Introducing Meta-models for a More Efficient Hazard Mitigation Strategy with Rockfall Protection Barriers

• Published in: Rock mechanics and rock engineering Vol. 51; no. 4; pp. 1097 - 1109
• Main Authors: Toe, David, Mentani, Alessio, Govoni, Laura, Bourrier, Franck, Gottardi, Guido, Lambert, Stéphane
• Format: Journal Article
• Language: English
• Published: Vienna Springer Vienna 01.04.2018; Springer Nature B.V; Springer Verlag
• Subjects: Accuracy; Barriers; Civil Engineering; Computer simulation; Earth and Environmental Science; Earth Sciences; Emergency preparedness; Environmental hazards; Geophysics/Geodesy; Hazard assessment; Hazard mitigation; Kinetic energy; Mathematical models; Mechanics; Mitigation; Model accuracy; Original Paper; Parameters; Physics; Protection; Rockfall; Simulation; Structural mechanics; Trajectory analysis; Rockfall mitigation; Meta-model; Barrier; Deterministic model; Deterministic model 21
• ISSN: 0723-2632; 1434-453X
• DOI: 10.1007/s00603-017-1394-9

The paper presents a new approach to assess the effecctiveness of rockfall protection barriers, accounting for the wide variety of impact conditions observed on natural sites. This approach makes use of meta-models, considering a widely used rockfall barrier type and was developed from on FE simulation results. Six input parameters relevant to the block impact conditions have been considered. Two meta-models were developed concerning the barrier capability either of stopping the block or in reducing its kinetic energy. The outcome of the parameters range on the meta-model accuracy has been also investigated. The results of the study reveal that the meta-models are effective in reproducing with accuracy the response of the barrier to any impact conditions, providing a formidable tool to support the design of these structures. Furthermore, allowing to accommodate the effects of the impact conditions on the prediction of the block–barrier interaction, the approach can be successfully used in combination with rockfall trajectory simulation tools to improve rockfall quantitative hazard assessment and optimise rockfall mitigation strategies.