Cuvillier Verlag

Publications, Dissertations, Habilitations & Brochures.
International Specialist Publishing House for Science and Economy

Cuvillier Verlag

De En Es
Experimental and Theoretical Investigations of Wicking in Porous Media

Hard Copy
EUR 62.80

E-book
EUR 0.00

Download
PDF (4.2 MB)
Open Access CC BY 4.0

Experimental and Theoretical Investigations of Wicking in Porous Media (English shop)

Yulia Grebenyuk (Author)

Preview

Extract, PDF (110 KB)
Table of Contents, PDF (45 KB)

ISBN-13 (Hard Copy) 9783736997271
ISBN-13 (eBook) 9783736987272
Language English
Page Number 222
Lamination of Cover glossy
Edition 1.
Publication Place Göttingen
Place of Dissertation Bremen
Publication Date 2018-02-05
General Categorization Dissertation
Departments Engineering
Technical mechanics
Mechanical and process engineering
Keywords Wicking, Imbibition, Capillary pressure, Cryogenic liquid, Evaporation, Porous media, Ceramics, Permeability, Porosity, Pore size
Description

The aim of this work is to advance the knowledge on the behavior of fluids in porous materials. Wicking, or imbibition, is a spontaneous penetration of liquid into porous media due to capillary forces. Due to the challenges of the capillary transport of cryogenic liquids, the wicking of liquid nitrogen subjected to evaporation was of a special interest for this research. For that, a novel test facility was built to perform experiments in a one-species system under pre-defined non-isothermal conditions. Two one-dimensional macroscopic wicking models were proposed to evaluate the impact of the porous sample superheat, geometrical and structural characteristics as well as the impact of the vapor flow created due to evaporation. In the second part of this work, the capillary transport abilities of porous ceramic monoliths of anisotropic structure were studied. The polymer-derived ceramic samples fabricated with the freeze-casting method were characterized via vertical wicking tests. In the third part, the capillary transport properties of porous media and the wicking process were examined using the computational fluid dynamics software. The results of benchmark microscopic and macroscopic simulations may serve as a basis for further numerical investigations of fluid flow problems in porous media.