Lime treatment of plastic clays with special focus on triaxial extension behaviour

Kan, Kuchvichea

13 October 2020

Clay soils can be stabilized by the chemical reaction between the clay particles and lime to produce calcium aluminate and calcium silicate minerals. This cementation effect on clay particles result in increasing the strength of lime-treated clay soils. The mechanical strengths (compressive, tensile and shear strengths) of clay soils are improved from soft to stiff behavior by treating with lime and evolve along the curing time.An extensive experimental investigation has been carried out using laboratory reconstituted (compacted) expansive soils, covering a range of plasticity indices. Four selected soils with different fundamental physical and mechanical behaviors have been used to stabilize with lime. In addition to basic geomechanical characterization tests (modified proctor compaction, uniaxial compression strength, indirect tensile strength, oedometric compression, direct shear tests), a special focus was put on triaxial compression and extension tests upon drained and undrained conditions. Also, the development of swelling pressure upon wetting was also carefully investigated.The shear behavior of compacted clay soils is experimentally investigated by using both direct shear test and triaxial shear tests. These tests were conducted on saturated specimens for four selected soils. It is observed that the shear strength of both tests is evolving with addition of lime and with the plasticity index. In addition to the strength parameters, triaxial shear test was also used to determine the Young modulus of treated soils. It was noticed that the lime treatment increases the elastic modulus of selected clay soils.The triaxial compression system was modified to a triaxial extension system in order to evaluate the triaxial tensile strength of one of the tested soils (N1, from Quenast, Belgium). The pure tensile strength of soils can be determined from triaxial extension test at low confining pressures while high confining pressures induces shear failure.The failure criteria of lime-treated soils were studied in different stress planes to evaluate the shear and tensile strength obtained from triaxial extension test and triaxial compression test. A combined rupture criterion of original and modified Griffith criteria was applied. The results obtained from experimental testing have shown that at low confining pressures, the failure stress of extension test followed the Original Griffith Criterion started from pure tension, and at the higher confining pressures the failure stress followed the Modified Griffith (equivalent to Mohr-Coulomb, in this case).In application of this combined equation, the result of four selected soils obtained from triaxial tension test, direct shear test and triaxial compression test was plotted in the (sigma,to) in order to verify this equation. These experimental results match with the combined equation.This analysis revealed the strong interest of extension triaxial tests, with respect to more conventional indirect tension tests (also called splitting tests). Extension triaxial tests allow to control the drainage conditions and performed a full effective stress analysis of the stress-strain responses, including pre-failure behavior and ultimate strength criterion. Also, it provides a smooth transition between shear strength and tensile strength criterion, depending on the confining pressure of the test.At the end of this work, experimental results are analyzed and correlated with several parameters. Shear strength, compression index and swelling pressure were found to depend primarily on plasticity index for both treated and untreated materials. Many approaches in literature have also expressed these mechanical properties of soils in function of plasticity index. However, there are a few equations matching closely to testing results. For the development of swelling pressure upon wetting, a modified equation was proposed for experimental data for non-treated soils and lime-treated soils. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Mécanique des sols

Lime treatment

plastic clays

triaxial extension

Two-scale geomechanical characterization of sand-bentonite mixtures treated with lime

