7 compressibilty of soils
KhalidAljanabi
9,124 views
68 slides
Mar 20, 2015
Slide 1 of 68
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
About This Presentation
compressibility of soils
Slide Content
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
290
Compressibilty of Soils
ûH
Deformation of soil grains
Expulsion of water
Relocation of soil particles
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
290
Compressibilty of Soils
ûH
Deformation of soil grains
Expulsion of water
Relocation of soil particles
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
291
Topics
” Introduction
” Immediate Settlement
” Consolidation Settlement (Primary Consolidation)
” Secondary Compression (Secondary consolidation)
Settlement
” Time Rate of Consolidation
” Methods for Accelerating Consolidation Settlement
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
291
Topics
” Introduction
” Immediate Settlement
” Consolidation Settlement (Primary Consolidation)
” Secondary Compression (Secondary consolidation)
Settlement
” Time Rate of Consolidation
” Methods for Accelerating Consolidation Settlement
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
160
” Introduction
i Soil deformation may occur by change in:
a) Stress
b) Water content
c) Soil mass
d) Temperature
i The compression is caused by
a) Deformation of soil particles
b) Relocation of soil particles
c) Expulsion of water or air from the voids
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
160
” Introduction
i Soil deformation may occur by change in:
a) Stress
b) Water content
c) Soil mass
d) Temperature
i The compression is caused by
a) Deformation of soil particles
b) Relocation of soil particles
c) Expulsion of water or air from the voids
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
161
i Types of settlement:
a) Immediate (Elastic) Settlement /e
b) Consolidation Settlement (primary consolidation) /c
c) Secondary Compression (Consolidation) Settlement /s
Thus, the total settlement will be sceT
GGGG
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
161
i Types of settlement:
a) Immediate (Elastic) Settlement /e
b) Consolidation Settlement (primary consolidation) /c
c) Secondary Compression (Consolidation) Settlement /s
Thus, the total settlement will be sceT
GGGG
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
162
” Immediate (Elastic) Settlement
i Due elastic deformation of soil grains without any change in
moisture content
i It is usually small and occurs directly after the application of a
load.
i The magnitude of the contact settlement will depend on the
flexibility of the foundation and the type of material on which
it is resting, these distributions are true if E is constant with
depth.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
162
” Immediate (Elastic) Settlement
i Due elastic deformation of soil grains without any change in
moisture content
i It is usually small and occurs directly after the application of a
load.
i The magnitude of the contact settlement will depend on the
flexibility of the foundation and the type of material on which
it is resting, these distributions are true if E is constant with
depth.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
163
i all the previous relationship discussed in previous chapter
were based on the following assumptions:-
a) The load is applied at the ground surface
Flexible
Rigid
Sand Clay
Contact pressure
distribution
Contact pressure
distribution
Contact pressure
distribution
Contact pressure
distribution
Settlement profile
Settlement profile
Settlement profile
Settlement profile
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
163
i all the previous relationship discussed in previous chapter
were based on the following assumptions:-
a) The load is applied at the ground surface
Flexible
Rigid
Sand Clay
Contact pressure
distribution
Contact pressure
distribution
Contact pressure
distribution
Contact pressure
distribution
Settlement profile
Settlement profile
Settlement profile
Settlement profile
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
164
b) The loaded area is flexible.
c) The soil medium is homogenous, elastic, isotropic,
and extends to a great depth.
x Relations for Immediate Settlement Calculation
p
s
s
e I
E
B
2
1
P
VG
'
Schleicher (1926)
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
164
b) The loaded area is flexible.
c) The soil medium is homogenous, elastic, isotropic,
and extends to a great depth.
x Relations for Immediate Settlement Calculation
p
s
s
e I
E
B
2
1
P
VG
'
Schleicher (1926)
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
165
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
165
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
166
x Improved Relationship for Immediate Settlement
Mayne and Polous (1999) present an improved relationship for
calculating /e taking into account –
- rigidity of the foundation
- depth of embedment of the foundation
- the increase in modulus of elasticity E with depth
- the location of rigid layers at limited depth
EFG
o
s
ee III
E
B
2
1
P
VG
'
S
BL
B
e
4
for rectangular footing
DiameterB
e for circular footing
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
166
x Improved Relationship for Immediate Settlement
Mayne and Polous (1999) present an improved relationship for
calculating /e taking into account –
- rigidity of the foundation
- depth of embedment of the foundation
- the increase in modulus of elasticity E with depth
- the location of rigid layers at limited depth
EFG
o
s
ee III
E
B
2
1
P
VG
'
S
BL
B
e
4
for rectangular footing
DiameterB
e for circular footing
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
167
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
167
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
168
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
168
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
169
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
169
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
170
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
170
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
171
” Consolidation Settlement (Primary Consolidation)
x Fundamentals of Consolidation
Deformation of saturated soil occurs by reduction of pore
space & the squeezing out of pore water.
