-
Geosynthetics and yReinforced Soil Structures
Geosynthetic Reinforced Pile Platforms
Dr. K. Rajagopalf f CProfessor of Civil Engineering
IIT Madras, Chennai, Indiae-mail: [email protected]
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Construction on Soft Foundation SoilProblems
(a) Slope instability (b) Unacceptable vertical settlements
(From Lawson,2012)(From Lawson,2012)
2(c) Localised differential settlements at
embankment surface(d) Difficulty to move the construction
equipment( Concept- Lawson,2012)
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Methods of Ground Improvement
Soil Replacement Preloading Preloading Light Weight Fill
Preloading ith Vertical Drain Preloading with Vertical Drain
Vacuum Preloading Stone Column-OSC,ESC Piled Raft Basal
Reinforcement Piled Embankment Geosynthetic Reinforced Pile
Supported
Embankment3
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Geosynthetic Reinforced yPiled Embankments
Rail/Road embankmentRail/Road embankment
Soft clay
Pil I li dPiles Inclined Piles
Firm stratum
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Advantages of Geosynthetic Reinforced Piled g yEmbankments
Faster construction-Loading rate not dependent on the rate of
consolidation of soil
Eliminates differential settlements especially for large height
embankments
Slope stability
Relatively small pile caps and no need for raking piles
Low long term maintenance costs
5
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Embankment Piling
CFA (Continuous Flight Auger) piles
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Load Transfer Platform at Second Severn Crossing13
Load Transfer Platform at Second Severn Crossing(Tensar, UK
brochure)
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Measured data fromMeasured data from Second Severn, UK(Tensar,
UK brochures)
14
( )
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Application areas
Bridge abutment approach roads (Buchanan
1984)(Buchanan,1984)
Airport runways (Hossain and Rao, 2005) Subgrade improvement
(Han, 1975) Minimize differential settlements under storage
tanks (Alzamora et al. 2000) Segmental retaining wall (Alzamora
et al. 2000) Widening of the existing roadway embankment
(Han and Gabr 2002) To construct confined embankment
structures
(Lawson 2012)
15
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Construction Sequence Installing piles with certain grid
formation in the soft soil up to
a certain depth.
Geosynthetic material is laid on top of a thin layer (0.1 m) ofl
t i lgranular material.
After placing the geosyntheticp g g ylayer, the embankment fill
isconstructed to the requiredheight in stages.
Fi ll th t ti h Finally the construction such asrailway or road
pavement isbuilt on top of the embankment
16
built on top of the embankment Geosynthetic Reinforced Piled
Embankment System
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Plan Layout of the Piles
L t ( ) S d (b) T i l(a) (b)
Layout (a) Square and (b) Triangular
Geosynthetic Layout
(a) (b)
17Optimal geosynthetic layout (a) direction of placing the
layers and (b) direction of load
(Lawson,2012)
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Load Transfer Mechanism
(b) Membrane action of geosynthetic(a) Soil Arching (b) Membrane
action of geosynthetic(Russell and Pierpoint,1997)
(a) Soil Arching
( ) C t ti f t d th il d t th(c) Concentration of stresses
around the pile due to thestiffness difference between the soft
foundation soil and the rigid pile
18
soil and the rigid pile
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Design Methods
(a) British Standard-BS8006:1995
This is the most widely used method and is very conservative
This is the most widely used method and is very conservative.
Based on Marstons (1913) formula for positive projectingased o a
s o s ( 9 3) o u a o pos ve p ojec gconduits, Jones et al.(1990)
developed an empirical relationshipfor the ratio of average
vertical stress acting on the pile caps tothe average vertical
stress acting across the base of theembankment .
where c c vv
p C a HH
pc=Arched vertical stress on top of the pilev=Average vertical
stress on top of the pile
19
Cc= Arching Coefficient (Marston 1913)a = size of pile caps
Positive Projecting Conduit (Marston,1913)
-
BS8006 adopted Jones et al.(1990) for the design of piled b k
tembankments.
BS8006 gives empirical equations for arching coefficient as
follows
cCas follows
cEnd bearing piles,C 1.95 0.18Ha
cFriction piles,C 1.5 0.07
aHa
a
BS8006 considers two cases
1. Embankment height is below thecritical height of
1.4(s-a):
Arching is not fullydeveloped
Partial arching
20
Partial archingHere A= Load acting on the piles due to arching,
B= Load taken by the geosynthetic andC= Load acting on the soft
subsoil
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For 0.7 1.4 ,s a H s a
2 22 2Load on the geosynthetic,
fs q s cT
v
s f H f w pW s as a
1Geosynthetic Tension T 1
v
TW s a
rGeosynthetic Tension, T 1 2 6where is the geosynthetic
strain
f are the partial fact
a
f
ors used in the designfs f , are the partial factqf ors used in
the design
b k h i h i b2. Embankment height is abovethe critical height of
1.4(s-a):
Full arching is developed
21 Full arching
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Height of embankment above arching height plays no Height of
embankment above arching height plays norole in the tension
developed on the geosynthetic.
