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SEISMIC FORCE RESISTING SYSTEMS AND RESPONSES OF CONCRETE BUILDINGS TO SEISMIC FORCES

SEISMIC FORCE RESISTING SYSTEMS AND RESPONSES OF CONCRETE BUILDINGS TO SEISMIC FORCES. TOPICS COVERED. Seismic Force Resisting Systems Building Configuration Response of Concrete Buildings. SEISMIC FORCE RESISTING SYSTEMS.

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SEISMIC FORCE RESISTING SYSTEMS AND RESPONSES OF CONCRETE BUILDINGS TO SEISMIC FORCES

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  1. SEISMIC FORCE RESISTING SYSTEMS AND RESPONSES OF CONCRETE BUILDINGS TO SEISMIC FORCES

  2. TOPICS COVERED • Seismic Force Resisting Systems • Building Configuration • Response of Concrete Buildings

  3. SEISMIC FORCE RESISTING SYSTEMS • Basic structure systems that may be used to resist earthquake forces include • Moment-Resisting Frame Systems • Bearing Wall Systems • Dual System • Building Frame System • Inverted Pendulum System

  4. MOMENT-RESISTING FRAME SYSTEMS • A structural system with complete space frame for gravity loads • Lateral forces are resisted by flexural action of frame members • Entire space frame or portion may be designated as seismic-force-resisting system • Three types of detailing of frames are possible based on the effects of seismic forces • Ordinary RC frames • Intermediate moment frames • Special moment frames

  5. BEARING WALL SYSTEMS • A structural system without complete space frame for gravity loads • Bearing walls provide support for gravity loads • Lateral loads are also resisted by the bearing walls acting as shear walls • Two types of detailing of walls are possible based on the effects of seismic forces • Ordinary RC shear walls • Special RC shear walls

  6. DUAL SYSTEMS • A structural system with the following features • Complete space frame for gravity loads • 25% base shear resisted by space frames • Resistance to lateral force is provided by the shear walls • Moment frames are either special or intermediate frames • Different combinations of shear walls are possible including • Ordinary RC shear walls • Special RC shear walls

  7. BUILDING FRAME SYSTEMS • A structural system without complete space frame for gravity loads • Lateral loads are resisted by the shear walls • No interaction between the shear wall and frames is considered in the lateral load analysis • Two types of detailing of walls are possible based on the effects of seismic forces and building height • Ordinary RC shear walls • Special RC shear walls

  8. INVERT PENDULUM SYSTEMS • Structures that have a large portion of mass concentrated near the top • Essentially one degree of freedom • Little redundancy and overstrength • Inelastic behaviour concentrated at the base • Less energy dissipation capacity than other systems

  9. BUILDING CONFIGURATION • Buildings having irregular configurations in plan and/or elevation suffered greater damage • Inelastic behaviour concentrates in certain localized regions in irregular structure • Structural elements deteriorate rapidly in these areas • Inelastic demand tend to be well distributed throughout a regular structure • Elastic analysis methods are not capable to accurately predict distribution of seismic demand in an irregular structure • Building with regular configuration are encouraged and highly irregular buildings are prohibited on sites close to active faults

  10. PLAN IRREGULARITIES • Five different plan irregularities have been identified • Torsional irregularity • Re-entrant corners • Diaphragm discontinuity • Out-of-plan offsets • Nonparallel systems

  11. PLAN IRREGULARITIES • Torsional irregularity

  12. PLAN IRREGULARITIES • Re-entrant corners

  13. PLAN IRREGULARITIES • Diaphragm discontinuity

  14. PLAN IRREGULARITIES • Out-of-plan offsets

  15. PLAN IRREGULARITIES • Nonparallel systems

  16. VERTICAL IRREGULARITIES • Five different vertical structural irregularities have been identified • Stiffness irregularity-soft story • Weight (mass) irregularity • Vertical geometric irregularity • In-plane discontinuity in vertical lateral-force-resisting elements • Discontinuity in capacity-weak story

  17. VERTICAL IRREGULARITIES • Stiffness irregularity-soft story

  18. VERTICAL IRREGULARITIES • Weight (mass) irregularity

  19. VERTICAL IRREGULARITIES • Vertical geometric irregularity

  20. VERTICAL IRREGULARITIES • In-plane discontinuity in vertical lateral-force-resisting elements

  21. VERTICAL IRREGULARITIES • Discontinuity in capacity-weak story

  22. RESPONSE OF CONCRETE BUILDINGS • A reliable load path is necessary to transfer lateral forces to the foundation • Earthquake forces are resisted by either walls or frame elements • Foundation components transfer the force to the earth • Key elements of the load path through the structure include • Diaphragm • Walls • Frames • Foundations • Connections are also important components of the chain • Resistance of building is as strong as the weakest link in the path

  23. DIAPHRAGM RESPONSE • Diaphragms typically span between shear walls of concrete • Respond like deep beams bending in their own plane under lateral forces • Forces produced at the diaphragm edge include • Shear • Tension or compression • Seismic forces acting perpendicular to the long side produce shear forces acting in the opposite direction • Shear forces are transferred to the shear walls • Tension develops in the chord and compression develops on the side on which seismic forces act

  24. DIAPHRAGM RESPONSE • Forces similar to chord forces also develop around openings • Openings may need to be reinforced with additional longitudinal steel • Shear forces at the diaphragm edge are transferred through shear-friction • Another mechanism of shear transfer is dowel action • The assumption here is that reinforcement acts as anchor bolt in shear

  25. SEISMIC RESPONSE OF SHEAR WALLS • Shear walls resist gravity loads and in-plane lateral forces • They are like vertical cantilever deep beams • Shear force from diaphragm causes bending moment and shear force in the plane of the wall • Tendency to overturn and slide is resisted by the foundation • Bending moment increases from top to bottom of a building and causes tension and compression forces in the wall plane • Seismic response of short stocky shear wall is governed by shear • Response of taller walls is governed by flexure

  26. SEISMIC RESPONSE OF SHEAR WALLS • For walls with H/L between 1-2 response depends on several factors including amount of shear reinforcing • Shear dominated response is characterized by inclined (x-shaped) cracking pattern • The wall can loose strength rapidly with little warning

  27. SEISMIC RESPONSE OF FRAMES • Response of frames is different than shear walls to lateral forces • Frame resists by being deformed by lateral forces due to the rigidity of the beam-column joints • Beams and columns bend due to this rigidity • Tension stresses caused by the bending must be resisted by the reinforcement • Bending also causes vertical shear forces in beams and horizontal shear forces in columns • Vertical shear reinforcement is needed in beams and horizontal shear reinforcement in columns

  28. FOUNDATION RESPONSE • Foundations can be shallow or deep • Shallow foundations are supported by vertical pressure of earth • Foundation types include • Square or rectangular spread footings • Continuous strip footings • Deep foundations consists of piles made of • Wood • Steel • Concrete • Piles can be poured in place or driven piles

  29. FOUNDATION RESPONSE • Piles are supported by end bearing and skin friction • Connected together by ties, grade beams or slabs on grade • Shear forces are transferred from walls and frames to the foundation • Dowels in foundation must match the vertical reinforcement in walls and frames

  30. THANK YOU FOR YOUR ATTENTION !

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