Inelastic Displacement Ratios for Seismic Assessment of Structures Subjected to Forward-Directivity Near-Fault Ground Motions

AbstractThis paper describes a detailed numerical investigation into the inelastic displacement ratios of non-structural components mounted within multi-storey steel framed buildings and subjected to ground motions with forward-directivity features which are typical of near-fault events. The study is carried out using detailed multi-degree-of-freedom models of 54 primary steel buildings with different structural characteristics. In conjunction with this, 80 secondary non-structural elements are modelled as single-degree-of-freedom systems and placed at every floor within the primary framed structures, then subsequently analysed through extensive dynamic analysis. The influence of ground motions with forward-directivity effects on the mean response of the inelastic displacement ratios of non-structural components are compared to the results obtained from a reference set of strong-ground motion records representing far-field events. It is shown that the mean demand under near-fault records can be over twice as large as that due to far-fault counterparts, particularly for non-structural components with periods of vibration lower than the fundamental period of the primary building. Based on the results, a prediction model for estimating the inelastic displacement ratios of non-structural components is calibrated for far-field records and near-fault records with directivity features. The model is valid for a wide range of secondary non-structural periods and primary building fundamental periods, as well as for various levels of inelasticity induced within the secondary non-structural elements.

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Effects of Fling Step and Forward Directivity on Seismic Response of Buildings

Earthquake Spectra ◽

10.1193/1.2192560 ◽

2006 ◽

Vol 22 (2) ◽

pp. 367-390 ◽

Cited By ~ 255

Author(s):

Erol Kalkan ◽

Sashi K. Kunnath

Keyword(s):

Seismic Response ◽

Ground Motions ◽

High Amplitude ◽

Moment Frames ◽

Steel Moment Frames ◽

Damage Potential ◽

Near Fault ◽

Forward Directivity ◽

Fling Step ◽

Far Fault

This paper investigates the consequences of well-known characteristics of near-fault ground motions on the seismic response of steel moment frames. Additionally, idealized pulses are utilized in a separate study to gain further insight into the effects of high-amplitude pulses on structural demands. Simple input pulses were also synthesized to simulate artificial fling-step effects in ground motions originally having forward directivity. Findings from the study reveal that median maximum demands and the dispersion in the peak values were higher for near-fault records than far-fault motions. The arrival of the velocity pulse in a near-fault record causes the structure to dissipate considerable input energy in relatively few plastic cycles, whereas cumulative effects from increased cyclic demands are more pronounced in far-fault records. For pulse-type input, the maximum demand is a function of the ratio of the pulse period to the fundamental period of the structure. Records with fling effects were found to excite systems primarily in their fundamental mode while waveforms with forward directivity in the absence of fling caused higher modes to be activated. It is concluded that the acceleration and velocity spectra, when examined collectively, can be utilized to reasonably assess the damage potential of near-fault records.

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Assessment of permanent drift demands in steel moment-resisting steel buildings due to recorded near-fault forward directivity earthquake ground motions and velocity pulse models

Structures ◽

10.1016/j.istruc.2020.07.035 ◽

2020 ◽

Vol 27 ◽

pp. 1260-1273

Author(s):

Jorge Ruiz-García ◽

José M. Ramos-Cruz

Keyword(s):

Ground Motions ◽

Steel Buildings ◽

Velocity Pulse ◽

Near Fault ◽

Earthquake Ground Motions ◽

Forward Directivity ◽

Moment Resisting

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Seismic response analysis of intake tower structure under near-fault ground motions with forward-directivity and fling-step effects

Soil Dynamics and Earthquake Engineering ◽

10.1016/j.soildyn.2020.106098 ◽

2020 ◽

Vol 132 ◽

pp. 106098 ◽

Cited By ~ 3

Author(s):

Xi Chen ◽

Yunhe Liu ◽

Binpeng Zhou ◽

Dixiong Yang

Keyword(s):

Seismic Response ◽

Ground Motions ◽

Response Analysis ◽

Seismic Response Analysis ◽

Near Fault ◽

Forward Directivity ◽

Fling Step ◽

Tower Structure

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Inelastic Displacement Spectra and Its Utilization of DDB Design for Seismic Isolated Bridges Subjected to Near-Fault Pulse-Like Ground Motions

Earthquake Spectra ◽

10.1193/033017eqs056m ◽

2019 ◽

Vol 35 (3) ◽

pp. 1109-1140 ◽

Cited By ~ 3

Author(s):

Yi-feng Wu ◽

Hao Wang ◽

Jian Li ◽

Ben Sha ◽

Ai-qun Li

Keyword(s):

Design Method ◽

Ground Motions ◽

Single Degree Of Freedom ◽

Sdof System ◽

Inelastic Displacement ◽

Displacement Spectra ◽

Near Fault ◽

The Mean ◽

Displacement Based ◽

Isolated Bridges

A variety of research has focused on the inelastic displacement demand of a single degree of freedom (SDOF) system when subjected to near-fault pulse-like ground motions, in which the concerned ductility, μ, is typically lower than ten for normal structures. However, for seismic isolated structures that are more prone to large displacement, the corresponding research is limited. The purpose of this paper is to investigate the inelastic displacement spectra of an SDOF system with μ ranging from 5 to 70 and further proposes a direct displacement-based (DDB) design method for seismic isolated bridges. More concretely, a pool of near-fault pulse-like records is assembled, the mean C μ as a function of T/ T p is developed, and the influences of the ductility, μ, and the post-to-pre-yield ratio, α, on C μ are carefully investigated. Then the corresponding inelastic displacement spectra, S d, are obtained, and a comprehensive piecewise expression is proposed to fit S d. After that, the utilization of the spectra for the DDB design of a three-span seismic isolated continuous bridge is performed, and the principal of simplifying the bridge to an SDOF system is carefully explained and verified.

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Plastic hinge length of reinforced concrete columns subjected to both far-fault and near-fault ground motions having forward directivity

The Structural Design of Tall and Special Buildings ◽

10.1002/tal.729 ◽

2011 ◽

Vol 22 (12) ◽

pp. 903-926 ◽

Cited By ~ 13

Author(s):

Alireza Mortezaei ◽

Hamid Reza Ronagh

Keyword(s):

Reinforced Concrete ◽

Ground Motions ◽

Plastic Hinge ◽

Concrete Columns ◽

Reinforced Concrete Columns ◽

Near Fault ◽

Forward Directivity ◽

Far Fault ◽

Plastic Hinge Length

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Near-Fault Directivity Spectrum for Nuclear Structure Design on Rock Site

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.243-249.3820 ◽

2011 ◽

Vol 243-249 ◽

pp. 3820-3823

Author(s):

Long Jun Xu ◽

Sheng Chao Yang

Keyword(s):

Nuclear Structure ◽

Ground Motions ◽

Response Spectra ◽

Structure Design ◽

Design Spectra ◽

Directivity Effect ◽

Near Fault ◽

Forward Directivity ◽

Rock Site ◽

Large Earthquakes

This study is aimed at evaluating the safety implications of near-fault directivity effect on nuclear structure and facilities designed according to the Chinese code. To this end, a set of near-fault ground motions at rock site with typical forward-directivity effect is examined with emphasis on several key parameters and response spectra. The bi-normalized response spectra in terms of different corner periods are utilized to derive nuclear design spectra. It was concluded that nuclear design spectra on rock site derived from typical directivity records are significantly influenced by both magnitude and distance. The nuclear design spectra specified in the code need to be adjusted to reflect the near-fault directivity effect of large earthquakes.

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