The water can only escape through the pores which for fine-
grained soils are very small, while for coarse-grained soils
are large enough for the process to occur immediately after
the application of load.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
171
” Consolidation Settlement (Primary Consolidation)
x Fundamentals of Consolidation
Deformation of saturated soil occurs by reduction of pore
space & the squeezing out of pore water.
The water can only escape through the pores which for fine-
grained soils are very small, while for coarse-grained soils
are large enough for the process to occur immediately after
the application of load.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
172
Skeletal Material
(incompressible)
Pore water
(Incompressible)
Voids
Solid
Voids
Solid
Initial State Deformed State
Water
+
Time
dependent
process
û1
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
172
Skeletal Material
(incompressible)
Pore water
(Incompressible)
Voids
Solid
Voids
Solid
Initial State Deformed State
Water
+
Time
dependent
process
û1
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
173
x Spring model
water
Effective soil skeleton “spring”
Water squeezed
out
ûu û1
P
û1 = P/A
ûu < û1 ûu = 0 ûu = 0
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
173
x Spring model
water
Effective soil skeleton “spring”
Water squeezed
out
ûu û1
P
û1 = P/A
ûu < û1 ûu = 0 ûu = 0
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
174
Total Stress
Time
Time
Excess Pore
Pressure
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
174
Total Stress
Time
Time
Excess Pore
Pressure
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
175
Effective Stress
Time
Settlement
Time
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
175
Effective Stress
Time
Settlement
Time
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
176
Conclusions
x Especially in low permeability soils (silts and clays) settlement is
delayed by the need to squeeze the water out of the soil
x Consolidation is the process of gradual transfer of an applied load
from the pore water to the soil structure as pore water is squeezed
out of the voids.
x The amount of water that escapes depends on the size of the load
and compressibility of the soil.
x The rate at which it escapes depends on the coefficient of
permeability, thickness, and compressibility of the soil.
Consider a clay layer with thickness H subjected to an instantaneous
increase of total stress û1.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
176
Conclusions
x Especially in low permeability soils (silts and clays) settlement is
delayed by the need to squeeze the water out of the soil
x Consolidation is the process of gradual transfer of an applied load
from the pore water to the soil structure as pore water is squeezed
out of the voids.
x The amount of water that escapes depends on the size of the load
and compressibility of the soil.
x The rate at which it escapes depends on the coefficient of
permeability, thickness, and compressibility of the soil.
Consider a clay layer with thickness H subjected to an instantaneous
increase of total stress û1.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
177
Ground water table
Total stress increase Pore water pressure increase Effective stress increase
At time t = 0
At time 0 < t < ’
At time t = ’
û1
û1
û1
ûu = û1 û1
/
= 0 H
Depth
Sand
Sand
û1
ûu = 0 û1
/
= û1
û1
/
> 0 ûu < û1
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
177
Ground water table
Total stress increase Pore water pressure increase Effective stress increase
At time t = 0
At time 0 < t < ’
At time t = ’
û1
û1
û1
ûu = û1 û1
/
= 0 H
Depth
Sand
Sand
û1
ûu = 0 û1
/
= û1
û1
/
> 0 ûu < û1
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
178
x One-Dimensional Laboratory Consolidation Test
It was suggested by Terzaghi.
Consolidometer (Oedometer)
ûpn applied by a lever arm
H
Porous Stone
Porous Stone
Soil Sample
Dia. § 64 mm(2.5 in)
H § 25 mm (1 in)
Metal Ring
Sample
Water
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
178
x One-Dimensional Laboratory Consolidation Test
It was suggested by Terzaghi.
Consolidometer (Oedometer)
ûpn applied by a lever arm
H
Porous Stone
Porous Stone
Soil Sample
Dia. § 64 mm(2.5 in)
H § 25 mm (1 in)
Metal Ring
Sample
Water
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
179
ûp1
ûp2
ûp3
ûpn
H
ûH1
ûH2
ûH3
ûHn
Each load increment is kept
for 24 hrs, after that, the
load is usually doubled
The compression
deformation is
measured by a
micrometer dial
gauge
4h
4hn
Settlement (deformation) vs. time
U% = 100%
Time at
U%=100%
t50%
U% = 0
4H
d50
d100
d0
Stage I-Initial compression
Stage II-Primary consolidation
Stage III-Secondary Compression
Time (log scale)
Soil
Time, min Deformation, mm
o
¼
½
1
2
5
10
20
30
1 hr
2 hr
……..