Same is the case with surcharge For H>1 4 s a
For H>1.4 ,
1 4
s a
sf s a
2 22 2
1.4 fs cT
v
sf s a pW s as a
r
1Geosynthetic Tension, T 12 6
TW s a 2 6a
22
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Horizontal force at the slope
,,
Horizontal force at the embankment slope after
BS8006(Satibi,2009)
Geosynthetic tensile load needed to resist the horizontal f f th
b k t i T
0.5 ( 2 )
hrs a fs qT K f H f q H
force of the embankment is Trs
a
where K Active lateral earth pressure coefficient
, = partial factors used in the designfs qf f
23
, p gfs qf f
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(b) Hewlett and Randolph Method(1988)
This theory is based on limit state of soil inhemispherical
domed region over piles.p g p
The stability of arch at the crown and at the pile top ofh h i h
i l d d d i h ithe hemispherical dome formed defines the entire
stability.
24Hemispherical domes (Hewlett & Randolph, 1997)
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Stress Reduction Ratio ( S3D ) defined as the ratio of the
Stress Reduction Ratio ( S3D ) defined as the ratio of theaverage
vertical stress acting on the reinforcement tothe overburden
pressure due to the embankment fill was
1
used to check the stability.
3 1 22
1 at the crown of the arch2
1 1 1 11
pD k
pp
Sk a a a ak
k
2 1k 21 ppk s s s s
2 1
3
2 1 2 1 at the pile top 1 1
2 2 3 2 2 3
pkp p
Dp p
s k s a kaSs H k H k
- Largest value is the critical S3D
25
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(c) The new German Method (EBGEO 2004)
In the old German approach the arching modeldeveloped by Hewlett
and Randolph (1988) was used tocalculate the stresses generated due
to arching.
EBGEO 2004 adopts the m lti shell arching theor EBGEO 2004
adopts the multi-shell arching theorybased on the work of Zaeske
(2001).
26Multi shell arching theory adopted in New German Method
(Kempfert,2004)
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3-dimensional soil element is considered and theequilibrium of
forces about the radial direction is usedto calculate the vertical
stress coming onto the soil,zo k
2 22 2, 1 1 2 1 1 24gzo k g g ghp h h h hh
, 4g g gh
where
2 222 1 212
where1 1 2 ( ), K=tan 45 , ,
2 8 8crit ka K s a s as a
s
In the second step the vertical stress acting on the top of,zo
k
p g pthe subsoil is used to calculate the vertical load Fk onthe
geosynthetic.
27
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Load distribution on the geosynthetic for rectangular pile
layout (Kempfert,2004)
2 x,k ,1 , F2 2 180yLx x y Lx zo kxsaA s s atn As
2 y,k ,1 , F2 2 180xLy x y Ly zo ky
saA s s atn As
28
y
-
The maximum strain k is obtained from thedimensionless design
graphs (EBGEO 2004)
kJwLErsb
dimensionless design graphs (EBGEO, 2004).
Here,J t il tiff f thJk= tensile stiffness of the
geosynthetic (kN/m)Lw= (s-a)= pile clear spacingbErs= width of
support
29(EBGEO,2004)
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Horizontal force at the slope
The additional horizontal force in the reinforcement The
additional horizontal force in the reinforcementbeneath the
embankment slope is given by
1E E h k P h k ,ah
2where K Active earth pressure coefficient
k ah k k k ahE E h k P h z k
30
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(d) The Dutch Method (CUR 226)
Introduced in 2009.
Adopts major parts of the German EBGEO 2004.
Flat terrain-thin embankments are constructed andtherefore the
EBGEO method was modified to suit thetherefore the EBGEO method was
modified to suit therequirements. (Eekelen et al.2010)
Main difference from EBGEO-Different set of load-and-resistance
factors were adopted in the DutchG id liGuideline.
31
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(e) Guido Method
Guido et al. (1987) observed that the inclusion of stiffbiaxial
geogrid within a granular fill improved thebearing capacity of the
foundation soilbearing capacity of the foundation soil.
Concluded that the angle of load spread through a Concluded that
the angle of load spread through agranular fill reinforced with
geogrid would be at anangle of 45 degrees.
The approach is mainly for asingle layer of geosynthetic atthe
base of the embankmentfill.
