T. J. Zhu scite author profile

SUMMARYUsing a three element single mass model, this paper presents the ductility demands on the elements of torsionally unbalanced systems when subjected to strong earthquake shaking. Torsionally unbalanced systems based on nine structural configurations are considered, ranging from torsionally stiff systems with the centre of rigidity (CR) centrally located to torsionally flexible systems with CR eccentrically located. The strength of the elements is designed based on the Canadian and New Zealand codes, and the Uniform Building Code (UBC) of the United States. It is shown that all three codes can limit the ductility demands on the elements to that of a similar but torsionally balanced system when the system is torsionally stiff. However, substantial additional ductility demands on the element at the stiff edge of the system exist for torsionally flexible systems when the New Zealand code or UBC is used. The large ductility demand is caused by the low strength of the stiff-edge element permitted by these codes.

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Effect of peak ground acceleration to velocity ratio on ductility demand of inelastic systems

Zhu

Heidebrecht

Tso

1988

Earthq Engng Struct Dyn

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SUMMARYA statistical analysis is performed to investigate the significance of peak ground acceleration to velocity ratio ( u h ) on the displacement ductility demand of simple bilinear hysteretic systems. Three groups of earthquake records representative of low, normal and high a/v ranges are used as input ground motions. The design yield strength of the inelastic systems is specified from the base shear formula in the 1980 National Building Code of Canada (NBCC 1980) and that in NBCC 1985 respectively. The former case represents the common practice of specifying seismic design base shear based on a peak site acceleration, while in the latter case the base shear is specified based on peak ground velocity and u/u ratio. Mean displacement ductility demands are obtained for the three groups of ground motions; and the corresponding dispersion characteristics are examined. The results show that the ground motion u/u range has a significant effect on the displacement ductility demand, and it should be accounted for in design strength specification.

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Effect of Peak Ground a/v Ratio on Structural Damage

1988

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Design of torsionally unbalanced structural systems based on code provisions II: Strength distribution

Zhu

Tso

1992

Earthq Engng Struct Dyn

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SUMMARYThis paper presents the results of an analytical study of the strength distribution of lateral load resisting elements in torsionally unbalanced systems designed based on codified torsional provisions. It is shown that the element strength can be expressed conveniently as the element strength of a similar but torsionally balanced system multiplied by a strength factor. This strength factor depends on three system parameters, namely, the location of the element relative to the centre of rigidity, and the torsional stiffness and eccentricity of the structure. In addition, it depends on the design coefficients of the code specified design eccentricity expressions. The influence of each of these factors on the element strength distribution is discussed. A new set of values for the design coefficients is proposed. By means of examples, it is shown that the proposed torsional provision is an improvement over those suggested in the National Building Code of Canada and the New Zealand code.

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T. J. Zhu

Engineering implication of ground motion A/V ratio

Design of torsionally unbalanced structural systems based on code provisions I: Ductility demand

Effect of peak ground acceleration to velocity ratio on ductility demand of inelastic systems

Effect of Peak Ground a/v Ratio on Structural Damage

Design of torsionally unbalanced structural systems based on code provisions II: Strength distribution

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