Uncertainty in shear resistance models of reinforced concrete beams according to fib MC2010

Prior studies point to high model uncertainty in shear prediction. Model factors for various shear prediction models are characterized here, based on a recent and well‐vetted database of shear failures. Characterization includes estimation of main statistical parameters; and importantly also correlation and regression analysis to assess consistency of model factors over ranges of design parameters. The aim of the study is to identify models suitable for use as general probabilistic model (GPM) in future reliability assessments. The Variable Strut Inclination Method (VSIM), shear level of approximation III of the fib Model Code 2010, and ACI 318 displayed high bias, variability and various correlations with shear input parameters which make them unsuitable choices for GPM. The compression chord capacity model and the modified compression field theory displayed low bias and variability with consistent model factors over the ranges of shear design parameters and are thus suitable as GPM. Concerns stem from observed inconsistency in capacity prediction by VSIM and size effect in ACI. Reliability assessment is advised.

Section: Discussion Of Mf Statistical Results and Trendssupporting

confidence: 56%

{MF}_{x} = \frac{V_{Exp, x}}{V_{Model, x} ((), X)}

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Section: Assessment Of Model Uncertainty and Biasmentioning

confidence: 99%

Model uncertainties and bias in SHEAR strength predictions of slender stirrup reinforced concrete beams

Olalusi

Viljoen

2019

“…The results in Figures and and in Tables and should be seen against the backdrop of monotonic test‐to‐model comparisons by Sigrist et al and Sykora et al: LoA II and III were found by Sigrist et al to provide median test‐to‐prediction ratios in 243 rectangular or T‐beams with stirrups (79 of which had axial force, normally due to prestress) equal to 1.34 and 1.195, respectively, and corresponding coefficients of variation of 17 and 13%. In Sykora et al 459 beams gave median test‐to‐prediction ratios of 1.58 and 1.125 for LoA II and III, respectively, and corresponding coefficients of variation of 25 and 23%. …”

Section: The Three Levels Of Approximation In Mc2010 and The Ec2‐2018mentioning

confidence: 74%

“…• Of the beneficial contribution of the axial load, outlined in Section 3 • Of the reduction in shear resistance due to cycling of the load, see Section 5.2. Tables 3 and 4 should be seen against the backdrop of monotonic test-tomodel comparisons by Sigrist et al 15 and Sykora et al 16 :…”

Section: Introductionmentioning

confidence: 98%

Cyclic shear resistance for seismic design, based on monotonic shear models in fib Model Code 2010 and in the 2018 draft of Eurocode 2

Biskinis

Fardis

2019

Shear resistance decays during cycling of inelastic deformations, causing flexural plastic hinges to fail in cyclic shear before reaching their ultimate flexural deformation. The monotonic shear model in MC2010 does not work for shear failure after flexural yielding. Accurate, unbiased, lack‐of‐fit‐free prediction of cyclic shear resistance, before or after flexural yielding, is possible, if: (a) inelasticity is considered in the calculation of longitudinal strains at section mid‐depth, through the “equal displacement rule” of Earthquake Engineering; (b) axial forces are taken to contribute to shear resistance with the transverse component of the diagonal strut between member ends; (c) the Eurocode 2 shear model for loads near supports is used for squat members; and (d) minor changes are made to the minimum compression field angle and the concrete strength reduction along it in MC2010, Levels II or III of approximation.

“…This clearly shows that if filter is not applied COV increases because of diverse shear behavior, for a given a v / d , exhibited by beams in unfiltered database. This is also true for higher order moments like skewness and kurtosis which gets significantly affected by filtering criteria (see Figure ) as pointed out by Sykora et al In the study conducted by Sykora et al, the aim was to address the biases and scatters in the predictions using fib shear capacity equation. Therefore, distribution of shear capacity was not discussed and was considered as an open area of research.…”

Section: Modeling Errormentioning

confidence: 92%

Probabilistic studies on mechanics‐based shear capacity models for reinforced concrete beams with stirrups

Jayakumar

Kanchi

2019

The efficiency of shear capacity models of reinforced concrete beams with stirrups depends on the assumed mechanism and in few cases depends also on critical shear crack angle prediction. In the present study, three mechanics‐based shear capacity models (the limit analysis‐based models presented by Nielsen and Hoang, and the Mari et al. model) are considered covering the range space of shear span to effective depth ratios greater than 2.5. The statistics of modeling error associated with these models are determined using the database created in this study. The database contains limited results of experimental investigations, available in literature, on shear capacity of reinforced concrete beams with stirrups. The randomness in shear capacity is quantified by performing probabilistic analysis of one set of nominally similar beams taken from the database. Based on the shear capacity distribution obtained, characteristic design equations of reinforced concrete beams are proposed. The results of reliability analyses show that the reliability of a beam, for a given mean live to dead load ratio, varies when different shear capacity models are used in the analysis. Thus, calibration studies need to be performed for selecting a model for design.