UID:
almahu_9947362541302882
Umfang:
XV, 148 p. 104 illus., 16 illus. in color.
,
online resource.
Ausgabe:
1st ed. 2015.
ISBN:
9783319245102
Serie:
Springer Theses, Recognizing Outstanding Ph.D. Research,
Inhalt:
This pioneering work deals with the parameterization of rockfalls in the context of 3D run-out modelling at a study site in the Bavarian Alps. The main objective was to cover not only low-magnitude, high-frequency rockfalls (〈10 m3) but also Mid-Magnitude events, which involve rock volumes of between 10 and 100 m3 (boulder falls) and between 100 and 10,000 m3 (block falls). As Mid-Magnitude events have been insufficiently covered in terms of rockfall modelling up to now, a geomechanical approach has been developed to characterize those events by means of a case study. For a 200 m3 limestone block a potential failure scenario was analysed by combining a deterministic failure analysis with a numerical process-based run-out model. To model potential run-out scenarios of the 200 m3 block, the beta version of the code RAMMS::Rockfall, developed by the Swiss Institute for Snow and Avalanche Research (SLF), was applied. RAMMS::Rockfall makes it possible to include the block shape and thus consider the effects of varying block shapes on the run-out distance. The run-out modelling for the entire project site was performed using the scientific code Rockyfor3D (Dorren/ecorisQ). To provide quantitative information in terms of input parameters, a field recording of block sizes at the talus slope, as well as a detailed discontinuity analysis at the source area, were conducted. The book successfully demonstrates how detailed and quantitative field investigation can contribute to 3D rockfall modelling.
Anmerkung:
Aims and objectives -- State of the art -- Study site -- Methodology -- Results -- Discussion -- Conclusion -- Outreach.
In:
Springer eBooks
Weitere Ausg.:
Printed edition: ISBN 9783319245096
Sprache:
Englisch
DOI:
10.1007/978-3-319-24510-2
URL:
http://dx.doi.org/10.1007/978-3-319-24510-2
