SEISMIC POUNDING BETWEEN ADJACENT BUILDING STRUCTURES SUBJECTED TO NEAR FIELD GROUND MOTION

The characteristic of near-field earthquake records has been investigated in the previous studies. However, the effects of the near-field earthquakes on the response of the building structures need to be further investigated. Engineering demand parameters like inter-story drift ratio and floor acceleration can provide a good means for comparing the response of structures to the near-field and the far-field earthquakes. The main objective of this paper was to apply these two parameters to compare the behavior of the concrete Moment Resistant Frame (MRF) subjected to near-field and far-field ground motions. In this study, non-linear numerical simulations were performed on concrete MRF office buildings subjected to two sets of 14 near-field records and 14 far-field records. The analytical models simulated 4-story, 8-story, and 16 story buildings. The obtained results indicated that the near-field effects can increase the inter-story drift ratio and floor acceleration at lower stories of low and mid-rise building subjected to high ground motion intensities.

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Collapse analysis of building structures under excitation of near-fault ground motion with consideration of large deformation and displacement

The Structural Design of Tall and Special Buildings ◽

10.1002/tal.308 ◽

2007 ◽

Vol 16 (2) ◽

pp. 165-180 ◽

Cited By ~ 4

Author(s):

Ming-Hsiang Shih ◽

Chang-Liang Chen ◽

Wen-Pei Sung

Keyword(s):

Large Deformation ◽

Ground Motion ◽

Building Structures ◽

Near Fault ◽

Collapse Analysis ◽

Near Fault Ground Motion

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Critical Response of 2DOF Elastic–Plastic Building Structures under Double Impulse as Substitute of Near-Fault Ground Motion

Frontiers in Built Environment ◽

10.3389/fbuil.2016.00002 ◽

2016 ◽

Vol 2 ◽

Cited By ~ 11

Author(s):

Ryo Taniguchi ◽

Kotaro Kojima ◽

Izuru Takewaki

Keyword(s):

Ground Motion ◽

Building Structures ◽

Critical Response ◽

Elastic Plastic ◽

Near Fault ◽

Near Fault Ground Motion

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Predicting the near-field strong ground motion based on uncertainties in asperities: an opportunity to reproduce the characteristics of the 1970 Tonghai earthquake (Ms 7.8)

Journal of Seismology ◽

10.1007/s10950-021-09997-w ◽

2021 ◽

Author(s):

Zongchao Li ◽

Jize Sun ◽

Xueliang Chen ◽

Guochen Wang ◽

Qingfeng Ding

Keyword(s):

Ground Motion ◽

Strong Ground Motion ◽

Near Field ◽

Strong Ground

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Strain, tilt, and rotation associated with strong ground motion in the vicinity of earthquake faults

Bulletin of the Seismological Society of America ◽

10.1785/bssa0720051717 ◽

1982 ◽

Vol 72 (5) ◽

pp. 1717-1738 ◽

Cited By ~ 1

Author(s):

Michel Bouchon ◽

Keiiti Aki

Keyword(s):

Ground Motion ◽

Rotational Velocity ◽

Near Field ◽

Strike Slip ◽

Phase Velocities ◽

Crustal Structures ◽

Time Histories ◽

San Fernando ◽

Earthquake Faults ◽

Strong Ground

abstract In the absence of near-field records of differential ground motion induced by earthquakes, we simulate the time histories of strain, tilt, and rotation in the vicinity of earthquake faults embedded in layered media. We consider the case of both strike-slip and dip-slip fault models and study the effect of different crustal structures. The maximum rotational motion produced by a buried 30-km-long strike-slip fault with slip of 1 m is of the order of 3 × 10−4 rad while the corresponding rotational velocity is about 1.5 × 10−3 rad/sec. A simulation of the San Fernando earthquake yields maximum longitudinal strain and tilt a few kilometers from the fault of the order of 8 × 10−4 and 7 × 10−4 rad. These values being small compared to the amplitude of ground displacement, the results suggest that most of the damage occurring in earthquakes is caused by translation motions. We also show that strain and tilt are closely related to ground velocity and that the phase velocities associated with strong ground motions are controlled by the rupture velocity and the basement rock shearwave velocity.

