Seismic Response of a Three-Dimensional Asymmetric Multi-Storey Reinforced Concrete Structure

Lim, Hyun-Kyu; Kang, Jun Won; Pak, H.; Chi, Hyung-gun; Lee, Young‐Geun; Kim, Jang Hwan

doi:10.3390/app8040479

Cited by 8 publications

(8 citation statements)

References 19 publications

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“…In literature, there are some articles that analyse the seismic response of both symmetric and asymmetric multi-storey reinforced concrete structures [4][5][6]. Dimova and Alashki show in [4] that even the symmetric reinforced concrete structures behave under seismic loading like the irregular ones under accidental small eccentricity, and the method for the correction of the structure response is presented.…”

Section: Introductionmentioning

confidence: 99%

“…By using the finite element model of asymmetric three-storey reinforced concrete building, validated by modal experiments under low-intensity ground motion simulation, it is shown that the torsional effects are much greater for an asymmetric structure than for a symmetric structure with approximately the same design conditions, especially under high-intensity earthquakes [5].…”

Section: Introductionmentioning

confidence: 99%

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A Method for Reducing of the Overall Torsion for Reinforced Concrete Multi-Storey Irregular Structures

Botiș

Cerbu

2020

Applied Sciences

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The uneven distributions of mass and stiffness in the case of multi-storey concrete buildings lead to a torsion sensitivity of those civil structures under dynamical loadings like earthquakes or wind and gusts. In order to minimize the overall torsion, it is imperatively necessary to reduce the distance between the centre of mass (CM) and centre of stiffness (CS) in the design stage. In this context, the main purpose of this paper is to present a theoretical method of reducing torsion by minimizing the distance between CM and CS at the level of each floor of the structure. Principal stiffness axes are also changed in convenient directions so that the movement of the structure leads to a favourable plastic mechanism in the fundamental mode of vibration. To achieve the goal, the main objective is to change the dimensions and orientations of the pillars located on the perimeter of the structures. The described method was used to study: irregular shaped structures in plan; structures with stairs or with central concrete core; structures with elevation retractions. The overall torsion reducing was achieved with Matlab programs, and the verification of the results was carried out by using the software ETABS 2016.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Method for Reducing of the Overall Torsion for Reinforced Concrete Multi-Storey Irregular Structures

Botiș

Cerbu

2020

Applied Sciences

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“…The modern seismic design provisions for reinforced concrete (RC) structures enforce ductility requirements to meet target limit states, avoiding brittle failure [1]. As a typical shear failure of an RC member is often very brittle, more accurate descriptions of shear behavior are imperative in achieving proper safety goals.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Finite Element Analysis Formulation for Shear in Reinforced Concrete Beams

2019

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This study suggests a novel beam-column element formulation that utilizes an equilibrium-driven shear stress function. The beam shear is obtained from the bi-axial states of micro-planes, through matrix condensation and zero vertical traction assumptions. This properly remedies the shear stiffening of a one-dimensional beam-column element, keeping its degrees of freedom to a minimum. For verification of the proposed method, a total of seven shear test results of reinforced concrete (RC) beams were collected from the literature, in which the key variables were the reinforcement ratio, the presence of shear reinforcement, and section shape. The advantages are clearly shown in the shear stresses distributions being accurately described and the global load-displacement relations being successfully obtained and matching well with various test results. The proposed model shows satisfactory descriptions of the monotonic load-displacement response of the RC beams failing in multiple modes that vary from diagonal-tension to flexural-compression. In addition, more accurate and reliable information of sectional responses including sectional shear deformation and stresses is collected, leading to better prediction of a potential shear failure mode. Finally, the advantages of the proposed model are demonstrated by comparing the analysis results of an RCT-beam by using the different shear assumptions that include the constant and parabolic shear strains, constant shear flow, and the proposed shear stress function.

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“…The seismic performance of frame structures has been continually investigated by researchers, mainly through developing structures with maximum energy dissipation capacity [1][2][3][4][5][6][7][8][9]. In the 1950s, a new type of frame structure with a soft first story was designed by pioneers such as Le Corbusier [10] who applied the soft-first-story idea by lifting the structure off the ground.…”

Section: Introductionmentioning

confidence: 99%

Seismic Performance of a New Structural Design Solution for First-Story Isolated RC Buildings with Coupled Beam-Column Connections

Liu

2019

Applied Sciences

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This study proposes a new structural design of the first-story isolation system in reinforced concrete (RC) structures. Compared to the conditional buildings with independent columns, this new design integrates the independent columns with beams to increase the seismic capacity of the building by increasing the integrated stiffness of the coupled columns and the stability of the isolation system. The seismic responses of the proposed structure and the corresponding isolation effect were investigated by performing a series of numerical simulation and shaking table tests on a typical 7-story RC frame structure. The structure models were subjected to four earthquake waves with two PGAs (peak ground acceleration) of 0.30 g and 0.40 g for seismic analysis regarding the peak acceleration and inter-story displacement. Both simulation and testing results showed that the story acceleration and inter-story displacement of the superstructure in the isolated model decreased significantly. While the substructure below the isolation layer had a negligible decrease of acceleration. The connection of beams with concrete columns significantly increases the seismic capacity of the RC frame buildings compared to non-isolated frame buildings. The coupled beam-column connections could thus be potentially adopted in the practical first-story isolation system to avoid the requirements of large column stiffness and large column size.

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Seismic Response of a Three-Dimensional Asymmetric Multi-Storey Reinforced Concrete Structure

Cited by 8 publications

References 19 publications

A Method for Reducing of the Overall Torsion for Reinforced Concrete Multi-Storey Irregular Structures

A Method for Reducing of the Overall Torsion for Reinforced Concrete Multi-Storey Irregular Structures

Nonlinear Finite Element Analysis Formulation for Shear in Reinforced Concrete Beams

Seismic Performance of a New Structural Design Solution for First-Story Isolated RC Buildings with Coupled Beam-Column Connections

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