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J Dewanckele, T De Kock, MA Boone, V Cnudde, L Brabant, MN Boone, G Fronteau, L Van Hoorebeke, P Jacobs (2012)
4D imaging and quantification of pore structure modifications inside natural building stones by means of high resolution X-ray CTSci Total Environ, 416
M Dohnal, J Dusek, T Vogel (2010)
Improving hydraulic conductivity estimates from Minidisk infiltrometer measurements for soils with wide pore-size distributionsSoil Sci Soc Am J, 74
D Vandevoorde, M Pamplona, O Schalm, Y Vanhellemont, V Cnudde, E Verhaeven (2009)
Contact sponge method: performance of a promising tool for measuring the initial water absorptionJournal of Cultural Heritage, 10
C Hall, W. Hoff (2002)
Water transport in brick, stone and concrete
R Haverkamp, PJ Ross, KRJ Smettem, JY Parlange (1994)
Three-dimensional analysis of infiltration from the disc infiltrometer. 2. Physically based infiltration equationWater Resour Res, 30
E Wendler, R Snethlage (1989)
Der Wassereindringprüfer nach Karsten—Anwendung und Interpretation der MesswerteBautenschutz + Bausanierung, 12
KRJ Smettem, JY Parlange, PJ Ross, R Haverkamp (1994)
Three-dimensional analysis of infiltration from the disc infiltrometer. 1. A capillary-based theoryWater Resour Res, 30
M Van Genuchten (1980)
A closed-form equation for the prediction of the hydraulic conductivity of unsaturated soilsSoil Sci Soc Am J, 44
(1980)
Recommended tests to measure the deterioration of stone and to assess the effectiveness of treatment methodsMater Struct, 13
Over the last decades the Karsten tube has been used as a versatile testing device to measure the water absorption of porous walls. It is non-destructive and it can give reproducible results when used accurately. A major drawback however is the lack of a physical interpretation of the results. This paper uses analytical models and a numerical simulation in 3D to allow a more fundamental and general interpretation of the test results. A relatively simple model for a soil infiltrometer test was proven to give a good fit to experimental field data and to lab test results. 3D numerical simulations, performed with Delphin 5 software, provide extra insight about the correctness of the model assumptions of a sharp front process and a simplified shape of the wetting front. A supplementary measurement of the increase of the diameter of the wetted zone during the test allows a straightforward calculation of the capillary saturated moisture content and the sorptivity of the material. Moreover an analytical relation is presented between the results of the Karsten test as described in the old standards and the sorptivity.
Materials and Structures – Springer Journals
Published: Nov 22, 2012
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