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Constant Head Flow
Constant head permeameter is recommended for coarse-grained soils only since for such soils, flow rate is measurable with adequate precision. As water flows through a sample of cross-section area A, steady total head drop h is measured across length L.  

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Permeability is obtained from: 
Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Falling Head Flow
Falling head permeameter is recommended for fine-grained soils. 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

 

Total head h in standpipe of area a is allowed to fall. Hydraulic gradient varies with time. Heads h1 and h2 are measured at times t1 and t2. At any time t, flow through the soil sample of cross-sectional area A is

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)    ------------------------(1)                  

Flow in unit time through the standpipe of cross-sectional area a is

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) ------------------------(2)   

Equating (1) and (2) ,

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)   
Integrating between the limits, 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Field Tests for Permeability

 

Field or in-situ measurement of permeability avoids the difficulties involved in obtaining and setting up undisturbed samples in a permeameter. It also provides information about bulk permeability, rather than merely the permeability of a small sample.

A field permeability test consists of pumping out water from a main well and observing the resulting drawdown surface of the original horizontal water table from at least two observation wells. When a steady state of flow is reached, the flow quantity and the levels in the observation wells are noted.

Two important field tests for determining permeability are: Unconfined flow pumping test, and confined flow pumping tes

Unconfined Flow Pumping Test

 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

In this test, the pumping causes a drawdown in an unconfined (i.e. open surface) soil stratum, and generates a radial flow of water towards the pumping well. The steady-state heads h1 and h2 in observation wells at radii r1 and r2 are monitored till the flow rate becomes steady.

The rate of radial flow through any cylindrical surface around the pumping well is equal to the amount of water pumped out. Consider such a surface having radius r, thickness dr and height h. The hydraulic gradient is

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Area of flow, Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

From Darcy's Law,

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) 
Arranging and integrating,

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)
Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Confined Flow Pumping Test
Artesian conditions can exist in a aquifer of thickness D confined both above and below by impermeable strata. In this, the drawdown water table is above the upper surface of the aquifer. 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

For a cylindrical surface at radius r,

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)
Integrating,Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)
Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)
Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) 

Permeability of Stratified Deposits

When a soil deposit consists of a number of horizontal layers having different permeabilities, the average value of permeability can be obtained separately for both vertical flow and horizontal flow, as kVand kH respectively.

Consider a stratified soil having horizontal layers of thickness H1H2H3, etc. with coefficients of permeability k1k2k3, etc.

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

 

For vertical flow
The flow rate q through each layer per unit area is the same.

 

q = q=q2

Let be the equivalent hydraulic gradient over the total thickness and let the hydraulic gradients in the layers be i1, i2, i3etc. respectively.

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) ............... where kV = Average vertical permeability

 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

The total head drop h across the layers is

 

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

 

Horizontal flow
When the flow is horizontal, the hydraulic gradient is the same in each layer, but the quantity of flow is different in each layer.

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

The total flow is

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Considering unit width normal to the cross-section plane,

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

 

 

Worked Examples

Example 1:  Determine the following:
(a) Equivalent coefficient of vertical permeability of the three layers
(b) The rate of flow per m2 of plan area
(c) The total head loss in the three layers

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Solution: 

(a)  Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) = 1.33 x 10-3 cm/s

(b) Considering an area A = 1 m2 =1 x 10cm2

q = k.i.A =  Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) = 7 x 10-4 x 0.25/2 x (1x104) = 0.875 cm3/s per m2 of plan area

(c) For continuity of flow, velocity is the same.

  Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)  where Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) = total head loss in three layers

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Example 2: For a field pumping test, a well was sunk through a horizontal stratum of sand 14.5 thick and underlain by a clay stratum.Two observation wells were sunk at horizontal distances of 16 m and 34 m respectively from the pumping well.The initial position of the water table was 2.2 m below ground level.

At a steady-state pumping rate of 1850 litres/min, the drawdowns in the observation wells were found to be 2.45 m and 1.20 m respectively. Calculate the coefficient of permeability of the sand.

Solution:

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)

 r1 = 16 m
 r2 = 34 m
 h1 = 14.5 - 2.2 - 2.45 = 9.85 m
 h2= 14.5 - 2.2 - 1.2 = 11.1 m

   k =  Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE)   = 2.82 x 10-4 m/s  = 1.41 x 10-2 cm/s 

The document Laboratory Measurement of Permeability | Soil Mechanics - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Soil Mechanics.
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FAQs on Laboratory Measurement of Permeability - Soil Mechanics - Civil Engineering (CE)

1. What is permeability and why is it important in civil engineering?
Ans. Permeability refers to the ability of a material to allow fluids or gases to pass through it. In civil engineering, permeability is crucial as it determines the ease with which water or other fluids can flow through soil or rock. This information is essential for designing infrastructure such as drainage systems, underground tunnels, and retaining walls, as well as for understanding the behavior of soil and rock formations during construction and environmental studies.
2. How is permeability measured in a laboratory setting?
Ans. Permeability can be measured in the laboratory using various methods. One commonly used method is the constant head permeameter, where a constant water head is maintained on one side of a soil sample while measuring the flow rate of water passing through it. Another method is the falling head permeameter, where the water level is allowed to fall while measuring the time it takes for the water to pass through the sample. Both methods provide quantitative data on the permeability of the material being tested.
3. What factors can influence the permeability of soil or rock?
Ans. Several factors can affect the permeability of soil or rock. The grain size and shape of the particles, as well as the arrangement and interconnectivity of the void spaces, play a significant role. For example, soils with well-graded particles tend to have higher permeability compared to those with poorly graded particles. Other factors include the compaction level, presence of fines (such as clay), and the presence of cracks or fractures in rock formations.
4. How does laboratory measurement of permeability differ from field measurements?
Ans. Laboratory measurement of permeability allows for controlled conditions and accurate testing of small soil or rock samples. However, field measurements are often more practical and provide a better representation of the actual permeability of larger soil masses or rock formations. Field tests, such as the pumping test or the slug test, involve measuring the flow of water in situ and can account for the effects of heterogeneity, anisotropy, and the presence of groundwater.
5. What are the limitations of laboratory measurement of permeability?
Ans. Laboratory measurements of permeability have some limitations. Firstly, the size and scale of the sample may not represent the actual conditions in the field accurately. Secondly, laboratory tests usually involve saturated conditions, while in the field, unsaturated conditions may be more common. Additionally, laboratory measurements may not capture the effects of microbiological activity or chemical reactions that can influence permeability in certain soil or rock formations. It is, therefore, important to consider these limitations and complement laboratory tests with field investigations for a comprehensive understanding of permeability.
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