Abstract

Issues concerning the advanced numerical analysis of concrete building structures in sophisticated computing systems currently require the involvement of nonlinear mechanics tools. The efforts to design safer, more durable and mainly more economically efficient concrete structures are supported via the use of advanced nonlinear concrete material models and the geometrically nonlinear approach. The application of nonlinear mechanics tools undoubtedly presents another step towards the approximation of the real behaviour of concrete building structures within the framework of computer numerical simulations. However, the success rate of this application depends on having a perfect understanding of the behaviour of the concrete material models used and having a perfect understanding of the used material model parameters meaning. The effective application of nonlinear concrete material models within computer simulations often becomes very problematic because these material models very often contain parameters (material constants) whose values are difficult to obtain. However, getting of the correct values of material parameters is very important to ensure proper function of a concrete material model used. Today, one possibility, which permits successful solution of the mentioned problem, is the use of optimization algorithms for the purpose of the optimization-based inverse material parameter identification. Parameter identification goes hand in hand with experimental investigation while it trying to find parameter values of the used material model so that the resulting data obtained from the computer simulation will best approximate the experimental data. This paper is focused on the optimization-based inverse identification of the parameters of a concrete cap material model which is known under the name the Continuous Surface Cap Model. Within this paper, material parameters of the model are identified on the basis of interaction between nonlinear computer simulations, gradient based and nature inspired optimization algorithms and experimental data, the latter of which take the form of a load-extension curve obtained from the evaluation of uniaxial tensile test results. The aim of this research was to obtain material model parameters corresponding to the quasi-static tensile loading which may be further used for the research involving dynamic and high-speed tensile loading. Based on the obtained results it can be concluded that the set goal has been reached.

Highlights

  • Continuous and extensive use of concrete for the purpose of building the new structures currently leads to the efforts of refine the design of concrete structures through the computer numerical simulations based on the finite element method [1,2,3]

  • The involvement of tools of the advanced numerical analysis especially means that it is necessary to consider the nonlinear behaviour of concrete within the context of computer simulations intended for the analysis and design of concrete structures

  • In this paper, the material parameters of the Continuous Surface Cap Model were identified via optimization methods implemented in the optiSLang program

Read more

Summary

Introduction

Continuous and extensive use of concrete for the purpose of building the new structures currently leads to the efforts of refine the design of concrete structures through the computer numerical simulations based on the finite element method [1,2,3]. Parameters of the material model are identified on the basis of interaction between nonlinear computer simulations, gradient based and nature inspired optimization algorithms implemented in the optiSLang program and experimental data, the latter of which take the form of a load-extension curve obtained from the evaluation of unconfined uniaxial tensile test results. Computer simulations The process of the optimization-based inverse parameter identification performed in this paper further demanded performing of nonlinear computer simulations For this purpose, the simplified computational model of the unconfined uniaxial tensile test was created in LS-Dyna software which is based on an explicit finite element method and in which the nonlinear computer simulations were performed. The fact, that the material model allows to calculate the quasi-static response, was used within this paper

Parameter description
Optimized values
Conclusions

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.