Hashemi Afrapoli, Mir Amid

30 November 2015

The use of lime for soil stabilization has greatly increased since the second half of the 20th century. A lot of research has been conducted to understand the mechanisms of stabilization. These mechanisms are caused by pozzolanic reactions between lime and clay minerals. However, it has not yet been possible to quantify the factors affecting the evolution of these reactions. The variety of soils and the disruptive elements do not allow comparing these soils with each other and giving any quantitative and generalized conclusions in terms of mechanical improvement. The goal of this study is to build a progressive understanding of this phenomenon by avoiding any disruptive elements and controlling most of the parameters. Consequently, the choice is made to study a synthetic soil by controlling its particle size distribution and composition. This soil is a mixture of sand and bentonite taken at different compositions. An analysis of the evolution of lime treatment on such model soils is carried out on two scales: the macroscopic scale and the microscopic scale. The macroscopic scale studies the evolution through unconfined compressive strength, lime consumption, electrical resistivity as well as complementary studies such as sonic and triaxial tests. Results from macroscopic tests show that sand takes an important part into soil stabilization, meaning that a soil containing a lot of clay does not necessary give the best long term mechanical characteristics. Tests that allow a much more detailed comprehension of stabilization are also presented. Microscopic evolution is studied through X-Ray Computed Tomography and Mercury Intrusion Porosimetry. A study on tomographic image treatment has also been carried out to segment the images from its different constituents. / L'utilisation de la chaux pour stabiliser le sol s'est considérablement déve-lop-pée depuis la seconde moitié du 20e siècle. De nombreuses recherches ont vu le jour pour comprendre les mécanis-mes de cette stabilisation. Ces mé-ca-nis-mes sont causés par les réactions pouzzolaniques entre la chaux et les minéraux argileux. Cependant, il n'a pas encore été possible de quantifier totalement les facteurs influençant le déroulement de ces réactions. La diversité des sols et la présence d'éléments perturbateurs ne permettent pas de les comparer et d'en tirer des conclusions quantitatives et généralisables en termes d'amélioration des paramètres mécaniques. Cette étude envisage donc de construire une compréhension progressive du phénomène en ne prenant pas en compte les éléments perturbateurs et en contrôlant à priori un maximum de paramètres. Pour ce faire, il est proposé d'étudier un sol synthétique dont la granulométrie et la composition peuvent être contrôlées. Ce sol est un mélange de sable et de bentonite pris à différentes compositions. Une analyse sur l'évolution du traitement à la chaux est alors effectuée sur ces mélanges sur deux échelles :l'échelle macroscopique et l'échelle microscopique. L'échelle macroscopique envisage des essais de compression simple, de consommation de chaux, de résistivité électrique ainsi que des essais complémentaires tels que les essais soniques et triaxiaux. Les résultats macroscopiques montrent que le sable joue un rôle important dans la stabilisation, le sol présentant la fraction argileuse la plus importante n'ayant pas les meilleures caractéristiques mécaniques à long terme. Les tests permettant une compréhension plus fine de cette stabilisation sont également présentés. L'échelle microscopique est étudiée via la tomographie aux rayons-X et la porosimétrie au mercure. Une étude sur le traitement des images tomographiques est aussi mise en oeuvre pour segmenter de manière adéquate les images de ses différents constituants. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Mécanique des sols

Lime Treatment

Sand Bentonite Mixtures

X-Ray Micro Computed Tomography

Étude des propriétés thermo-hydro-mécaniques des sols fins traités à la chaux / Investigating the thermo-hydro-mechanical properties of lime-treated fine-grained soils

