Experimental and Numerical Investigation of Material Non-Linearity in Steel Elements Under Different Loading Protocols
Citation
YAPICI, Orhan, A. Necmettin GÜNDÜZ & Cenk AKSOYLAR. "Experimental and Numerical Investigation of Material Non-Linearity in Steel Elements Under Different Loading Protocols". Structures, 20 (2019): 74-87.Abstract
In order to investigate the behaviour of a steel structure and provide effective design, most of the time analyses
procedures which can take account the non-linear material behaviour are needed. These non-linear analysis
procedures which are widely applied with different levels of accuracy, adopt two major approaches which can be
classified as lumped plasticity and distributed plasticity models. This paper aims to analyze the accuracy of two
different plasticity approaches such as lumped and distributed plasticity models on providing the non-linear
material behaviour of steel elements under different loading protocols by comparing numerical and experimental
results. In the first part, monotonic and cyclic quasi static tests and pseudo dynamic tests under instantaneous
constant load and seismic load are conducted by using the small scale Load and Boundary Condition
Box. Small scale steel specimens are used for the experiments. Results of the experiments are comprehensively
reported. In the second part of the study, several numerical models are generated for each test. Monotonic and
cyclic loading pushover analyses are carried out with both lumped plasticity models and distributed plasticity
models. In these numerical studies, different types of material models are considered and numerical analysis
results are validated against the experimental results. Accuracy of lumped plasticity and distributed plasticity
models are assessed and a comprehensive comparison of different analysis and material models is reported. It is
generally observed that using the fiber based method with bilinear kinematic hardening material model provides
more accurate element responses for hot rolled steels.