3Stress Reduction Ratio= D
s aS
32
3Stress Reduction Ratio 3 2DS
H
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(f) The Swedish Method
Carlsson (1987) considered a wedge of soil with aninternal angle
at the apex of the wedge equal to 30.g p g q
Valid in two-dimensional model.
Carlsson adopted a critical height of 1.87(s-a).
Miriam and George (2003) presented the expression for p pS3D for
this model as per Hewlett & Randolph (1997)
32
6 tan15Ds a s a
SH
33
6 tan15s a HTwo dimensional model by Carlsson,1987
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Rogbeck et al. (1998) modified this model into a 3D form which
is an inverted truncated pyramid
h di i l d l b b k l 1998
Modified form of this 3D arching model was adopted by
Three dimensional model by Rogbeck et al. ,1998(Lawson,2012)g p
y
Nordic authorities (Svan et al.2000).
I N di d i th hi l id d t i l d34
In Nordic design the arching angle was widened to includean
angle of arching between 68-75.
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A i i U i C ll (R ll d Pi i 1997 H
Numerical Analyses-Different approaches Axisymmetric Unit Cell
(Russell and Pierpoint 1997, Han
and Gabr 2002, Yoo and Kim 2009)
3D Column (Yoo and Kim 2009, Jenck et al. 2009)
Full three dimensional analyses (Huang et al.2005,Liu
etal.2007)
3DColumnPile
Full Embankment
35 Axisymmetric unit cell
-
Major Numerical Work-3D Column Russell and Pierpoint (1997)
carried out a numerical study using Russell and Pierpoint (1997)
carried out a numerical study using
FLAC3D to compare the different analytical methods.-Terzaghi
(1943), Hewlett and Randolph (1988) and BS 8006g ( ), p ( )
Two cases were considered-The A13 piled embankment(heavily
reinforced) and the Second Severn Crossingembankment (minimal
reinforcement).
Design methods predicted differently for different
embankmentgeometriesgeometries
Tension force calculated by different design methods Design
Methods A13 Embankment
(Reinforcement Tension,
kN/ )
Second Crossing
(Reinforcement Tension,
kN/ )kN/m) kN/m)
BS8006 73 491
Ter aghi 104 297
36
Terzaghi 104 297
Hewlett & Randolph 104 280
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Han and Gabr (2002)Major Numerical Work-Axisymmetric unit
cell
Han and Gabr (2002)investigated the influenceof the tensile
stiffness ofthe geosynthetic, the heightof the fill, and the
elasticmodulus of the pilematerial.
One layer of geosyntheticwas used and a full bondwas assumed
between thegeosynthetic and the soil.
Major findings are givenbelow
Pile Layout and the axisymmetric model considered for the
analysis (Han and Gabr,2002)
37
below.
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(a) (b)Effect of (a) pile modulus and (b) geosynthetic stiffness
on the maximum settlements
(Han and Gabr,2002)
The influence of geosynthetic tensile stiffness becomes
lessimportant when the stiffness exceeds 4,000 kN/m.
( , )
For a pile of elastic modulus of 30,000 MPa, the maximumttl t f
th i f d d d b 20% f
38
settlement for the reinforced case was reduced by 20% fromthat
for the unreinforced case.
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(a) (b)Effect of geosynthetic (a) Stress Concentration Ratio(b)
Tensile force distribution
(Han and Gabr,2002)
(a) (b)
The inclusion of geosynthetic reinforcement enhances thestress
transfer from the soil to the piles.
Tension is not uniform along the geosynthetic and themaximum
tension occurs at the edge of the pile.
39
maximum tension occurs at the edge of the pile.
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Major Numerical Work-Full three dimensional
Geogrid Reinforced Pile supported highway embankment Geogrid
Reinforced Pile supported highway embankmentlocated in Shanghai
China-Liu et al. (2007)
Case history back analyzed by 3D fully coupled finite-element
analysis.
Instrumented cross section of the embankment40
Instrumented cross section of the embankment (Liu et
al.,2007)
-
Full three dimensional model developed (Li l 2007)(Liu et
al.,2007)
Significant load transfer from the soil to the piles due to
soilg parching-contact pressure acting on the pile was 14
timeshigher than that acting on the soil located between the
piles.
Lateral displacements considerably reduced- stability of
theembankment increased significantly
41
embankment increased significantly.