24 hr
Cv & k are determined from this relationship
” At each time point:
” Record the dial indicator reading
” At the end of each load increment:
” Record the dial reading at completion of primary consolidation for each load (usually 24 hours)
” At the unloading of the specimen:
” Remove load in decrements, recording dial indicator readings
” Conduct a water content test on specimen after unloading is complete
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
179
ûp1
ûp2
ûp3
ûpn
H
ûH1
ûH2
ûH3
ûHn
Each load increment is kept
for 24 hrs, after that, the
load is usually doubled
The compression
deformation is
measured by a
micrometer dial
gauge
4h
4hn
Settlement (deformation) vs. time
U% = 100%
Time at
U%=100%
t50%
U% = 0
4H
d50
d100
d0
Stage I-Initial compression
Stage II-Primary consolidation
Stage III-Secondary Compression
Time (log scale)
Soil
Time, min Deformation, mm
o
¼
½
1
2
5
10
20
30
1 hr
2 hr
……..
24 hr
Cv & k are determined from this relationship
” At each time point:
” Record the dial indicator reading
” At the end of each load increment:
” Record the dial reading at completion of primary consolidation for each load (usually 24 hours)
” At the unloading of the specimen:
” Remove load in decrements, recording dial indicator readings
” Conduct a water content test on specimen after unloading is complete
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
180
x Void Ratio-Pressure (e-log
1. calculate the height of solids, Hs
ws
s
s
AG
W
H
J
Prove it.
2. calculate initial height of voids, Hv
s
HHH
3. calculate initial void ratio, eo
s
v
s
v
v
v
o
H
H
AH
AH
V
V
e
4. for the 1
st
incremental loading, 11 (
A
P
1'
) which causes a
deformation ûH1
sH
H
e
1
1
'
'
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
180
x Void Ratio-Pressure (e-log
1. calculate the height of solids, Hs
ws
s
s
AG
W
H
J
Prove it.
2. calculate initial height of voids, Hv
s
HHH
3. calculate initial void ratio, eo
s
v
s
v
v
v
o
H
H
AH
AH
V
V
e
4. for the 1
st
incremental loading, 11 (
A
P
1'
) which causes a
deformation ûH1
sH
H
e
1
1
'
'
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
181
5. calculate new void ratio after consolidation caused by 11
11
eee
o
'
6. for the next loading, 12 (
A
PP
21''
), which causes additional
deformation ûH2, the void ratio at the end of consolidation is
sH
H
ee
2
12
'
Note:- at the end of consolidation 1 = 1
/
Plot the corresponding e with 1
/
on semi-logarithmic
paper. The typical shape of e-log 1
/
will be as shown in
the figure.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
181
5. calculate new void ratio after consolidation caused by 11
11
eee
o
'
6. for the next loading, 12 (
A
PP
21''
), which causes additional
deformation ûH2, the void ratio at the end of consolidation is
sH
H
ee
2
12
'
Note:- at the end of consolidation 1 = 1
/
Plot the corresponding e with 1
/
on semi-logarithmic
paper. The typical shape of e-log 1
/
will be as shown in
the figure.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
182
Change in void ratio vs. vertical effective stress
Void Ratio
Log 1
/
Cc & Cs are determined from this relationship
Cc = Compression Index
Cs (Cr) = swelling (rebound) Index
Cc
Cs
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
182
Change in void ratio vs. vertical effective stress
Void Ratio
Log 1
/
Cc & Cs are determined from this relationship
Cc = Compression Index
Cs (Cr) = swelling (rebound) Index
Cc
Cs
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
183
x Normally Consolidated and Overconsolidated Clays
O
P
RCO
V
V
c
c
..
Log 1
/
1
/
O 1
/
P
At past
p
V
c= max. preconsolidation pressure
At past
p
V
c= max. preconsolidation pressure
At present
o
V
c= Effective overburden pressure
At present
o
V
c= Effective overburden pressure
Normally Consolidated
Overconsolidate
d
po
VV
c c
po
VV
cc
May be removed due geologic processes or human processes
Relationship is linear and stepper when the effective stresses
is exceeding maximum past preconsolidation pressure
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
183
x Normally Consolidated and Overconsolidated Clays
O
P
RCO
V
V
c
c
..
