Download Lecture 2 Why Landslides occur

Landslide Hazards
Types of Landslide
Why Landslides occur
N.K. Tovey
Н.К.Тови
Landslide just west of Maracas Beach, Trinidad December 2002
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Man’s Influence (Agriculture /Development)
Pumping
Drainage
Hydrology (rainfall)
Earthquakes
Ground
Water
Ground Loading
Surface
Water
Material Properties
Landslide
Preventive
Measures
Design
Construction
GIS
Geology
(Shear Strength)
Erosion/Deposition
Glaciation
Weathering
Geochemistry
Stability Assessment
Slope Profile
(Consolidation)
Slope Management
Landslide Warning
Landslide
Cost
Build
Cut / Fill Slopes
No Danger
Safe at the moment
Temporarily Safe
Consequence
Remedial
Measures
Remove
Consequence
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Landslides: Types of Landslide
•
•
•
•
•
Cut Slopes
Fill Slopes
Retaining Walls
Hybrids: Cut/Retaining Wall / Fill/Retaining Wall
“Natural” Slopes - is there a better word?
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Landslides: Types of Slope
• Cut Slopes
• Fill Slopes
• Retaining Walls
Cut Slope
“Natural” Slope
Fill Slope
Retaining Wall
•
•
Hybrids: Cut/Retaining Wall
/ Fill/Retaining Wall
“Natural” Slopes - is there a
better word?
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Cut Slopes and Fill Slopes
Cut Slope
“Natural” Slope
Fill Slope
Retaining Wall
Failure of “Natural Slope” – cut slope and retaining wall unaffected
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Is there such a thing as a “Natural Slope?”
Landslides
triggered by
anthropogenic
activity
•?
Deep seated
landslide unaffected
by anthropogenic
activity
slopes where there has been no anthropogenic activity, or
where there is such activity it causes small changes to the
geometry of the slope so that the Factor of Safety is
largely unaffected.
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Relationship between mobilizing & resisting forces
Shear
Force
SS321
N1
N2
N3
Normal Force
S

Force (S) required to move block
is proportional to Normal Force (N)
On a slope

W
W
W
N =W
N depends on weight and 
N =
W cos 
S also depends on weight and 
N = W sin 
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Properties of Soils
Coulomb: a French Military Engineer
Problem: Why do Military Fortifications Fail?
Is there a relationship between F and N?
N
F
F
F = N tan 
......4.3
 is the angle of internal friction

N
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Properties of Soils
Suppose there is some “glue” between block and surface
Initially - block will not fail until bond is broken
N
F
Block will
fail
F

F = C + N tan 
C is the cohesion
......4.4
Block is
stable
C
N
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Properties of Soils
F = C + N tan 
above equation is specified in forces
In terms of stress:
 = c +  tan 
• Three types of material
– granular (frictional) materials - i.e. c = 0 (sands)
•  =  tan 
– cohesive materials - i.e.  = 0 (wet clays)
• = c
– materials with both cohesion and friction
•  = c +  tan 
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Properties of Soils
• Stress Point at B
- stable
• Stress Point at A
- stable only if
cohesion is present
• if failure line changes,
then failure may occur.
F
A
B
N
Implication: Vertical slopes stable only to a height of
Where  is unit weight = ρg
2c/
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Properties of Soils – Effects of Packing and Water
Loose: grains can slip over
each other easily
Dense: grains have to rise up to slip
over each other.
Sample must EXPAND
Water filling voids forces
grains apart +pwp
Water partly filling voids
causes suction - pwp
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Properties of Soils
N
N
N
N
N
N
N
N
F

dense
loose
N
Displacement
Peak in dense test is reached at around 1 - 3% strain
What happens if residual strength is used compared to peak strength?
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Properties of Soils

dense
loose
At critical
voids ratio
volume
loose
dense
Displacement
Change in
volume
Displacement
Displacement
Dense / overconsolidated soils
expand on shearing
Loose / normally consolidated
soils contract on shearing
Eventually a common void
ratio and shear strength
What Shear Strength should be used?
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Properties of Soils – Effects of water
•
Distance stress point is
from failure line is a
measure of stability.
•

C
+ve pwp
•
Greater distance
> greater stability
Fs =
CA / BA
-ve pwp moves
stress point to right
B
Moves point closer
to failure line
Moves point further
from failure line
 less stability
 greater stability

A
 = c + ( - u) tan 
Slopes near Hadleigh, Essex are only stable because of -ve pwp
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Properties of Soils – Effects of previous history
Sedimentation / glaciation/
anthropogenic loading
e
Consolidation and Rebound
volume of voids
Void ratio (e) =
Erosion /
unloading
Dense / heavily
overconsolidated
loose / lightly
overconsolidated
log 
What happens if slope movement
does not allow volume change?
If dense, sample tries to expand
> - ve pwp >>>> more stable
If loose, sample tries to contract
> +ve pwp >>>> less stable
Water
sucked in
e
volume of solids
Water
squeezed
out
Critical
State Line
log 
+ve pwp
-ve pwp
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Types of Slope Failure
Water table
Infinite Slope
Failure
Surface
Extensive Slope of nearly constant angle
W
•
•
•
•
Many slopes approximate to this
Strata are parallel to surface
Failure Surface is parallel to surface
Water Table is parallel to surface
Analysis is relatively straight forward assuming a
block sliding and relevant properties.
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Types of Slope Failure: Finite Slopes
W

Fs

•
•
•
•
Straight Line failure
Only applicable for slopes ABOVE water table
Postulate failure mechanism
Need to test for minimum factor of safety.
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Types of Slope Failure – problem of cracks
W

•
•
•
•
Cracking at surface at crest
Reduces length of shear resistance
Allows water to fill crack and cause destabilising pressure
In dry summers keep crest damp to prevent crack formation!!!
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Types of Slope Failure
• Backward tilting surface at
crest of failure ~ 10o.
• Summer water table
• Winter Water Table
• Slope failure
• Toe failure
• Deep seated Base failure
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Types of Slope Failure
• If water is under pressure then debris from landslide becomes
fluid. Controlled disaster becomes a major disaster - Aberfan
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Types of Slope Failure: Progressive Failure

dense
Displacement
• Bulging must occur before failure takes places
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Types of Slope Failure: Method of Analysis
• Divide up slope into slices and
sum up the stability of all slices.
• Detailed analysis allows for
estimating inter-slice forces
• Can be ignored as first
approximation as these are
conservation assumptions
• Leads to lower Fs than actual
S
W
N
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Slope Failure: Remedial Action
• Create berms with longitudinal drains to
remove surface water
• Reprofile Slope –
remove material at
middle – top
• Add weight to toe
• Lower water table
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Types of Slope Failure
• Analysis of safety involves
– Soil Sampling
– Field Surveying
– Location of Water Table
– Laboratory Testing of samples
– Analysis of stability
– Some parts of analysis are conservative – Other parts over estimate factor of safety and
may give false sense of security
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strength
Appraising Test Data
1
2
3
4
5
Test No.
• Several tests on soil samples from a slope
• What value should be used in analysis
Errors in Interpretation of Field Data
• Two Boreholes
• Both hit solid rock
• Fs ~1.4
• Slope Failed
• Inappropriate Failure mechanism
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