Modelling Approaches for Inelastic Behaviour of RC Walls: Multi-level Assessment and Dependability of Results

Almeida, João Saraiva Esteves Pacheco de; Tarquini, Danilo; Beyer, Katrin

doi:10.1007/s11831-014-9131-y

Cited by 47 publications

(26 citation statements)

References 53 publications

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“…Residual strength and strain: Upon the onset of lap splice degradation, the strength of most test units with lap splices dropped sharply whereas for two test units the loss of strength was more gradual (TW3 and VK2). Postpeak response modelling is a delicate task as it requires challenging procedures to match numerical and physical localization issues (Almeida et al 2012(Almeida et al , 2016Calabrese et al 2010). This applies in particular to brittle deformation mechanisms such as lap splices, which are often characterized by steep softening slopes.…”

Section: Factors Affecting Lap Splice Strength and Strain At Degradatmentioning

confidence: 99%

Influence of Lap Splices on the Deformation Capacity of RC Walls. I: Database Assembly, Recent Experimental Data, and Findings for Model Development

et al. 2017

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Recent postearthquake missions have shown that reinforced concrete (RC) wall buildings can experience critical damage owing to lap splices, which led to a recent surge in experimental tests of walls with such constructional details. Most of the 16 wall tests described in the literature thus far were carried out in the last six years. This paper presents a database with these wall tests, including the description of a new test on a wall with lap splices and a corresponding reference wall with continuous reinforcement. They complement the existing tests by investigating a spliced member with a shear span ratio smaller than two, which is the smallest among them. The objective of this database is to collect information not just on the force capacity but mainly on the deformation capacity of lap splices in reinforced concrete walls. It is shown that (1) well-confined lap splices relocate the plastic hinge above the lap splice, (2) lap splices with adequate lengths but insufficiently confined attain the peak force but their deformation capacity is significantly reduced, and (3) short and not well-confined lap splices fail before reaching the strength capacity. The analysis of the test results, which are used in the companion paper for the finite element analysis of walls with lap splices, indicates in particular that the confining reinforcement ratio and the ratio of shear span to lap splice length influence the lap splice strain capacity.

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Section: Factors Affecting Lap Splice Strength and Strain At Degradatmentioning

confidence: 99%

Influence of Lap Splices on the Deformation Capacity of RC Walls. I: Database Assembly, Recent Experimental Data, and Findings for Model Development

et al. 2017

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“…Research by Coleman andSpacone (2011), Pugh et al (2015) and Almeida et al (2016) shows that if wall response is simulated using common concrete material models (e.g. Mander et al 1988, Saatcioglu andRazvi 1992) to define the softening portion of the compressive stress-strain envelope, simulated drift at onset of lateral strength loss is inaccurate and a function of the number of elements and/or fiber cross sections used per element.…”

Section: Constitutive Modelingmentioning

confidence: 99%

Recommended modeling parameters and acceptance criteria for nonlinear analysis in support of seismic evaluation, retrofit, and design

2017

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PrefaceIn September 2014, the Applied Technology Council (ATC) commenced a task order project under National Institute of Standards and Technology (NIST) Contract SB1341-13-CQ-0009 to conduct comprehensive review of the generalized component models published in the current ASCE/SEI standard and relevant research, and develop recommendations for improvement . The need for defining parameters for nonlinear force-deformation models for components, elements, or assemblies is identified as a high-priority research and development topic in NIST GCR 14-917-27 report, Nonlinear Analysis Study and Development Program for Performance-Based Seismic Engineering, (NIST, 2013b) which outlines a research and development program for addressing the gap between state-of-the-art academic research and state-of-practice engineering applications for nonlinear structural analysis, analytical structural modeling, and computer simulation in support of performance-based seismic engineering. Buildings (ASCE, 2014), is widely used by designers for evaluating and upgrading existing buildings. The component models in the current standard were developed for use in existing building analysis, but they have also become widely employed in new building analysis. The purpose of this report is to recommend broad improvements to seismic nonlinear modeling and acceptance criteria requirements for different structural systems. The current standard, ASCE/SEI 41-13, Seismic Evaluation and Retrofit of Existing List of Tables xxviiThis publication is available free of charge from: https://doi.org/10.6028/NIST.GCR.17-917-45 List of Tables Executive SummaryThis report presents recommended hysteretic relationships for use in nonlinear seismic analysis in support of performance-based seismic design and evaluation projects. The primary intended audience for this report are committee members engaged in the development of building code requirements for the use of nonlinear analysis in design, though individual engineers engaged in performance-based engineering projects may find the information presented herein useful.Nonlinear static and dynamic analysis are commonly used by engineers to assess the probable performance of existing buildings and to design major new buildings. The most comprehensive guidelines presently available for performing nonlinear seismic analysis are contained in ASCE/SEI 41-13, Seismic Evaluation and Retrofit of Existing Buildings (ASCE, 2014). This guidance includes recommended backbone shapes and control points that describe the envelope of hysteretic response of various structural elements when subjected to ramped, fully-reversed, cyclic loading protocols. Most of these backbone recommendations are based on data available in the mid-1990s. Substantial additional research has been conducted since that time, enabling the development of updated backbones and control points for steel braced frame and moment frame, reinforced concrete shear wall and moment frame, and masonry and wood shear wall structur...

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“…2 depicts the comparison between the tip displacements given by the proposed HOBT and that of Heyliger and Reddy [2]. The results are normalised with respect to those provided by the EBBT, which for the assumed geometric and loading conditions (prismatic element, linear elastic behaviour and nodal loads), always provide the same solution; this holds independently of the number of elements (N) and type of formulation (displacement-based or force-based) [14].…”

Section: Mesh Refinement and Bounding Of The Solutionmentioning

confidence: 99%

Force-based higher-order beam element with flexural-shear-torsional interaction in 3D frames. Part II: Applications

Almeida

Correia

Pinho

2015

Engineering Structures

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a b s t r a c tThe specific features of the proposed force-based formulation derived in the companion paper, which is applied for the first time to higher-order beam theories, are herein thoroughly validated. Introductory numerical examples illustrate the influence of mesh refinement, boundary conditions, and slenderness ratios for isotropic linear elastic response. Specific higher-order effects-unique to the developed element-are then suitably interpreted, as well as the formulation appropriateness to consider distributed loads and to model three-dimensional behaviour, which is verified with solid finite element analyses. Extensive comparisons against existing proposals, namely other refined higher-order beam theories, emphasize the performance of the proposed approach. Finally, the nonlinear response of the element with a multiaxial J2 linear plasticity material model is analysed, highlighting its advantages in relation to a classical force-based Euler-Bernoulli beam using a one-dimensional plastic material model with kinematic hardening.

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Modelling Approaches for Inelastic Behaviour of RC Walls: Multi-level Assessment and Dependability of Results

Cited by 47 publications

References 53 publications

Influence of Lap Splices on the Deformation Capacity of RC Walls. I: Database Assembly, Recent Experimental Data, and Findings for Model Development

Influence of Lap Splices on the Deformation Capacity of RC Walls. I: Database Assembly, Recent Experimental Data, and Findings for Model Development

Recommended modeling parameters and acceptance criteria for nonlinear analysis in support of seismic evaluation, retrofit, and design

Force-based higher-order beam element with flexural-shear-torsional interaction in 3D frames. Part II: Applications

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