Details zur Publikation

Kategorie Textpublikation
Referenztyp Zeitschriften
DOI 10.1007/s12665-017-7080-0
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Titel (primär) Hydromechanical modelling of the SEALEX experiments
Autor Yi, H.; Wang, W. ORCID logo ; Kolditz, O. ORCID logo ; Shao, H.; Zhou, H.
Quelle Environmental Earth Sciences
Erscheinungsjahr 2017
Department ENVINF
Band/Volume 76
Heft 21
Seite von art. 737
Sprache englisch
Keywords Hydromechanics; SEALEX; Bentonite–sand mixture; DECOVALEX; OpenGeoSys
UFZ Querschnittsthemen RU5;
Abstract Numerical modelling of coupled physical processes in bentonite–sand mixtures under the geological conditions is significant for designing and constructing sealing systems in deep underground repositories for highly radioactive nuclear waste. Within the framework of DECOVALEX 2015, Task A, this work presents the model validation of OpenGeoSys by numerical modelling of coupled hydromechanical (HM) processes in bentonite–sand mixtures. Parameters used in the HM model were determined by modelling the laboratory tests of the sealing experiment (SEALEX). Afterwards these parameters were applied for the modelling of a small-scale mock-up test considering the influence of technological gap and incidental fail of the seal in the sealing system. In order to investigate the availability of employing these HM parameters and numerical models directly to field predictions, the modelling results and measured data of an in situ SEALEX experiment were analysed comparatively. The modelling results reproduced well the main features in HM behaviour of the compacted bentonite–sand mixture, which denotes that the adopted HM models and parameters are adequate for describing the HM processes in the sealing system. It is necessary to take the elastoplastic behaviour and evolution of the permeability of bentonite–sand mixtures into account when using the adopted models to reproduce the HM processes of a sealing system.
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Yi, H., Wang, W., Kolditz, O., Shao, H., Zhou, H. (2017):
Hydromechanical modelling of the SEALEX experiments
Environ. Earth Sci. 76 (21), art. 737 10.1007/s12665-017-7080-0