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Design of Geosynthetic Reinforced Piled Embankment - Example
Pulverized fly ash filled embankment
9 m = 14kN/m3Pile caps (1.1 m square)( q )
Soft clay(Without piles
settlement = 700 mm)
4 m
)
Embankment Details
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Reinforcement detailsReinforcement details
Low creep reinforcement Tensile safety factor = 3.0 Peak
extension at failure = 12%
Geotextiles Longitudinal Strength (kN/m)Transverse
Strength (kN/m)g ( ) g ( )
A 1000 50A 1000 50
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Circular arc Deformation analysis
Aa = 4-1.1 = 2.9 m
A
2Geosynthetic
RG
Assuming
b = 0.2 0.7= 0.14 m
TT
b 0.2 0.7 0.14 m
From the geometryb TTTT
212
b tana
a11 03
2
.
a R sin
2
7 58
G
G
a R sin
R . m
12T
R bGWeight of the fill , W 52 08W . kN mT
-
Considering the reaction force asg
0 15 18.9 kN mBW . h
The tension in the geosynthetic,
251.5 kN/mConsider a single layer of geosynthetic (Optimal)
T G T BT R W W Consider a single layer of geosynthetic
(Optimal),
total strength = 1050 kN/m
The strain in the ge G 251 5otextile, 12 2 871050. % . %
GFrom the geometry 90 0 6GR a . %
-
As G < the predictedG p
Try with b = 0.19 m
14 93 = 14.93 RG = 5.63 m WT = 38.08 kN/m TT = 108 kN/mT
For this the strain G, from the load deformation data =
1.23%
F h 1 2%From the geometry, G = 1.2%
As these two are compatible the tension in the geosynthetic TT =
108 kN/m. G = 1.2 %G
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Catenary Deformation analysis
From the Equation of the catenary, the tension in the
geosynthetic is given byg y g y
21 1 aT WT WB
2
2 2
1 1 162
1 16 4 161 1 1
TaT WT WB a b
b a b bl
2 21 16 4 161 1 182G eb a b blogb aa a 1 69Loading coefficient 0
12c
c
. hC .B c
-
1D Arching: Pressure ratio = C B /h1D Arching: Pressure ratio =
Cc Bc/h
2D Arching: Pressure ratio = (Cc B /h)22D Arching: Pressure
ratio = (Cc Bc/h)2
-
Loading Coefficient,1 69 0 12 13.71c
c
. hC .B Pressure ratio (1D) = CcBc/h = 1.676Pressure ratio (2D)
= (1.676)2 = 2.809In any 4 square piles,
o Pile area = 1.21 m2T l 16 2o Total area = 16 m2
o Soil area = 14.79 m2
Total load = 16149 = 2016 kN Total load = 16149 = 2016 kN Load
on the pile = 1.211492.809 = 428 kN Load on soil = 2016 428 = 1588
kN = 107 4 kN/m2 Load on soil = 2016-428 = 1588 kN = 107.4
kN/m2
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W 107 4 kN/WT = 107.4 kN/mWB = 0.15 h = 18.9 kN/mAs per the
equations shown earlier
T = 309 8 kN/mTT = 309.8 kN/m
From load-extension data G = (309.8/1050)12 = 3.5 %Using the
equation for 1+G as shown earlier, G = 3.4 %
As the two values are in close agreement further iteration is
notAs the two values are in close agreement further iteration is
not necessary.
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BS 8006-1995 Method
According to BS8006, the minimum height of embankmentrequired is
0.7 (s-a) and for full arching to develop the height of
theembankment should be greater than 1.4 (s-a)
In the present case, 0.7(4 1.1) = 2.03 m < 9 m
and1.4(4-1.1)=4.06 m < 9 m- Full arching develops in this
case
The Arching coefficient (considering end bearing pile).1 95 0
18. HCc .a
The vertical stress on the pile cap = 15.77
2 215 77 1 1C a 215 77 1 114 9 468 1 kN/m9c
c vC a . .p .H
-
For H > 1.4(s-a), The distributed load carried by the
geosynthetic reinforcement
1 4s s a 2 22 2
1 4
176 85 kN/
cT
v
. s s a pW s as a
(Serviceability condition, partial factors in the equations are
given a value of 1) = 176.85 kN/m
Tension in the reinforcement (BS8006-Design strain is 5%) 11 486
2 kN/mTW s aT
Tension due to lateral thrust,
1 486.2 kN/m2 6rT a 0 5 170 1 kN/mLT . Ka H .
Total tension = 656.3 kN/m
7 /L
-
Results of Design
By Circular arc methodTT = 108 kN/m; G = 1.2 %; WT = 38.08 kN/mT
; G ; T
By Catenary deformation methody yTT = 310 kN/m; G = 3.4 %; WT =
107.4 kN/m
By BS 8006 1995 methodTT = 656.3 kN/m; G = 5 %; WT = 176.85
kN/mT 656.3 N/ ; G 5 %; WT 76.85 N/
-
54
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References1. Alzamora, D., M. H. Wayne and J. Han (2000)
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other fills. Section 8.3.3 British Standard Institution.
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THANK YOU !THANK YOU !
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