Log 1
/
1
/
O 1
/
P
At past
p
V
c= max. preconsolidation pressure
At past
p
V
c= max. preconsolidation pressure
At present
o
V
c= Effective overburden pressure
At present
o
V
c= Effective overburden pressure
Normally Consolidated
Overconsolidate
d
po
VV
c c
po
VV
cc
May be removed due geologic processes or human processes
Relationship is linear and stepper when the effective stresses
is exceeding maximum past preconsolidation pressure
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
184
x Effect of Disturbance on Void Ratio-Pressure Relationship
x Usually e-log 1
/
founded by performing consolidation test
on undisturbed sample or remolded sample, does not
reflects the field (virgin) compression curve.
x This difference is attribute to disturbance due to-
ƒ Handling and transferring samples into consolidation
cells.
ƒ Sampling and stress relief
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
184
x Effect of Disturbance on Void Ratio-Pressure Relationship
x Usually e-log 1
/
founded by performing consolidation test
on undisturbed sample or remolded sample, does not
reflects the field (virgin) compression curve.
x This difference is attribute to disturbance due to-
ƒ Handling and transferring samples into consolidation
cells.
ƒ Sampling and stress relief
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
185
0.4eo
0.4eo
Laboratory compression curve
Field (virgin) compression curve, Slope =
Cc
Laboratory rebound curve
Slope = Cs (Cr)
1p
/
=
1o
/
Laboratory compression curve
eo
Field (virgin) compression curve
Slope = Cc
eo
1p
/
1o
/
N.C. CLAY
O.C. CLAY
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
185
0.4eo
0.4eo
Laboratory compression curve
Field (virgin) compression curve, Slope =
Cc
Laboratory rebound curve
Slope = Cs (Cr)
1p
/
=
1o
/
Laboratory compression curve
eo
Field (virgin) compression curve
Slope = Cc
eo
1p
/
1o
/
N.C. CLAY
O.C. CLAY
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
186
x Calculation of Settlement from One-Dimensional Primary
Consolidation
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
186
x Calculation of Settlement from One-Dimensional Primary
Consolidation
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
187
o
c
o
sc
oo
o
s
svvvo
cco
e
e
H
e
AH
eeVAV
e
AH
e
V
V
eVVVVV
AAHHAVVV
'
' ' '
' ' '
'
1
1
11
)(
1
1
G
G
GG
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
187
o
c
o
sc
oo
o
s
svvvo
cco
e
e
H
e
AH
eeVAV
e
AH
e
V
V
eVVVVV
AAHHAVVV
'
' ' '
' ' '
'
1
1
11
)(
1
1
G
G
GG
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
188
N.C. CLAY
O.C. CLAY
)log(
11
)log(]log)[log(
log
o
o
o
c
o
c
o
o
coocc
H
e
C
e
e
H
CCe
e
C
V
VV
G
V
VV
VVV
V
c
c'c
'
c
c'c
cc'c 'Ÿ
c'
'
eo
1p
/
1o
/
1p
/
=
1o
/
1o
/
+ û1
/
eo
ûe
eo
1p
/
1o
/
1o
/
+ û1
/
)log(
11
log(]log)[log(
log
o
o
o
s
o
c
o
o
sooss
H
e
C
e
e
H
CCe
e
C
V
VV
G
V
V
VVV
V
c
c'c
'
c
'c
cc'c 'Ÿ
c'
'
If 1o
/
+ û1
/
d1
/
p
If 1o
/
+ û1
/
d1
/
p
»
»
¼
º
«
«
¬
ª
c
c'c
c
c
'
c
c'c
c
c
cc'ccc '' '
)log()log(
11
)log()log(
]log)[log(]log[log
21
p
o
c
o
p
s
oo
c
p
o
c
o
p
s
pocops
CC
e
H
e
e
H
CC
CCeee
V
VV
V
V
G
V
VV
V
V
VVVVV
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
188
N.C. CLAY
O.C. CLAY
)log(
11
)log(]log)[log(
log
o
o
o
c
o
c
o
o
coocc
H
e
C
e
e
H
CCe
e
C
V
VV
G
V
VV
VVV
V
c
c'c
'
c
c'c
cc'c 'Ÿ
c'
'
eo
1p
/
1o
/
1p
/
=
1o
/
1o
/
+ û1
/
eo
ûe
eo
1p
/
1o
/
1o
/
+ û1
/
)log(
11
log(]log)[log(
log
o
o
o
s
o
c
o
o
sooss
H
e
C
e
e
H
CCe
e
C
V
VV
G
V
V
VVV
V
c
c'c
'
c
'c
cc'c 'Ÿ
c'
'
If 1o
/
+ û1
/
d1
/
p
If 1o
/
+ û1
/
d1
/
p
»
»
¼
º
«
«
¬
ª
c
c'c
c
c
'
c
c'c
c
c
cc'ccc '' '
)log()log(
11
)log()log(
]log)[log(]log[log
21
p
o
c
o
p
s
oo
c
p
o
c
o
p
s
pocops
CC
e
H
e
e
H
CC
CCeee
V
VV
V
V
G
V
VV
V
V
VVVVV
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
189
Compression Index (Cc) and Swell Index (Cs)
Several correlations were suggested for Cc besides other eq.
