Moisture equilibrium in the vertical in swelling soils. I. Basic theory

Soil Research ◽  
1969 ◽  
Vol 7 (2) ◽  
pp. 99 ◽  
Author(s):  
JR Philip
Keyword(s):  
Soil Mechanics ◽  
Scalar Potential ◽  
Moisture Ratio ◽  
Moisture Distribution ◽  
Soil Physics ◽  
Swelling Soils ◽  
Total Potential ◽  
Common Notion ◽  
Classical Behaviour ◽  
Equilibrium Profile

The classical methodology of the scalar potential is used to develop the theory of equilibrium moisture distribution in the vertical in swelling soils. In addition to the well-known moisture potential � and the gravitational potential -z (z being the vertical ordinate, taken positive downward), the total potential � includes a further component �, the overburden potential. It is shown that � = de/d� [P(Zo) + ?zzo] (A) where e is the void ratio, 6 is the moisture ratio, P(zJ is the load (if any) at the surface z = z,, and y is the apparent wet specific gravity. The equilibrium condition that � be constant in depth reduces to a first-order differential equation, the solutions of which represent equilibrium moisture profiles. The singular solution � = �pt for all z > zo (B) separates two distinct classes of non-singular solutions. �p, designated the pycnotatic point, is the moisture ratio at which � assumes its maximum value. Swelling soils satisfying certain conditions (which appear to be theoretically reasonable and agree with the data of soil physics and soil mechanics) possess one, and only one, pycnotatic point. In such soils, then, three distinct types of equilibrium profile occur: (i) Hydric profiles, for which the surface moisture ratio �o > �p. 6 decreases with increasing z, asymptotically approaching 8, at great depths. (ii) Pycnotaticprojiles, for which 8, = aP and equation (B) is satisfied. (iii) Xeric profiles, for which �o < �p. � increases with z, asymptotically approaching �p at great depths. The physical significance of this result is discussed with the aid of calculations for an illustrative example. The hydrology of swelling soils is entirely different in character from classical hydrological behaviour, which ignores the consequences of volume change. Contrary to a common notion, the effects of overburden potential manifest themselves right to the surface of the soil: it is not the magnitude of n, but that of d�/dz, which is important. The effect of swelling on the behaviour of the soil water may be crudely summarized as follows: Gravity operates completely in reverse to the expectations of classical theory in the 'normal' part of the hydric range; its effect diminishes to zero at the pycnotatic point; and it approaches classical behaviour at the dry end of the xeric range. Applications of the analysis to equilibrium states in hydrology and soil mechanics are treated in Part II. In later papers the concept of the overburden potential is applied to steady vertical flows and to infiltration in swelling soils.

Moisture equilibrium in the vertical in swelling soils. II. Applications

Soil Research ◽  
1969 ◽  
Vol 7 (2) ◽  
pp. 121 ◽  
Author(s):  
JR Philip
Keyword(s):  
Hydraulic Conductivity ◽  
Water Table ◽  
Soil Mechanics ◽  
Three Dimensional ◽  
Moisture Distribution ◽  
Specific Yield ◽  
Swelling Soils ◽  
Total Potential ◽  
Equilibrium Distributions ◽  
Moisture Profiles

The paper discusses, with the aid of calculated examples, applications in hydrology and soil mechanics of the analysis developed in Part I. Various classical concepts of groundwater hydrology fail completely for swelling soils. The distributions of saturation and of hydraulic conductivity relative to the water table differ entirely from the conventional picture. Variations in surface topography affect moisture distribution in swelling soils. The theory of this effect is developed for topographies that are not too steep and is illustrated by examples. The equilibrium distributions found would be classically interpreted as disequilibrium states persisting because of small hydraulic conductivity; but, in fact, the moisture differentials are maintained, not by a lack of conductivity, but by a lack of difference in total potential. The variation of specific yield with water table elevation and stratum thickness in swelling soils is basically different from that in non-swelling soils. The analysis of Part I is used to discuss the following topics in soil mechanics: the variation of equilibrium soil levels with water-table depth, and with water depth over the soil; the effect of surface loading on equilibrium moisture profiles and on soil levels. Extension of the analysis to two- and three-dimensional systems is treated briefly.

scholarly journals Characterization of Low-Cost Capacitive Soil Moisture Sensors for IoT Networks

Sensors ◽  
2020 ◽  
Vol 20 (12) ◽  
pp. 3585 ◽  
Author(s):  
Pisana Placidi ◽  
Laura Gasperini ◽  
Alessandro Grassi ◽  
Manuela Cecconi ◽  
Andrea Scorzoni
Keyword(s):  
Soil Moisture ◽  
Soil Mechanics ◽  
Low Cost ◽  
Rapid Development ◽  
Accurate Determination ◽  
Volume Ratio ◽  
Capacitive Sensor ◽  
Soil Physics ◽  
Moisture Sensor

The rapid development and wide application of the IoT (Internet of Things) has pushed toward the improvement of current practices in greenhouse technology and agriculture in general, through automation and informatization. The experimental and accurate determination of soil moisture is a matter of great importance in different scientific fields, such as agronomy, soil physics, geology, hydraulics, and soil mechanics. This paper focuses on the experimental characterization of a commercial low-cost “capacitive” coplanar soil moisture sensor that can be housed in distributed nodes for IoT applications. It is shown that at least for a well-defined type of soil with a constant solid matter to volume ratio, this type of capacitive sensor yields a reliable relationship between output voltage and gravimetric water content.