Wang, Yejiao

02 December 2016

Le traitement à la chaux est une technique qui améliore considérablement la maniabilité et le comportement mécanique des sols à problèmes. Cependant, la durabilité de ce traitement dans les ouvrages en terre sur le long terme représente un enjeu important pour leur stabilité. En outre, la procédure de mise en place, et par conséquent, la taille des agrégats qui en résulte, est un paramètre essentiel qui peut influencer le comportement des sols traités à la chaux utilisés dans le domaine de la construction d’ouvrages. Ce travail de thèse vise à étudier le comportement thermo-hydro-mécanique des sols traités à la chaux, et plus particulièrement les effets du temps de cure et de la taille des agrégats. Des échantillons de sols limoneux et argileux traités à la chaux ont été préparés avec des agrégats de différentes tailles puis soumis à des temps de cures plus ou moins longs. Ces matériaux ont ensuite été étudiés à travers des observations de la microstructure, des analyses minéralogiques, des mesures de la conductivité thermique, de la perméabilité à l’air et de la capacité de rétention d'eau, complétées par de la détermination de la compressibilité et des mesures des modules de cisaillement en petites déformations. Les résultats montrent que le traitement à la chaux modifie de manière significative le comportement thermo-hydro-mécanique des sols. De plus, le comportement des sols traités est fortement influencé par la taille des agrégats. Plus celle-ci est grande, plus la conductivité thermique et la perméabilité à l'air est importante. En revanche, la capacité de rétention en eau est diminuée de même que la compressibilité et la rigidité du sol / Lime treatment is a technique which greatly improves the workability and the mechanical behaviour of problematic soils. However, the sustainability of this treatment in the earthworks for the long term is an important issue for their stability. Besides, the aggregate size resulting from the construction procedure is an essential parameter that may influence the behaviour of treated soils in field construction. The present work deals with the thermo-hydro-mechanical properties of lime-treated soils, with an emphasis put on the curing time and the aggregate size effects. Lime-treated soil samples (both silt and clay) were prepared with different sizes of aggregates and cured during different periods. Afterwards, these soils were studied through microstructural observations, mineralogical analyses, thermal conductivity, air permeability and water retention capacity measurements, as well as the determinations of compressibility and small strain shear modulus. The results show that significant changes of thermo-hydro-mechanical behaviour of soils are induced by lime treatment after curing. Moreover, the aggregate size also plays an essential role in the behaviour of treated soils. Samples prepared with the large aggregates present higher thermal conductivity and air permeability, but with lower water retention capacity, poorer compression behaviour and smaller stiffness

Traitement à la chaux

Taille des agrégats

Propriétés thermo-Hydro-Méchanique

Lime treatment

Aggregates size

Thermo-Hydro-Mechanical properties

The effects of compaction delay and environmental temperature on the Mechanical and Hydraulic properties of lime-stabilized extremely high plastic clays

Ali, Hatim, Mohamed, Mostafa H.A.

18 October 2017

yes / A comprehensive experimental programme was performed with the focus on assessing the effects of compaction delay and ambient temperature on the physical, mechanical and hydraulic properties of lime treated expansive clays. Specimens were mellowed for a period of 0, 3, 6, 12, 24 and 48 h at two different temperatures of 20°C and 40°C prior to being compacted, tested and/or cured for up to 28 days for evaluating the impacts on long-term strength development. All specimens were prepared with the same dry unit weight of 12.16 kN/m3 and moisture content of 40% except for tests aimed at determining dry unit weight as a function of mellowing period. The results revealed that as the mellowing duration increased the dry unit weight declined remarkably at both temperature within the first 12 h. In addition, higher reduction rate was observed when specimens were mel-lowed at a temperature of 40°C. A 97% reduction in swelling pressure was obtained when the specimens were compacted upon mixing (zero hour mellowing period) and left to cure for 24 h prior to testing. Permeability coefficient of lime treated expansive clays was increased by up to 40 times when compaction was delayed for 24 h or when specimens were mellowed at 40°C. Specimens mellowed at a temperature of 40°C showed rela-tively stable values of permeability coefficient over the measurement period which could be attributable to accelerated pozzolanic reaction. The Unconfined Compressive Strength tests revealed that strength of lime treated expansive clays is significantly affected by compaction delay. An increase of 234% and 282% in the Unconfined Compressive Strength was achieved after 24 h of mixing with no compaction delay at 20°C and 40°C respectively. Gradual long-term gain in strength was observable within the 28 days post mixing but the rate of strength gain becomes slower and independent of temperature after the first 24 h of mixing. The results sug-gested that the four key reaction mechanisms occur concurrently with the first 12–24 h after lime addition recognized as being the most crucial period of time. Damaging the cementitious compounds by delayed com-paction is harmful to strength and restraining of swelling potential of lime treated expansive clays.

The effects of lime content and environmental temperature on the mechanical and hydraulic properties of extremely high plastic clays

Ali., H., Mohamed, Mostafa H.A.