and in most cases cs CtoC
10
1
5
1
#
Cc = 0.009(LL – 10) undisturbed clays LL= liquid limit
Cc = 0.007(LL – 7) remolded clays LL= liquid limit
=
1o
/
+ û1
/
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
189
Compression Index (Cc) and Swell Index (Cs)
Several correlations were suggested for Cc besides other eq.
and in most cases cs CtoC
10
1
5
1
#
Cc = 0.009(LL – 10) undisturbed clays LL= liquid limit
Cc = 0.007(LL – 7) remolded clays LL= liquid limit
=
1o
/
+ û1
/
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
190
” Secondary Compression (Consolidation) Settlement
”Secondary compression settlement is a form of soil creep that
is largely controlled by the rate at which the skeleton of
compressible soils, particularly clays, silts, and peats, can yield
and compress.
”Secondary compression is often conveniently identified to
follow primary consolidation when excess pore fluid pressure
can no longer be measured; however, both processes may occur
simultaneously.
”Also referred to as the “secular effect”
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
190
” Secondary Compression (Consolidation) Settlement
”Secondary compression settlement is a form of soil creep that
is largely controlled by the rate at which the skeleton of
compressible soils, particularly clays, silts, and peats, can yield
and compress.
”Secondary compression is often conveniently identified to
follow primary consolidation when excess pore fluid pressure
can no longer be measured; however, both processes may occur
simultaneously.
”Also referred to as the “secular effect”
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
191
1
212 log
loglog
t
t
e
tt
e
C
'
'
D
pe
C
C
c
1
D
D
¸
¸
¹
·
¨
¨
©
§
c
1
2
log
t
t
HC
s
D
G
Type of soil
D
Cc
O.C clays 0.001 or less
N.C clays 0.005 to 0.03
Organic soil 0.04 or more
Linear relationship
ûe
t1 t2
ef
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
191
1
212 log
loglog
t
t
e
tt
e
C
'
'
D
pe
C
C
c
1
D
D
¸
¸
¹
·
¨
¨
©
§
c
1
2
log
t
t
HC
s
D
G
Type of soil
D
Cc
O.C clays 0.001 or less
N.C clays 0.005 to 0.03
Organic soil 0.04 or more
Linear relationship
ûe
t1 t2
ef
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
192
” Time Rate of Consolidation
x Terzaghi (1925) proposed the first theory to consider the rate
of one-dimensional consolidation for saturated clay soils.
x Assumptions:-
1. The clay-water system is homogenous.
2. Saturation is complete.
3. Compressibility of water is negligible
4. The flow of water is in one direction only (direction of
compression)
5. Darcy
’
s law is valid
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
192
” Time Rate of Consolidation
x Terzaghi (1925) proposed the first theory to consider the rate
of one-dimensional consolidation for saturated clay soils.
x Assumptions:-
1. The clay-water system is homogenous.
2. Saturation is complete.
3. Compressibility of water is negligible
4. The flow of water is in one direction only (direction of
compression)
5. Darcy
’
s law is valid
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
193
To begin, consider a very small element of soil being subjected
to one-dimensional consolidation in the z-direction.
H=2Hdr
Depth
Sand
Sand
û1
w
u
h
J
vz dxdy
A=dxdy
V=dxdydz
dx
dy
dz
(vz+(˜vz˜z)dz) dxdy
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
193
To begin, consider a very small element of soil being subjected
to one-dimensional consolidation in the z-direction.
