Illustrations of flow nets

3D6 Environmental Engineering II

Dr Gopal Madabhushi

Trench supported by sheet piles

Impermeable clay

Uniform sand

5m

6m

6m

6m

Trench supported by sheet piles

Impermeable clay

Uniform sand

5m

6m

6m

6m

Trench supported by sheet piles

Impermeable clay

5m

6m

6m

6m

h=6mNh=10Nf=2.5+2.5

Uniform sand

Excavation supported by a sheet pile

Shale

Uniform sand

Water pumped away

Steel sheet

Excavation supported by a sheet pile

Shale

Uniform sand

Water pumped away

Steel sheet

Reduced sheet penetration; possible liquefaction v = 0

Shale

Uniform sand

Steel sheet

Reduced sheet penetration; possible liquefaction v = 0

Uniform sand

Reservoir Tail water

Shale

Concrete dam or weir

Reservoir Tail water

Shale

Uniform sand

Concrete dam with cut-off; reduces uplift pressure

Reservoir

Shale

Uniform sand

Concrete dam with cut-off; reduces uplift pressure

Reservoir

Shale

Uniform sand

Pumped well in confined aquifer

Observation wellpumped wellElevationAquifer heads

H

D aquiferRadial flow

Impermeable stratum

Plan

Pumped well in confined aquifer

Observation wellpumped wellElevationAquifer heads

H

D aquiferRadial flow

Impermeable stratum

Plan

Clay dam, no air entry

Shale

clay

reservoiratmospheric line

drain

Clay dam, no air entry

Shale

clay

atmospheric line

drainreservoir

Clay dam, no air entry

Observation well

Shale

clay

atmospheric line

drainreservoir

Clay dam, no air entry, reduced drain; seepage out of downstream face

Shale

clay

atmospheric lineNot possible

reservoir

Clay dam, with air entry

Shale

clay

reservoir

drain

Clay dam, with air entry

Shale

clay

reservoir

drain

Clay dam, no capillary, reduced drain; seepage out of downstream face

Shale

clay

reservoir

Clay dam, no capillary, reduced drain; seepage out of downstream face

Shale

clay

reservoir

Flow of water in earth dams

The drain in a rolled clay dam will be made of gravel, which has an effectively infinite hydraulic conductivity compared to that of the clay, so far a finite quantity of flow in the drain and a finite area of drain the hydraulic gradient is effectively zero, i.e. the drain is an equipotential

The phreatic surface connects points at which the pressure head is zero. Above the phreatic surface the soil is in suction, so we can see how much capillarity is needed for the material to be saturated. If there is insufficient capillarity, we might discard the solution and try again. Alternatively: assume there is zero capillarity, the top water boundary is now atmospheric so along it and the flow net has to be adjusted within an unknown top boundary as the phreatic surface is a flow line if there is no capillarity.

Flow of water in earth dams

yh

If then in the flow net, so once we have the phreatic surface we can put on the starting points of the equipotentials on the phreatic surface directly

Flow of water in earth dams

yh consyh

Unsteady flow effects

Consolidation of matrixChange in pressure head within the soil due to

changes in the boundary water levels may cause soil to deform, especially in compressible clays. The soil may undergo consolidation, a process in which the voids ratio changes over time at a rate determined by the pressure variation and the hydraulic conductivity, which may in turn depend on the voids ratio.

Liquefaction (tensile failure)The total stress normal to a plane in the soil can be separated

into two components, the pore pressure p and the effective inter-granular stress ’:

By convention in soils compressive stresses are +ve.Tensile failure occurs when the effective stress is less than the

fracture strength ’fracture, and by definition for soil ’fracture=0. When the effective stress falls to zero the soil particles are no longer in contact with each other and the soil acts like a heavy liquid. This phenomenon is called liquefaction, and is responsible to quick sands.

Breakdown of rigid matrix

p

Uniform soil of unitweight

Upward flow of water

Large upward hydraulic gradients:

Uniform soil of unitweight

Upward flow of water

Plug of Base areaA

Water table and datum

standpipe

Gap opening as plug rises

Critical head Pressure hcrit

Critical potentialHead zhh critcrit

z

At the base of the rising plug, if there is no side friction:

wcrit

v

hp

z

.

.

So if v=0 then v = p and :

wcritwcrit zhhz ...

w

wcritcrit z

hi

, icrit=0.8~1.0

where icrit is the critical hydraulic gradient for the quick sandCondition. As 18~20 kN/m3 for many soils (especially sandsand silts) and w 10 kN/m3 :

0.110

1020

z

hi critcrit

Frictional (shear failure)

Sliding failure of a gravity concrete dam due to insufficient friction along the base:

Uniform sand

Reservoir Tail waterWH1H2

W´ dspU .

Limiting condition on shear force T is:

maxmax tan. WT

where tan’max is the co-efficient of friction, so considering the base of the dam we are looking for:

21max HHF

where W‘ = W-U is the effective weight of the dam, U is thetotal uplift due to the pore pressure distribution p along the baseof the dam, and F = H1- H2 is the shear force along the Dam base