25 April 2018

Yes / This paper focuses on monitoring the evolution of lime-clay reactions using geotechnical parameters as a function of lime content and environmental temperature. Lime contents of 5, 7, 9, 11 and 13% by dry weight of expansive clay powder were added to prepare lime-clay specimens. The specimens were prepared at the same dry unit weight of 12.16 kN/m3 and moisture content of 40% except for tests aimed at the determination of dry unit weight as a function of mellowing period. Prepared specimens were mellowed or cured at two different ambient temperatures of 20 °C and 40 °C. Results attained from Unconfined Compressive Strength and permeability tests were employed to assess the impact of lime content on the mechanical and hydraulic properties of lime treated expansive clays. The results revealed that at the beginning, the rate of strength gain is remarkably fast for a particular period of time which is dependent on lime content. Furthermore, the strength gain on specimens cured at 40 °C is 8 times higher than that observed on specimens cured at 20 °C which highlights significant effect for the environmental temperature on accelerating the chemical reactions. Reduced dry unit weight due to increased resistance to compactability is observable with increasing lime content and higher environmental temperature. Accelerated pozzolanic reaction at higher environmental temperature resulted in permeability coefficient of specimens mellowed for 24 h at 40 °C to be higher than those mellowed at 20 °C. The results also highlighted that the permeability coefficient would be relatively stable when expansive clays were treated with small amounts of lime e.g. 5%.

Lime treatment

Expansive clay

Mechanical behaviour

Hydraulic behaviour

Swelling pressure

Unconfined compressive strength

Application of Various Pretreatment Methods to Enhance Biogas Potential of Waste Chicken Feathers

Khorshidi Kashani, Azar

January 2009

Chicken feathers are the most abundant keratinous biomass in the world. Disposal of thehuge and increasing volume of waste feathers presents as a major concern for poultryindustry. On the other hand, energy and material recovery of this valuable protein sourceis an important issue for organic solid waste treatment and bioenergy generation.Anaerobic digestion is an environmentally and economically promising alternativeprocess for biogas production of waste feathers.In this study in order to enhance the methane potential of batch anaerobic digestion ofchicken feathers this waste was treated by various kinds of pretreatments includingthermal, thermo-chemical, enzymatic, thermo-enzymatic and chemo-enzymatic methods.Also the effect of different treatment conditions on the methane yield was investigated.As a whole, thermo-chemical pretreatment with lime (Ca(OH)2) rendered the mostsignificant effect on enhancement of the chicken feathers methane potential. In particularlime treated triplicate samples under treatment condition of 40g TS feather/l water, 0.1gCa (OH)2 /g TS feather, 100°C and 30 min produced the highest amount of methane (anaverage maximum volume of 480 Nml/g VS, which is about 96.8% of the theoreticalmethane potential of protein), during 50 days of anaerobic incubation. Increasing theoperational parameters such as feather concentration, lime loading, temperature andreaction time improved the feathers solublisation resulting in a higher soluble chemicaloxygen demand (SCOD) concentration of the samples but inserted negative impacts onthe anaerobic digestion performance. Although other pretreatment methods improved theSCOD concentrations of the feathers too, compared to the lime treatment those methodsdidn’t show considerable effects on the enhancement of methane yield from the chickenfeathers. Thermo-enzymatic, enzymatic, and thermal pretreated triplicate samplesproduced an average maximum of 185 Nml/g VS, 154 Nml/g VS, and 143 Nml/g VS(37.3%, 31%, 28.8% of the theoretical methane potential) respectively, during 33 days of50 days of anaerobic incubation. Especially, chemo-enzymatic pretreated sample showednegative methane potential of only 41 Nml/g VS, i.e. 8% of the theoretical methanepotential. Consequently, lime pretreatment under the above recommended conditions canbe suggested for hydrolysis of chicken feathers to achieve significant enhancement of itsmethane potential.

