Symbols
D = Strength Excess Coefficient
f d (µ, T ) = Design strength required of the carrier system depending on the predicted ductility capacity and period
f (T e ) = Linear (elastic) strength demand calculated for the carrier system
f y (µ k , T ) = Projected ductility capacity and yield strength depending on period
I = Building Importance Factor
R = Structural System Behavior Coefficient
R a ( T ) =Projected ductility capacity and Seismic Load Reduction Coefficient depending on the period
R y (µ k , T) = Predicted ductility capacity and Yield Strength Reduction Coefficient depending on the period
T = Natural vibration period [s]
T B = Horizontal elastic design acceleration spectrum corner period [s]
µ k = ductility capacity prescribed for the carrier system
The basic seismic analysis procedure uses response spectra that are representative of, but substantially reduced from, the anticipated ground motions. As a result, at the MCER level of ground shaking, structural elements are expected to yield, buckle, or otherwise behave inelastically. In the standard, such design forces are computed by dividing the forces that would be generated in a structure behaving elastically when subjected to the design earthquake ground motion by the response modification coefficient, R, and this design ground motion is taken as two-thirds of the MCER ground motion.
The intent of R is to reduce the demand determined, assuming that the structure remains elastic at the design earthquake, to target the development of the first significant yield. This reduction accounts for the displacement ductility demand, Rd, required by the system and the inherent overstrength, Ω, of the seismic
force-resisting system (SFRS) (Fig. C12.1-1). Significant yield is the point where complete plastification of a critical region of the SFRS first occurs (e.g., formation of the first plastic hinge in a moment frame), and the stiffness of the SFRS to further increases in lateral forces decreases as continued inelastic behavior spreads
within the SFRS. This approach is consistent with member-level ultimate strength design practices. As such, first significant yield should not be misinterpreted as the point where first yield occurs in any member (e.g., 0.7 times the yield moment of a steel beam or either initial cracking or initiation of yielding in a reinforcing bar in a reinforced concrete beam or wall).
Fig. C12.1-1 shows the lateral force versus deformation relation for an archetypal moment frame used as an SFRS. Because of particular design rules and limits, including material strengths in excess of nominal or project-specific design requirements, structural elements are stronger by some degree than the strength required by analysis. The maximum strength developed along the curve is substantially higher than that at first significant yield, and this margin is referred to as the system overstrength capacity. The ratio of these strengths is denoted as Ω. The system overstrength described above is the direct result of overstrength of the elements that form the SFRS and, to a lesser extent, the lateral force distribution used to evaluate the inelastic force–deformation curve.
Structures typically have a much higher lateral strength than that specified as the minimum by the standard, and the first significant yielding of structures may occur at lateral load levels that are 30% to 100% higher than the prescribed design seismic forces. If provided with adequate ductile detailing, redundancy, and regularity, full yielding of structures may occur at load levels that are two to four times the prescribed design force levels.
The energy dissipation resulting from hysteretic behavior can be measured as the area enclosed by the force–deformation curve of the structure as it experiences several cycles of excitation. Some structures have far more energy dissipation capacity than others. The extent of energy dissipation capacity available depends largely on the amount of stiffness and strength degradation the structure undergoes as it experiences repeated cycles of inelastic deformation. Fig. C12.1-2 shows representative load deformation curves for two simple substructures, such as a beam–column assembly in a frame. Hysteretic curve (a) in the figure represents the behavior of substructures that have been detailed for ductile behavior. The substructure can maintain almost all of its strength and stiffness over several large cycles of inelastic deformation. The resulting force–deformation “loops” are quite wide and open, resulting in a large amount of energy dissipation. Hysteretic curve (b) represents the behavior of a substructure that has much less energy dissipation than that for the substructure (a) but has a greater change in response period. The structural response is determined by a combination of energy dissipation and period modification.
In this equation D , Resistance Redundancy Factor 's is shown. With this coefficient, it is expressed that the yield strength is excessive compared to the design strength.
The concept of ductility is mainly determined by the difference between the temporal displacement and permanent displacement regions in the stress-strain curve of the materials. For example, the following curve obtained in the base section as a result of the static cyclic loading test (push - pull) on a reinforced concrete cantilever column shows the typical nonlinear strength-displacement behavior.
Under the effect of an earthquake, structural elements behave similar to the curve above. In order to design the structure ductile, this displacement capability, which the elements can do, is used. For example, the behavior shown with the dashed line in the figure below represents a building with a brittle design and the continuous line symbolizes the ductile building.
The basis of the calculation method used for Design Based on Strength is the ductile behavior of the carrier system and the reduction of earthquake loads. As you will see in the curve below, the nonlinear behavior of the structure is translated into a conjugate linear system. The assumption is based on the assumption that the area under both curves is equal, that is, the building can absorb equal energy.
Sae represents the elastic spectral acceleration and m represents the weight of the structure.
Yield Strength Reduction Coefficient R y (µk, T) , according to the rule of equal displacement
The ductility capacity foreseen for structural systems with low stiffness is taken as equal to µk :
For structural systems with high rigidity, it was taken in TBDY 2018 as follows:
Structural Behavior Coefficient R , predicted ductility capacity μk 'or the defined Resistance Redundancy Factor D reasearch and Building Importance Factor I ' either depending defined:
For the section design with the bearing capacity approach in Design Based on Strength , the Earthquake Load Reduction Coefficient Ra (T ) corresponding to a certain fixed ductility capacity selected for each type of structural system is defined as follows ;
As a result, the Earthquake Load Reduction Coefficient R (T a ) is expressed by the following equations to be used in practice :