The role of lateral stresses on soil water relations in swelling clays

Soil Research ◽  
1986 ◽  
Vol 24 (4) ◽  
pp. 457 ◽  
Author(s):  
BG Richards
Keyword(s):  
Soil Water ◽  
Water Relations ◽  
Soil Water Potential ◽  
Three Dimensional ◽  
Soil Physics ◽  
Swelling Soils ◽  
Simple Theories ◽  
Swelling Clays ◽  
Swelling Soil ◽  
Stress States

The moisture characteristic of a swelling soil is the result of complex interaction between the soil water potential and imposed mechanical stresses. This can give rise to soil water profiles which cannot be interpreted by soil water theories for non-swelling soils. Agricultural soil physics has been concerned primarily with highly structured surface soils, and has developed simple theories for the effects of stress on soil water relations in swelling soils. These simple theories ignore the effect of lateral stress in the soil. Civil engineers, on the other hand, dealing mainly with less complex soils at depth, have developed more complex theories for the effect of three-dimensional stress states on soil water relations. This paper shows how the effect of three-dimensional stress can and should be included in soil water studies of swelling soils, and gives examples to demonstrate the possible magnitude of such effects.

Moisture profiles in swelling soils

Soil Research ◽  
1974 ◽  
Vol 12 (2) ◽  
pp. 71 ◽  
Author(s):  
T Talsma
Keyword(s):  
Water Table ◽  
Water Movement ◽  
Moisture Gradient ◽  
Clay Soils ◽  
Upward Flow ◽  
Swelling Soils ◽  
Equilibrium Profile ◽  
Moisture Profiles

In situ moisture profiles are examined, in two soils of clay texture and in a loam, for the condition of equilibrium about a water table. In addition, moisture profiles during periods of approximately steady upward flow are examined in one of the soils of clay texture. Equilibrium moisture profiles in the clay soils are typical of the 'hydric' profiles which have been predicted for swelling materials. Upward water movement occurs against the moisture gradient. The equilibrium profile in the loam is typical of those observed for non-swelling materials.

Hydrology of swelling soils: a review

Soil Research ◽  
2000 ◽  
Vol 38 (3) ◽  
pp. 501 ◽  
Author(s):  
D. E. Smiles
Keyword(s):  
Water Flow ◽  
Liquid Flow ◽  
Soil Mechanics ◽  
Material Balance ◽  
Flow Equation ◽  
Richards Equation ◽  
Gravitational Potential Energy ◽  
Future Research ◽  
Swelling Soils ◽  
Wide Range

A generally accepted theory of liquid flow in rigid systems has been used in soil science for more than 50 years. Liquid flow in systems that change volume with liquid content is not so well described and remains a major challenge to soil scientists, although its application in chemical and mining engineering and soil mechanics is increasingly accepted. Theory of water flow in swelling soils must satisfy material continuity. It must also account for changes in the gravitational potential energy of the system during swelling and for anisotropic stresses that constrain the soil laterally but permit vertical movement. A macroscopic and phenomenological analysis based on material balance and Darcy’s law is the most useful first approach to water flow and volume change in such soils. Use of a material coordinate based on the solid distribution results in a flow equation analogous to that L. A. Richards enunciated for non-swelling soils. This framework is strain-independent and solutions to the flow equation exist for a wide range of practically important conditions. The approach has been well tested in clay suspensions and saturated systems such as mine tailings and sediments. It is also applied in soil mechanics. This paper reviews central elements in application of the analysis to swelling soils. It argues that, as with use of the Richards’ equation in rigid soils, complexities are evident, but the approach remains the most coherent and profitable to support current need and future research. The use of material coordinates, to ensure material balance is assessed correctly, is simple.

Corrigendum to: Hydrology of swelling soils: a review

Soil Research ◽  
2001 ◽  
Vol 39 (6) ◽  
pp. 1467
Author(s):  
D. E. Smiles
Keyword(s):  
Water Flow ◽  
Liquid Flow ◽  
Soil Mechanics ◽  
Material Balance ◽  
Flow Equation ◽  
Richards Equation ◽  
Gravitational Potential Energy ◽  
Future Research ◽  
Swelling Soils ◽  
Wide Range

A generally accepted theory of liquid flow in rigid systems has been used in soil science for more than 50 years. Liquid flow in systems that change volume with liquid content is not so well described and remains a major challenge to soil scientists, although its application in chemical and mining engineering and soil mechanics is increasingly accepted. Theory of water flow in swelling soils must satisfy material continuity. It must also account for changes in the gravitational potential energy of the system during swelling and for anisotropic stresses that constrain the soil laterally but permit vertical movement. A macroscopic and phenomenological analysis based on material balance and Darcy’s law is the most useful first approach to water flow and volume change in such soils. Use of a material coordinate based on the solid distribution results in a flow equation analogous to that L. A. Richards enunciated for non-swelling soils. This framework is strain-independent and solutions to the flow equation exist for a wide range of practically important conditions. The approach has been well tested in clay suspensions and saturated systems such as mine tailings and sediments. It is also applied in soil mechanics. This paper reviews central elements in application of the analysis to swelling soils. It argues that, as with use of the Richards’ equation in rigid soils, complexities are evident, but the approach remains the most coherent and profitable to support current need and future research. The use of material coordinates, to ensure material balance is assessed correctly, is simple.

