1.Lateral Load Resistance: Shear walls are designed to resist horizontal or lateral loads, such as those generated by seismic activity. These walls effectively transfer the lateral forces from the upper levels of the building to the foundation, preventing excessive building sway or collapse during an earthquake.
2.Structural Stiffness: Shear walls increase the overall stiffness of a building. By introducing vertical elements, they improve the structural rigidity and reduce the building’s lateral deflections under seismic loads. This stiffness helps in controlling the building’s behavior during an earthquake and reduces damage to non-structural elements.
3.Energy Dissipation: Shear walls also play a role in dissipating seismic energy. During an earthquake, they absorb and redistribute the energy generated by the ground motion. This energy dissipation helps reduce the overall forces transmitted to the rest of the structure, thereby improving its seismic performance.
4.Vertical Load Resistance: Shear walls not only resist lateral loads but also provide vertical load-carrying capacity. They contribute to the overall strength of the building by bearing vertical gravity loads and transmitting them to the foundation.
5.Reducing Torsion: Shear walls help mitigate the torsional effects induced by seismic forces. By distributing the lateral forces evenly throughout the structure, they minimize any twisting or rotational movements that can occur during an earthquake.
6.Redundancy and Reducing Localized Damage: Incorporating multiple shear walls strategically throughout a building provides redundancy in the lateral load path. In the event of localized damage to one shear wall, the others can still contribute to the overall stability of the structure.