |
---|---|---|---|
Overall deformation (mm) | 5.7922 | 0.13358 | 97.7 |
Maximum shear stress (MPa) | 52.112 | 10.808 | 79.3 |
Maximum shear strain (mm/mm) | 0.0009396 | 0.0003444 | 63.3 |
Specimen ID | Overall Deformation (mm) | Maximum Shear Stress (Mpa) | Maximum Principal Elastic Strain (mm/mm) |
---|---|---|---|
CS4 | 0.873 | 19.92 | 0.00062 |
SS4 | 0.091 | 9.924 | 0.00018 |
CS5 | 5.7922 | 52.11 | 0.00093 |
SS5 | 0.1336 | 10.81 | 0.00034 |
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Tiwary, A.K.; Singh, S.; Chohan, J.S.; Kumar, R.; Sharma, S.; Chattopadhyaya, S.; Abed, F.; Stepinac, M. Behavior of RC Beam–Column Joints Strengthened with Modified Reinforcement Techniques. Sustainability 2022, 14, 1918. https://doi.org/10.3390/su14031918
Tiwary AK, Singh S, Chohan JS, Kumar R, Sharma S, Chattopadhyaya S, Abed F, Stepinac M. Behavior of RC Beam–Column Joints Strengthened with Modified Reinforcement Techniques. Sustainability. 2022; 14(3):1918. https://doi.org/10.3390/su14031918
Chicago/Turabian StyleTiwary, Aditya Kumar, Sandeep Singh, Jasgurpreet Singh Chohan, Raman Kumar, Shubham Sharma, Somnath Chattopadhyaya, Farid Abed, and Mislav Stepinac. 2022. "Behavior of RC Beam–Column Joints Strengthened with Modified Reinforcement Techniques" Sustainability 14, no. 3: 1918. https://doi.org/10.3390/su14031918
APA StyleTiwary, A. K., Singh, S., Chohan, J. S., Kumar, R., Sharma, S., Chattopadhyaya, S., Abed, F., & Stepinac, M. (2022). Behavior of RC Beam–Column Joints Strengthened with Modified Reinforcement Techniques. Sustainability, 14(3), 1918. https://doi.org/10.3390/su14031918