chicken feathers

keratin protein

biogas potential

lime treatment

enzymatic treatment

chemo-enzymatic treatment

Engineering and Technology

Teknik och teknologier

Traitement des sols argileux à la chaux : processus physico-chimique et propriétés géotechniques / Treatment of clay soils with lime : physico-chemical reactions and geotechnical properties

Lasledj, Abdelmadjid

03 December 2009

Le traitement des sols à la chaux est une technique ancienne et efficace dans les travaux de génie civil. Dans l'objectif du « zéro emprunt/zéro déchet » dans les travaux de terrassement routier, cette étude démontre que quelles que soient la plasticité et la médiocrité des propriétés hydromécaniques des sols argileux, le traitement à la chaux s'avère efficace. Les résultats expérimentaux concernant un sol argileux extrêmement plastique et gonflant montrent que les propriétés géotechniques s'améliorent avec le traitement à la chaux : le gonflement est éliminé, la plasticité réduite fortement et la résistance mécanique augmentée. Le suivi du processus physico-chimique de la réaction chaux–argile a permis de déterminer les quantités de chaux nécessaires aux changements instantanés ou/et durables du comportement hydromécanique des sols argileux traités. L'échange cationique poursuivi par la réaction pouzzolanique induisent dans les sols traités des modifications minéralogiques, texturales et structurales. Des hydrates calciques nouveaux sont formés grâce à la consommation de la chaux et des argiles. Ces hydrates tapissent les bords des particules argileuses et constituent une couche qui enrobent et assurent le lien entre les particules. Ces changements sont ainsi à l'origine des améliorations des propriétés géotechniques des sols traités. Les travaux de recherche réalisés démontrent que le processus et la cinétique des réactions chaux– argile dépendent du cation échangeable, de la quantité de chaux disponible, de la température de maturation et de la structure de l'argile : smectite, illite ou kaolinite. / Lime treatment techniques have largely been developed across the word mainly in civil engineering works. The context of sustainable development implies to improve the rate of reuse of clay soils in the earthworks. This study demonstrates that whatever the plasticity and poor hydromechanical properties of clay soils, the lime treatment is effective. Experimental results on highly plastic clay soil show that all geotechnical properties progress with the lime treatment: the swelling is eliminated, the plasticity is reduced greatly and the strength increases. Monitoring the physicochemical lime-clay reaction allowe to determine the quantities of lime required for short term and/or long term changes in the hydromechanical behaviour of treated clay soils. The cation exchange pursued by the pozzolanic reactions induced mineralogical, textural and structural changes in the treated soil. New hydrates are formed through the consumption of lime and clay. These hydrates contour the edges of clay particles and formed a layer which coat and provide the link between particles. These changes are well behind improvements in geotechnical properties of treated soil. The research conducted in this thesis shows that the process and the kinetics of lime-clay reactions depend on the exchangeable cation, the amount of lime available, to the curing temperature and the structure of the clay smectite, illite and kaolinite.

Traitement à la chaux

Argile plastique

Processus physico-chimique

Propriétés géotechniques

Lime treatment

Highly plastic clay

Physiochemical reaction

Geotechnical properties

Stabilisation des sols traités à la chaux et leur comportement au gel / Stabilization of lime treated soils and their behaviour under frost

