Smith's Elements of Soil Mechanics. Ian Smith
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Название: Smith's Elements of Soil Mechanics

Автор: Ian Smith

Издательство: John Wiley & Sons Limited

Жанр: Отраслевые издания

Серия:

isbn: 9781119750413

isbn:

СКАЧАТЬ voids of a soil may be filled with air or water or both. If only air is present the soil is dry, whereas if only water is present the soil is saturated. When both air and water are present the soil is said to be partially saturated. These three conditions are represented in Fig. 1.12a–c.

      The degree of saturation is simply:

      (1.9)equation

      (usually expressed as a percentage)

      For a dry soil, Sr = 0

      For a saturated soil, Sr = 1.0

      1.7.3 Particle density, ρs and specific gravity, Gs

      The specific gravity of a material is the ratio of the weight or mass of a volume of the material to the weight or mass of an equal volume of water. In soil mechanics the most important specific gravity is that of the actual soil grains and is given the symbol Gs.

      From the above definition it is seen that for a soil sample with volume of solids, Vs, mass of solids, Ms and weight of solids, Ws,

      (1.10)equation

      where ρw is the density of water (=1.0 Mg/m3 at 20 °C) and γw is the unit weight of water (=9.81 kN/m3).

      The density of the particles ρs is defined as:

equation Schematic illustration of water and air contents in a soil. (a) Dry soil. (b) Saturated soil. (c) Partially saturated soil.

      therefore,

equation

      If ρs is measured in units of Mg/m3 and the water temperature is assumed to be 20 °C, it follows that ρs and Gs are numerically equal. Gs, however is dimensionless whereas ρs has the units of density, Mg/m3.

      Particle density is determined in the laboratory through a well‐established and reliable testing procedure (described in BS EN ISO 17892‐3:2015, BSI, 2015). A mass of dry soil is mixed with distilled water in a standard glass vessel known as a pycnometer to separate all the particles and to enable all the air to be removed from the soil. In the test the difference in the volumes of water required to fill the pycnometer, both with and without the soil present, is determined. The particle density is equal to the dry mass of the soil divided by that volume difference.

Schematic illustration of pycnometer used in the determination of particle density. (a) Pycnometer filled with water only. (b) Pycnometer filled with soil and water.

      The mass of an empty pycnometer, together with its glass stopper, was 178.0 g. When completely filled with water and the stopper fitted the mass was 228.2 g. An oven dried sample of soil was placed in the pycnometer and the total mass, including the stopper, was 191.2 g. Water was added to the soil and, after a suitable period of shaking, was topped up until the vessel was brim full. The stopper was fitted and the total mass was found to be 236.4 g.

      Determine the particle density of the soil.

       Solution:

equation equation equation equation equation equation

      The particle density can be quickly found from a formula thus:

equation

      where

       ms = mass of dry soil (g)

       m1 = mass of pycnometer + water (g)

       m2 = mass of pycnometer + water + soil (g)

      1.7.4 Density and unit weight

      The amount of material in a given volume, V, may be expressed in two ways:

      the amount of mass, M, in the volume, or the amount of weight, W, in the volume.

      If we consider unit volume, the two systems give the mass density and the weight density of the material respectively. The mass density is usually simply referred to as density and the weight density is routinely referred to as the unit weight:

      (1.11)СКАЧАТЬ