Strength Enhancement of Interlocking Hollow Brick Masonry Walls with Low-Cost Mortar and Wire Mesh
Abstract
:1. Introduction
2. Details of Experimental Program
3. Dimensional Details of Masonry Walls
4. Materials
5. Strengthening of CCIHBM Walls
6. Load and Instrumentation
7. Results and Discussion
7.1. Axial Load versus Deformation Responses
7.2. Load Behavior of CCIHBM Walls
7.3. Ductility of the CCIHBM Walls
7.4. Failures of CCIHBM Walls
8. Conclusions
- The ultimate failure of control masonry wall was very brittle and sudden. The control CCIHBM wall, i.e., W-CON, failed at an ultimate load of 247 kN, and the corresponding deflection was 1.8 mm.
- The ultimate failure modes of the CEMENT mortar with wire mesh strengthened CCIHBM walls were found to be ductile.
- For the cement mortar and wire-mesh-strengthened walls, i.e., W-PC1-10-1W and W-PC1-10-3W, the ultimate axial deformation was increased by 150% and 233%, respectively, as compared to the control wall, i.e., W-CON.
- The ultimate load carrying capacity of CCIHBM walls W-PC1-10-1W and W-PC1-10-3W was increased by 66% and 143%, respectively, as compared to the control wall, i.e., W-CON.
- Based on experimental results, it can be concluded that the use of CEMENT mortar and wire-mesh is practical. However, there is need to evaluate and compare the performance of this method with other techniques.
- Future studies also required to develop constitutive material models for CCIHBM walls strengthened with cement mortar and wire mesh using finite element analysis and analytical studies.
Author Contributions
Funding
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
List of Abbreviations
CCIHBM | Clay Interlocking Hollow Brick Masonry |
CCIHB | Clay Interlocking Hollow Brick |
OPC | Ordinary Portland Cement |
FRP | Fibre Reinforced Polymers |
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Wall Specimen | Strengthening Material | Thickness (mm) | Type of Cement |
---|---|---|---|
W-CON | - | - | - |
W-PC1-10 | Cement mortar | 10 | OPC Type 1 |
W-PC1-20 | Cement mortar | 20 | OPC Type 1 |
W-PC2-20 | Cement mortar | 20 | OPC Type 2 |
W-PC1-10-1W | Cement mortar + Wire Mesh | 10 | OPC Type 1 |
W-PC1-10-3W | Cement mortar + Wire Mesh | 20 | OPC Type 1 |
Test Walls | Load (kN) | Deflection (mm) | Initial Stiffness (kN/mm) |
---|---|---|---|
W-CON | 247 | 1.8 | 235 |
W-PC1-10 | 278 | 4.0 | 295 |
W-PC1-20 | 336 | 2.0 | 414 |
W-PC2-20 | 510 | 2.2 | 500 |
W-PC1-10-1W | 410 | 4.5 | 498 |
W-PC1-10-3W | 600 | 6.0 | 524 |
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Joyklad, P.; Ali, N.; Rashid, M.U.; Hussain, Q.; Magbool, H.M.; Elnemr, A.; Chaiyasarn, K. Strength Enhancement of Interlocking Hollow Brick Masonry Walls with Low-Cost Mortar and Wire Mesh. Infrastructures 2021, 6, 166. https://doi.org/10.3390/infrastructures6120166
Joyklad P, Ali N, Rashid MU, Hussain Q, Magbool HM, Elnemr A, Chaiyasarn K. Strength Enhancement of Interlocking Hollow Brick Masonry Walls with Low-Cost Mortar and Wire Mesh. Infrastructures. 2021; 6(12):166. https://doi.org/10.3390/infrastructures6120166
Chicago/Turabian StyleJoyklad, Panuwat, Nazam Ali, Muhammad Usman Rashid, Qudeer Hussain, Hassan M. Magbool, Amr Elnemr, and Krisada Chaiyasarn. 2021. "Strength Enhancement of Interlocking Hollow Brick Masonry Walls with Low-Cost Mortar and Wire Mesh" Infrastructures 6, no. 12: 166. https://doi.org/10.3390/infrastructures6120166
APA StyleJoyklad, P., Ali, N., Rashid, M. U., Hussain, Q., Magbool, H. M., Elnemr, A., & Chaiyasarn, K. (2021). Strength Enhancement of Interlocking Hollow Brick Masonry Walls with Low-Cost Mortar and Wire Mesh. Infrastructures, 6(12), 166. https://doi.org/10.3390/infrastructures6120166