Nguyen, Thi Thanh Hang

21 April 2015

On s'intéresse dans le présent travail au comportement au gel des sols fins limono-argileux traités à la chaux seule, sols valorisables qui sont couramment rencontrés sur les chantiers de terrassement. Trois sols appartenant aux classifications A1, A2, A3 selon la norme NF P 11300, ont été choisis pour cette étude. Ces sols sont traités à 3 dosages en chaux correspondant à 3 objectifs : 1) amélioration (dosage en chaux minimal), 2) stabilisation et insensibilité à l'eau (dosage en chaux intermédiaire), 3) stabilisation et résistance au gel (dosage en chaux le plus élevé). Les sols traités sont ensuite conservés pendant quatre périodes de cure : 7 jours, 28 jours, 90 jours et 365 jours. Les deux processus de gel - le géligonflement et la gélifraction sont étudiés, parallèlement à l'évaluation des performances mécaniques, hydrauliques et microstructurales. Les résultats expérimentaux ont montré que les propriétés hydrauliques (la succion au front de gel, sp et la conductivité hydraulique à l'état non-saturé, kunsat) sont les paramètres qui gouvernent le phénomène de géligonflement des sols, traités ou non. Les résultats ont également mis en évidence le lien direct existant entre la microstructure (la distribution porale) et les propriétés hydrauliques du sol, principalement en termes de capacité de rétention d'eau et conductivité hydraulique. Le traitement augmente les performances mécaniques des sols d'une part, et amène d'autre part à des modifications de leur microstructure ; ceci induit des changements vis-à-vis de leur sensibilité au gel. Les sols sont plus gélifs directement après le traitement, cette sensibilité au gel diminuant avec le temps de cure. Une modélisation simple permettant d'estimer le gonflement au gel à partir de la succion au front de gel et de la valeur de conductivité hydraulique à l'état non-saturé a été proposée et validée. Vu que la détermination de la conductivité hydraulique à l'état non-saturé n'est pas un essai couramment pratiqué au sein de la plupart des laboratoires, un critère basé sur la succion au front de gel, sp, et la conductivité hydraulique à l'état saturé, ksat a été proposé pour évaluer la sensibilité des sols au gel. L'essai de gélifraction consiste à évaluer un coefficient de résistance de l'éprouvette de sol après 10 cycles de gel/dégel, RFT (%) - « retained strength factor after freeze-thaw testing ». Les résultats expérimentaux montrent que la valeur RFT des sols traités varie de 0% (lorsque les éprouvettes de sol perdent totalement leur résistance à la compression simple et sont détruites après 10 cycles de gel/dégel) à 90%. Quand RFT ≥ 60%, aucune dégradation visuelle de la surface des éprouvettes des sols traités n'est constatée. Ainsi, cette valeur est proposée comme critère d'acceptation des matériaux constitutifs d'une couche de forme subissant le gel avant son recouvrement. L'étude de l'effet du nombre des cycles de gel/dégel montre une diminution importante de la performance mécanique (RFT) durant trois premiers cycles de gel/dégel, et ce paramètre se stabilisant après 10 cycles. A l'aide de la technique de µ Tomographie X, l'endommagement interne des éprouvettes de sol ayant subi des cycles de gel/dégel a été quantifié. Une corrélation directe entre la diminution de performance mécanique et l'augmentation de l'indice de l'endommagement de l'éprouvette a été mise en évidence. Enfin, un modèle d'endommagement permettant d'évaluer la dégradation de la performance mécanique avec l'augmentation de l'indice d'endommagement a été établi / The present work deals with the behaviour of fine-grained silty and clayey soils treated with lime under frost. Those soils are frequently encountered in earthworks. Three soils corresponding to A1, A2, A3 classes according French NF P 11-300 standard were chosen for this study. These soils were treated with 3 lime dosages corresponding to three objectives: 1) improvement (minimum dosage), 2) stabilization and insensitivity to water (intermediate dosage), 3) stabilization and frost resistance (highest dosage). Lime-treated soils were subsequently cured for different times: 7, 28, 90, 365 days. Two frost processes, frost heave and freeze-thaw cycles, were applied in parallel with the assessment of mechanical, hydraulic and microstructural properties. Experimental results evidenced that it is the hydraulic properties (suction at frost front, sp and unsaturated hydraulic conductivity, kunsat) that govern the frost heave phenomenon of soils, treated or not. In addition, this study demonstrates the direct link between the microstructure (the pore size distribution) and the hydraulic properties (water retention curve and hydraulic conductivity). The treatment on one hand improves the mechanical performances of soils, and on the other hand modify their microstructure, and thus changes their frost sensitivity. The frost susceptibility increases directly after treatment, and then decreases with curing time. Based on the suction at frost front and the unsaturated hydraulic conductivity, a simple model was proposed and validated allowing to estimate the frost heave. Considering that the determination of unsaturated hydraulic conductivity is not a test commonly performed by most laboratories, a criterion based on the suction at frost front and the saturated hydraulic conductivity was proposed to estimate the frost sensibility of soils. The second frost resistance test consists of measuring the retained strength factor after 10 freeze-thaw cycles, RFT (%). The results obtained show that RFT of lime treated soil varies from 0% (when soil specimen completely loses its resistance and collapses after 10 freezethaw cycles) to 90%. When RFT is higher than 60%, no visual damage was observed on the specimen surface; consequently, this value is proposed as a criterion for acceptance of lime treated soil in capping layer before covering. In addition, the study of effect of freeze-thaw cycles showed a significant decrease of mechanical performance (RFT) during the first three cycles, and a stabilization after 10 cycles. Using X-ray Tomography, the intern damage of specimens due to freeze-thaw cycles was quantified. A correlation between the decrease of mechanical performance and the increase of damage index was evidenced. A model was then developed to evaluate the degradation of mechanical performance with the increase of damage index

