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Saturday, 1 December 2018

Index Properties of Soil

Index Properties:
  • These are the properties useful for classification and identification of soils.
  • Also give rough estimation of Engineering properties of soils.
  • Example: Particle size distribution and relative density for coarse grained soils and consistency limits for fine grained soils.

Engineering Properties:
  • These are the properties useful for engineering applications.
  • Examples: Permeability, Compressibility and shear strength.

Shape of Particles: Engineering properties of coarse grained soil depends on shape of particles
Particle size distribution:
  • Sieve analysis is used for coarse grained soils.
  • Wet sieve analysis is suitable if soil contains fines.
  • Sedimentation analysis or wet analysis is used for fine grained soils, finer than 75 micron , size.
  • Sedimentation analysis is based on Stoke’s law.
  • Stoke’s law is valid only if the size of the particle is between 0.2mm and O.2 micron.
  • Pipette method is the standard sedimentation method used in laboratory. It is an accurate method.
  • Dispersion solution containing 33g of the sodium hexametaphosphate and 7g. of sodium carbonate in distilled water to make one litre of solution. 
  • The process of removal organic matter and calcium compounds is known as pre treatment.
  • The hydrometer method of sedimentation analysis differs from the pipette analysis in the method of taking observations only.


>>Approximate version of Stroke’s Law, vs= 900 d2
Where
  • V velocity, in mm/sec
  • d = Diameter of particle, in mm.
Corrections to hydrometer reading:
  • Meniscus correction Cm is always positive.
  • Dispersing agent correction Cd is always negative.
  • Temperature correction is positive when greater than 27°C and negative when less than 27°C.
  • The hydrometer readings increase on the downward direction towards the hydrometer bulb.
  • Reading is taken corresponding to the upper level of the meniscus.
Particle size distribution curve :

Particle size distribution curve : It gives an idea about type of soil and gradation of soil.
  • Well graded soil: Soil contains good representation of particles of all sizes.
  • Gap graded soil: Excess of certain particles and deficiency of others. cr
  • Uniformly grades soil: Most of the particles are of the same size.
  • For coarse grained soils sizes D10, D30 and D60 are important.

Effective size (or) effective diameter (D10): Expressed in ‘mm’ It means, only 10% of particles are finer than this size.
Coefficient of uniformity(Cu): D60 / D10
  • It is a measure of particle size range. It is always greater than or equal to 1.
  • A soil is called uniformly graded if Cu lies between 1 and 2.
  • For a well graded gravel, C must be greater than 4.
  • Where as for a well graded sand, Cu must be greater than 6.

Coefficient of curvature (Cc): 

  • It represents shape of particle size curve.
  • For well grades soils, C lies between 1 and 3.
  • For uniformly graded soils, C = 1.

Relative density (or) Density index (ID)):
  • Most important for coarse grained soils.
  • Indicates relative compactness of soils.

  • emax = Max.void ratio (in loosest state)
  • emin = Min. void ratio (in densest state)
  • e = natural void ratio
  • Range in %age  0  ≤ ID  ≤ 100.

Limits of consistency (Atterberg'S  limits) :
  • Mostly used for fine grained soils.
  • Atterberg divided the entire range from liquid to solid state into four stages.

  1. Liquid state
  2. Plastic state
  3. Semisolid state
  4. Solid state.

  • Atterberg limits are the water contents at which soil mass passes from one state to the next.

Liquid Limit:
  • It is the minimum water content at which the soil is still in the liquid state, but has a small shearing strength against flowing.
  • It is the minimum water content at which part of a soil cut by a groove of standard dimensions will flow together for a distance of 12mm under an impact of 25 blows in the device.

Apparatus: Casa grand’s apparatus is used to determine liquid limit.



Flow Curve:

  • Flow curve gives an idea of shear strength variation with water content of the soil.
  • Soil passing through 424 micron IS sieve is used for the test.
  • The drop of the cup on hard base is 1 cm.
  • The shear strength õf the soil at liquid limit is about 2.7 kN/m2

Plastic Limit (Wp): It is the minimum water content at which the soil can be rolled into a thread of 3 mm in diameter without crumbling. It is determined by Plastic limit test or ‘Thread Test’.

Shrinkage Limit (Ws): It is the moisture content after which further loss of moisture does not cause a decrease in the volume of the soil.
Shrinkage limit is lowest water content at which a soil can still be completely  saturated. At shrinkage limit the shrinkage ceases.



Shrinkage Ratio : Volume change expressed in terms of percentage of dry volume to the corresponding change in moisture content.

>>Note: Shrinkage ratio of a soil is equal to the mass specific gravity of its dry state. (Gm.)




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