A parametric investigation on applicability of the curved shell finite element model to nonlinear response prediction of planar RC walls

Dashti, Farhad; Dhakal, Rajesh; Pampanin, Stefano

doi:10.1007/s10518-019-00582-8

Cited by 22 publications

(7 citation statements)

References 27 publications

(22 reference statements)

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“…12 DIANA has been extensively used to simulate nonlinear seismic response of RC structural walls in the past, but most of these studies have been conducted using curved shell finite elements. [13][14][15][16] However, it was shown in Niroomandi 11 that traditional eight-node solid elements (HX24L) and curved shell elements (Q20SH) may not be suitable for simulating walls subjected to bi-directional loading and especially to capture a failure mode affected by the out-of-plane behaviour of the wall such as the one observed in Wall D5-6. Using eight-node solid elements may in fact lead to a different out-of-plane stiffness, strength, and failure mode.…”

Section: Numerical Simulation Of Wall D5-6mentioning

confidence: 99%

“…In this study, the seismic behaviour of Wall D5‐6 was simulated using the finite element (FE) software, DIANA 12 . DIANA has been extensively used to simulate nonlinear seismic response of RC structural walls in the past, but most of these studies have been conducted using curved shell finite elements 13–16 . However, it was shown in Niroomandi 11 that traditional eight‐node solid elements (HX24L) and curved shell elements (Q20SH) may not be suitable for simulating walls subjected to bi‐directional loading and especially to capture a failure mode affected by the out‐of‐plane behaviour of the wall such as the one observed in Wall D5‐6.…”

Section: Numerical Simulation Of Wall D5‐6mentioning

confidence: 99%

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Out‐of‐plane shear‐axial failure in slender rectangular reinforced concrete walls

Niroomandi¹,

Pampanin

Dhakal

et al. 2022

Earthq Engng Struct Dyn

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On 22 February 2011, one of the main structural walls of one of the tallest buildings in Christchurch, New Zealand (Grand Chancellor Hotel), had an extremely brittle and unusual failure that significantly damaged the building, severely compromising its structural stability. To this date, this peculiar failure mode has not yet been fully investigated and understood. Moreover, currently, it is not possible to identify and assess walls that are prone to this failure mode. Following recent findings based on experimental investigations, this failure mode was identified as out-of-plane shear-axial failure. A Finite Element (FE) model was developed in DIANA to capture this failure mode, and through a numerical parametric study, the key parameters that contribute to the development of this failure mode in rectangular reinforced concrete (RC) walls were identified. Solid elements were used for the concrete material and embedded truss elements for the steel reinforcement. Bar buckling was not included in this investigation due to the limitation of DIANA in implementing the bar buckling and Menegotto-Pinto models together, among which the latter was found to be more influential on the behaviour of RC walls investigated in this study. Based on the numerical and experimental studies conducted, an analytical method is proposed to: (1) identify rectangular walls prone to out-of-plane shear-axial failure as a first-level check for both design and assessment purposes; and (2) determine the out-of-plane drift capacity of rectangular walls prone to out-of-plane shear-axial failure. Design recommendations are provided for rectangular walls prone to out-of-plane shearaxial failure.

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Section: Numerical Simulation Of Wall D5-6mentioning

confidence: 99%

Section: Numerical Simulation Of Wall D5‐6mentioning

confidence: 99%

Out‐of‐plane shear‐axial failure in slender rectangular reinforced concrete walls

Niroomandi¹,

Pampanin

Dhakal

et al. 2022

Earthq Engng Struct Dyn

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“…The quadrilateral four-node curved shell element (Q20SH) available in the commercial finite element analysis software DIANA ( 2011) is used in the study contributed by Dashti et al (2019). The efficiency of the element is first verified by the experimental results obtained for the benchmark specimens chosen within the Wall Institute.…”

Section: Overview Of the Contributionsmentioning

confidence: 99%

Guest editorial: Nonlinear modelling of reinforced concrete structural walls

Fischinger

Isaković

Kolozvari

et al. 2019

Bull Earthquake Eng

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“…These can be used to accurately reproduce the cyclic response of shear critical members (Del Vecchio et al, 2015; Palermo, 2014; Sritharan et al, 2014). More recently, three-dimensional (3D) numerical modeling has been proposed to capture the out-of-plane instability of slender RC shear walls frequently observed in the aftermath of recent seismic events (Dashti et al, 2019; Haro et al, 2019) as well as the out-of-plane shear failure mechanism in walls subjected to bidirectional loading (Niroomandi et al, 2021). Further research has focused on the seismic loss assessment of RC shear wall buildings with emphasis on the influence of modeling approaches and contribution of different components to the total losses (Terzic et al, 2019), the use of simple seismic performance assessment procedures (Bianchi et al, 2019), and the formulation of fragility functions (Caruso et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Influence of earthquake damage and repair interventions on expected annual losses of reinforced concrete wall buildings

2022

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Recent devastating earthquakes have shown that existing reinforced concrete (RC) buildings that rely on shear walls may exhibit damage and cracking. The majority of seismic actions are borne by shear walls; hence, the quantification of their residual post-earthquake capacity is critical. Moreover, the repair interventions that are typically implemented in practice may be insufficient to fully restore the original capacity of the undamaged system, particularly in terms of stiffness. This makes it difficult for stakeholders to decide on implementing either building repair or demolition and reconstruction. This article proposes a novel methodology to aid practitioners in quantifying the effect of earthquake damage and repair on the seismic performance of buildings with shear walls within a loss-assessment framework. A refined procedure relying on a validated nonlinear finite element numerical model capable of reproducing the shear response of RC walls is proposed along with an analytical approach. Parametric analyses of an RC case-study building are conducted, and the results are discussed and compared in terms of expected annual losses in the undamaged, damaged, and repaired configurations.

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A parametric investigation on applicability of the curved shell finite element model to nonlinear response prediction of planar RC walls

Cited by 22 publications

References 27 publications

Out‐of‐plane shear‐axial failure in slender rectangular reinforced concrete walls

Out‐of‐plane shear‐axial failure in slender rectangular reinforced concrete walls

Guest editorial: Nonlinear modelling of reinforced concrete structural walls

Influence of earthquake damage and repair interventions on expected annual losses of reinforced concrete wall buildings

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