Sols fins limono-Argileux

Traitement à la chaux

Géligonflement

Performances mécaniques

Propriétés hydrauliques

Microstructure

Fine-Grained silty and clayey soils

Lime treatment. frost heave

Freeze-Thaw cycles

Freezing-Thawing essai

Hydraulic properties

Microstructure

Stabilisation des sols traités à la chaux et leur comportement au gel / Stabilization of lime treated soils and their behaviour under frost

Nguyen, Thi Thanh Hang

21 April 2015

On s'intéresse dans le présent travail au comportement au gel des sols fins limono-argileux traités à la chaux seule, sols valorisables qui sont couramment rencontrés sur les chantiers de terrassement. Trois sols appartenant aux classifications A1, A2, A3 selon la norme NF P 11300, ont été choisis pour cette étude. Ces sols sont traités à 3 dosages en chaux correspondant à 3 objectifs : 1) amélioration (dosage en chaux minimal), 2) stabilisation et insensibilité à l'eau (dosage en chaux intermédiaire), 3) stabilisation et résistance au gel (dosage en chaux le plus élevé). Les sols traités sont ensuite conservés pendant quatre périodes de cure : 7 jours, 28 jours, 90 jours et 365 jours. Les deux processus de gel - le géligonflement et la gélifraction sont étudiés, parallèlement à l'évaluation des performances mécaniques, hydrauliques et microstructurales. Les résultats expérimentaux ont montré que les propriétés hydrauliques (la succion au front de gel, sp et la conductivité hydraulique à l'état non-saturé, kunsat) sont les paramètres qui gouvernent le phénomène de géligonflement des sols, traités ou non. Les résultats ont également mis en évidence le lien direct existant entre la microstructure (la distribution porale) et les propriétés hydrauliques du sol, principalement en termes de capacité de rétention d'eau et conductivité hydraulique. Le traitement augmente les performances mécaniques des sols d'une part, et amène d'autre part à des modifications de leur microstructure ; ceci induit des changements vis-à-vis de leur sensibilité au gel. Les sols sont plus gélifs directement après le traitement, cette sensibilité au gel diminuant avec le temps de cure. Une modélisation simple permettant d'estimer le gonflement au gel à partir de la succion au front de gel et de la valeur de conductivité hydraulique à l'état non-saturé a été proposée et validée. Vu que la détermination de la conductivité hydraulique à l'état non-saturé n'est pas un essai couramment pratiqué au sein de la plupart des laboratoires, un critère basé sur la succion au front de gel, sp, et la conductivité hydraulique à l'état saturé, ksat a été proposé pour évaluer la sensibilité des sols au gel. L'essai de gélifraction consiste à évaluer un coefficient de résistance de l'éprouvette de sol après 10 cycles de gel/dégel, RFT (%) - « retained strength factor after freeze-thaw testing ». Les résultats expérimentaux montrent que la valeur RFT des sols traités varie de 0% (lorsque les éprouvettes de sol perdent totalement leur résistance à la compression simple et sont détruites après 10 cycles de gel/dégel) à 90%. Quand RFT ≥ 60%, aucune dégradation visuelle de la surface des éprouvettes des sols traités n'est constatée. Ainsi, cette valeur est proposée comme critère d'acceptation des matériaux constitutifs d'une couche de forme subissant le gel avant son recouvrement. L'étude de l'effet du nombre des cycles de gel/dégel montre une diminution importante de la performance mécanique (RFT) durant trois premiers cycles de gel/dégel, et ce paramètre se stabilisant après 10 cycles. A l'aide de la technique