Parameter identification of rockfall protection barrier components through an inverse formulation

•We developed accurate macroscopic finite element models of wire-rope cables and wire ring-nets.•We applied parameter optimization techniques to find the best fit model parameters.•We proposed a numerical approach to model rockfall barrier connections in a realistic manner.•We proved the accuracy of...

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Bibliographic Details
Published inEngineering structures Vol. 77; pp. 1 - 16
Main Authors Escallón, J.P., Wendeler, C., Chatzi, E., Bartelt, P.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 15.10.2014
Elsevier
Subjects
Applied sciences
Buildings. Public works
Computation methods. Tables. Charts
Exact sciences and technology
Finite element model
Geotechnics
Miscellaneous
Multi-island genetic algorithm
Parameter optimization
Rockfall barrier
Structural analysis. Stresses
Finite element model
Parameter optimization
Rockfall barrier
Multi-island genetic algorithm
Protective device
Connection
Barrier
Rockfalls
Modeling
Optimization
Finite element method
Energy dissipation
Flexible structure
System description
Formulation
Wire rope
Safety net
Numerical simulation
Computing method
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Summary:•We developed accurate macroscopic finite element models of wire-rope cables and wire ring-nets.•We applied parameter optimization techniques to find the best fit model parameters.•We proposed a numerical approach to model rockfall barrier connections in a realistic manner.•We proved the accuracy of the proposed models based on simulation results of field tests. Rockfall barriers are key protection systems in mountainous regions worldwide. They are designed to intercept and capture falling rocks. Most systems are composed of flexible steel wire-nets connected to wire-rope cables which are in turn attached to steel posts and anchored to the ground. Additional energy dissipating devices can be connected to the cables to enhance the performance of the barriers. The composition and geometrical arrangement of wires forming net components and cables are a severe limitation to realistic finite element (FE) modeling of rockfall barriers. Detailed models are computationally expensive. Therefore, macroscopic models reflecting the system behavior on a coarser scale, i.e., the global behavior, need to be derived. In this work, macroscopic FE models pertaining to the modeling of the wire-ring net and the spiral cables have been developed and investigated. Material plasticity, damage initiation and ductile damage are taken into account. The non-linear force displacement response obtained in laboratory tests has been successfully reproduced by introducing additional parameters. An inverse optimization process based on the multi-island genetic algorithm is used for the determination of model parameters. The developed numerical approach succeeds in modeling rockfall barrier connections in a manner that is more refined than previous attempts, yet of low computational expense. The accuracy of this approach is verified by the match between simulation and test results of a full scale rockfall barrier prototype that was tested according to the ETAG027 standard.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2014.07.019