Identification and Performance of Swelling Soil Types

1965 ◽  
Vol 2 (2) ◽  
pp. 141-153 ◽  
Author(s):  
R M Hardy
Keyword(s):  
Soil Mechanics ◽  
Swelling Pressure ◽  
Soil Types ◽  
Engineering Practice ◽  
Swelling Soils ◽  
Design Practices ◽  
Swelling Soil ◽  
Current Design ◽  
Swelling Characteristics ◽  
And Performance

Many soil types, both overconsolidated and normally consolidated, in the Prairie provinces and northwestern Canada display high swelling characteristics. Experience has shown that conventional theories of soil mechanics are inadequate to predict accurately the performance of such soils in engineering practice. The paper discusses procedures for the identification of highly swelling soils and for numerically evaluating potential swelling pressures. Modifications to current design practices are suggested and the importance of swelling pressure concepts in engineering practice are discussed.

Contemporary Progress in Porous Media Theory

2000 ◽  
Vol 53 (12) ◽  
pp. 323-370 ◽  
Author(s):  
Reint de Boer
Keyword(s):  
Porous Media ◽  
Historical Development ◽  
Chemical Engineering ◽  
Volume Fraction ◽  
Soil Mechanics ◽  
Petroleum Industry ◽  
Entropy Inequality ◽  
Media Theory ◽  
Soil Physics ◽  
Porous Media Theory

In the last decade and, in particular in recent years, the macroscopic porous media theory has made decisive progress concerning the fundamentals of the theory and the development of mathematical models in various fields of engineering and biomechanics. This progress attracted some attention and therefore conferences (colloquia, symposia, etc) devoted almost exclusively to the macroscopic porous media theory have been organized in the last three years in Cambridge, United Kingdom (1996), Prague, the Czech Republic (1997), Essen, Germany (1997), Metz, France (1999), Stuttgart, Germany (1999) and Chicago, USA (2000) in order to collect all findings, to present new results, and to discuss new trends. Also in national and international journals a great number of important contributions have been published which has brought the porous media theory, in some parts, to a close. Therefore, the time seems to be ripe to review the state of the art. The Introduction is devoted to the historical development up to the end of the 1980s and the beginning of the 1990s (readers interested in an extended description of the historical development of the porous media theory are referred to de Boer, 2000). The volume fraction concept is formulated in Section 2. An extensive review of the kinematics in porous media theory is presented in Section 3. The balance equations and the entropy inequality are discussed in Sections 4 and 5. Section 6 is devoted to the investigation of the closure problem and the saturation condition. The constitutive theory with the description of elastic, elastic-plastic, and viscous states of the porous solid as well as some reflexions on the constitutive behavior of the pore fluids are represented in Section 7. Finally, some applications of the porous media theory in various fields (soil mechanics, chemical engineering, biomechanics and building physics as well as in environmental mechanics, soil physics, the petroleum industry, and material science) will demonstrate the usefulness of the macroscopic porous media theory. This review article contains 209 references.

scholarly journals Bearing Capacity of very Expansive Soils at Jatinangor Area, West Java, Indonesia

2018 ◽  
Vol 147 ◽  
pp. 07003
Author(s):  
David Simangunsong ◽  
Satrio Wibowo ◽  
Zufialdi Zakaria
Keyword(s):  
Bearing Capacity ◽  
Correlation Coefficient ◽  
Expansive Soils ◽  
Soil Mechanics ◽  
Expansive Soil ◽  
Soil Physics ◽  
West Java ◽  
Allowable Bearing Capacity ◽  
Shrinkage And Swelling

Expansive soil is a kind of soil that has ability to shrinkage and swelling. According to Ronny (2014) Jatinangor area has expansive soil that is so very influential in the planning of infrastructure construction. This research aimed to measure the bearing capacity of the very expansive soils in Jatinangor area and to determine the correlation between activity number of soil and its bearing capacity. The method used is to collect the soil physics and mechanics data. Based on the soil mechanics data, the research location is divided into three zones of allowable bearing capacity, those are zone with allowable bearing capacity < 4 T/m2, zone with allowable bearing capacity 4-7 T/m2, and zone with allowable bearing capacity > 7 T/m2. The correlation between activity number and bearing capacity of soil follows the equation qa = -1.9505(A) + 6.957 with correlation coefficient is -0.7911.

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