de µ Tomographie X, l'endommagement interne des éprouvettes de sol ayant subi des cycles de gel/dégel a été quantifié. Une corrélation directe entre la diminution de performance mécanique et l'augmentation de l'indice de l'endommagement de l'éprouvette a été mise en évidence. Enfin, un modèle d'endommagement permettant d'évaluer la dégradation de la performance mécanique avec l'augmentation de l'indice d'endommagement a été établi / The present work deals with the behaviour of fine-grained silty and clayey soils treated with lime under frost. Those soils are frequently encountered in earthworks. Three soils corresponding to A1, A2, A3 classes according French NF P 11-300 standard were chosen for this study. These soils were treated with 3 lime dosages corresponding to three objectives: 1) improvement (minimum dosage), 2) stabilization and insensitivity to water (intermediate dosage), 3) stabilization and frost resistance (highest dosage). Lime-treated soils were subsequently cured for different times: 7, 28, 90, 365 days. Two frost processes, frost heave and freeze-thaw cycles, were applied in parallel with the assessment of mechanical, hydraulic and microstructural properties. Experimental results evidenced that it is the hydraulic properties (suction at frost front, sp and unsaturated hydraulic conductivity, kunsat) that govern the frost heave phenomenon of soils, treated or not. In addition, this study demonstrates the direct link between the microstructure (the pore size distribution) and the hydraulic properties (water retention curve and hydraulic conductivity). The treatment on one hand improves the mechanical performances of soils, and on the other hand modify their microstructure, and thus changes their frost sensitivity. The frost susceptibility increases directly after treatment, and then decreases with curing time. Based on the suction at frost front and the unsaturated hydraulic conductivity, a simple model was proposed and validated allowing to estimate the frost heave. Considering that the determination of unsaturated hydraulic conductivity is not a test commonly performed by most laboratories, a criterion based on the suction at frost front and the saturated hydraulic conductivity was proposed to estimate the frost sensibility of soils. The second frost resistance test consists of measuring the retained strength factor after 10 freeze-thaw cycles, RFT (%). The results obtained show that RFT of lime treated soil varies from 0% (when soil specimen completely loses its resistance and collapses after 10 freezethaw cycles) to 90%. When RFT is higher than 60%, no visual damage was observed on the specimen surface; consequently, this value is proposed as a criterion for acceptance of lime treated soil in capping layer before covering. In addition, the study of effect of freeze-thaw cycles showed a significant decrease of mechanical performance (RFT) during the first three cycles, and a stabilization after 10 cycles. Using X-ray Tomography, the intern damage of specimens due to freeze-thaw cycles was quantified. A correlation between the decrease of mechanical performance and the increase of damage index was evidenced. A model was then developed to evaluate the degradation of mechanical performance with the increase of damage index

Sols fins limono-Argileux

Traitement à la chaux

Géligonflement

Performances mécaniques

Propriétés hydrauliques

Microstructure

Fine-Grained silty and clayey soils

Lime treatment. frost heave

Freeze-Thaw cycles

Freezing-Thawing essai

Hydraulic properties

Microstructure