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Compressive strength of an unsaturated granular material during cementation

TitleCompressive strength of an unsaturated granular material during cementation
Publication TypeConference Proceedings
Year of Publication2011
AuthorsDelenne J-Y, Soulié F, El Youssoufi M S, Radjaï F
SponsorTechnol GPowder Sci, Powderes & Sintered Mat Comm, Mat FSoc Met &, Grp FCeram
Conference NameSymposium on Science and Technology of Powders and Sintered Materials (STPMF 2009)
VolumePOWDER TECHNOLOGY
Number of Volumes208 Issue: 2 Special Issue: SI
Pagination308 - 311
Date PublishedMar-25-2011
Conference LocationMAY 25-27 2009 Montpellier, FRANCE
ISBN00325910
Abstract

The cohesive behaviour of unsaturated granular materials is due to the presence of cohesive bonds between grains. These bonds can have various physico-chemical characteristics and may evolve with environmental conditions. We study the case of a granular material partially saturated by an aqueous solution. The bonds are thus initially of capillary type and the mechanical strength is weak. At low relative humidity, the phase change of water involves crystallization of the solute at the contact points between grains, generating thus solid bonds. The mechanical strength of the material is then enhanced. An experimental study of the evolution of the mechanical strength during crystallization of the solute shows clearly the transition from capillary regime to cemented regime. This transition is not correlated with the mass of the crystallized solute, but rather with the residual degree of saturation. This behavior is analyzed here in the light of discrete element simulations. We introduce a local cohesion law that accounts for transition from capillary to cemented bonding. This law is formulated in terms of the degree of crystallization as a result of the evaporation of water at the boundary of the sample. The cohesion of the packing is initially of capillary type. A crystallization front then spreads from the sample boundaries to the center of the sample, and the strength increases as a result. Uniaxial compression allows us to determine the strength at different times. The numerical strength agrees well with the experimental data, and reveals strength enhancement as the solute crystallizes, as well as the transition from capillary to cementation regime.

DOI10.1016/j.powtec.2010.08.021
Short TitlePowder Technology
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