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Near-Field Ground Motion Modal versus Wave Propagation Analysis

Shock and Vibration ◽

10.1155/2010/359853 ◽

2010 ◽

Vol 17 (4-5) ◽

pp. 611-617 ◽

Cited By ~ 1

Author(s):

Artur Cichowicz

Keyword(s):

Ground Motion ◽

Strong Ground Motion ◽

Response Spectrum ◽

Near Field ◽

Spectral Characteristics ◽

Beam Model ◽

Drift Spectrum ◽

Localized Deformation ◽

Dominant Period ◽

Strong Ground

The response spectrum generally provides a good estimate of the global displacement and acceleration demand of far-field ground motion on a structure. However, it does not provide accurate information on the local shape or internal deformation of the response of the structure. Near-field pulse-like ground motion will propagate through the structure as waves, causing large, localized deformation. Therefore, the response spectrum alone is not a sufficient representation of near-field ground motion features. Results show that the drift-response technique based on a continuous shear-beam model has to be employed here to estimate structure-demand parameters when structure is exposed to the pulse like ground motion. Conduced modeling shows limited applicability of the drift spectrum based on the SDOF approximation. The SDOF drift spectrum approximation can only be applied to structures with smaller natural periods than the dominant period of the ground motion. For periods larger than the dominant period of ground motion the SDOF drift spectra model significantly underestimates maximum deformation. Strong pulse-type motions are observed in the near-source region of large earthquakes; however, there is a lack of waveforms collected from small earthquakes at very close distances that were recorded underground in mines. The results presented in this paper are relevant for structures with a height of a few meters, placed in an underground excavation. The strong ground motion sensors recorded mine-induced earthquakes in a deep gold mine, South Africa. The strongest monitored horizontal ground motion was caused by an event of magnitude 2 at a distance of 90 m with PGA 123 m/s2, causing drifts of 0.25%–0.35%. The weak underground motion has spectral characteristics similar to the strong ground motion observed on the earth's surface; the drift spectrum has a maximum value less than 0.02%.

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Near-Field Ground Motion of the 2002 Denali Fault, Alaska, Earthquake Recorded at Pump Station 10

Earthquake Spectra ◽

10.1193/1.1778172 ◽

2004 ◽

Vol 20 (3) ◽

pp. 597-615 ◽

Cited By ~ 81

Author(s):

W. L. Ellsworth ◽

M. Celebi ◽

J. R. Evans ◽

E. G. Jensen ◽

R. Kayen ◽

...

Keyword(s):

Ground Motion ◽

Near Field ◽

Free Field ◽

Monitoring And Control ◽

Peak Acceleration ◽

Permanent Displacement ◽

Soil Response ◽

Denali Fault ◽

Field Recording ◽

Pump Station

A free-field recording of the Denali fault earthquake was obtained by the Alyeska Pipeline Service Company 3 km from the surface rupture of the Denali fault. The instrument, part of the monitoring and control system for the trans-Alaska pipeline, was located at Pump Station 10, approximately 85 km east of the epicenter. After correction for the measured instrument response, we recover a seismogram that includes a permanent displacement of 3.0 m. The recorded ground motion has relatively low peak acceleration (0.36 g) and very high peak velocity (180 cm/s). Nonlinear soil response may have reduced the peak acceleration to this 0.36 g value. Accelerations in excess of 0.1 g lasted for 10 s, with the most intense motion occurring during a 1.5-s interval when the rupture passed the site. The low acceleration and high velocity observed near the fault in this earthquake agree with observations from other recent large-magnitude earthquakes.

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