H=2Hdr
Depth
Sand
Sand
û1
w
u
h
J
vz dxdy
A=dxdy
V=dxdydz
dx
dy
dz
(vz+(˜vz˜z)dz) dxdy
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
194
Volume of pore fluid which flows out = Volume decrease of the
soil
and thus
Rate at which pore fluid flows out = Rate of volume decrease of
soil
t
V
dxdydz
z
v
t
V
dxdyvdz
z
v
v
z
z
z
z
w
w
w
w
w
w
w
w
])[(
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
194
Volume of pore fluid which flows out = Volume decrease of the
soil
and thus
Rate at which pore fluid flows out = Rate of volume decrease of
soil
t
V
dxdydz
z
v
t
V
dxdyvdz
z
v
v
z
z
z
z
w
w
w
w
w
w
w
w
])[(
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
195
It will also be assumed that Darcy’s law holds and thus that
z
uk
z
h
kkiv
w
z
w
w
Jw
w
w
u
h
J
u = excess pore water pressure caused by the increase
of stress
t
V
dxdydzz
uk
w w
w
w
w
1
2
2
J
During consolidation
t
V
e
t
e
V
t
V
t
eVV
t
V
t
V
s
s
sssv
w
w
w
w
w
w
w
w
w
w
w
w )(
but
0
w
w
t
V
s
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
195
It will also be assumed that Darcy’s law holds and thus that
z
uk
z
h
kkiv
w
z
w
w
Jw
w
w
u
h
J
u = excess pore water pressure caused by the increase
of stress
t
V
dxdydzz
uk
w w
w
w
w
1
2
2
J
During consolidation
t
V
e
t
e
V
t
V
t
eVV
t
V
t
V
s
s
sssv
w
w
w
w
w
w
w
w
w
w
w
w )(
but
0
w
w
t
V
s
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
196
t
e
V
t
V
s
w
w
w
w
but
oo
s
e
dxdydz
e
V
V
11
t
e
e
dxdydz
t
V
o
w
w
w
w
1
t
e
ez
uk
ow
w
w
w
w
1
1
2
2
J But
uaae
vv
w c'w w )(V
av = coefficient of compressibility
t
u
m
t
u
e
a
z
uk
v
o
v
w w
w
w
w
w
w
?
1
2
2
J where
o
v
v
e
a
m
1
mv = coefficient of volume compressibility
û1
/
ûe
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
196
t
e
V
t
V
s
w
w
w
w
but
oo
s
e
dxdydz
e
V
V
11
t
e
e
dxdydz
t
V
o
w
w
w
w
1
t
e
ez
uk
ow
w
w
w
w
1
1
2
2
J But
uaae
vv
w c'w w )(V
av = coefficient of compressibility
t
u
m
t
u
e
a
z
uk
v
o
v
w w
w
w
w
w
w
?
1
2
2
J where
o
v
v
e
a
m
1
mv = coefficient of volume compressibility
û1
/
ûe
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
197
or
2
2
z
u
c
t
u
v
w
w
w
w
where
¸
¸
¹
·
¨
¨
©
§
o
v
w
vw
v
e
a
k
m
k
c
1
J
J
cv = coefficient of consolidation has units L
2
/T
k = coefficient of permeability
This equation is the basic differential equation of Terzaghi
,
s
consolidation theory and can be solved with the following
boundary conditions
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
197
or
2
2
z
u
c
t
u
v
w
w
w
w
where
¸
¸
¹
·
¨
¨
©
§
o
v
w
vw
v
e
a
k
m
k
c
1
J
J
cv = coefficient of consolidation has units L
2
/T
k = coefficient of permeability
This equation is the basic differential equation of Terzaghi
,
s
consolidation theory and can be solved with the following
boundary conditions
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
198
z = 0 u = 0 at a permeable boundary
z = 2Hdr u = 0 at a permeable boundary
t = 0 u = uo= û1 initial excess pore water pressure
The solutions yields
v
TM
m dr
o
e
H
MZ
M
u
u
2
0
)(sin
2
f
¦ »
¼
º
«
¬
ª
Where
)12(
2
mM
S
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
198
z = 0 u = 0 at a permeable boundary
z = 2Hdr u = 0 at a permeable boundary
t = 0 u = uo= û1 initial excess pore water pressure
The solutions yields
v
TM
m dr
o
e
H
MZ
M
u
u
2
0
)(sin
2
f
¦ »
¼
º
«
¬
ª
Where
)12(
2
mM
S
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
199
drH
z
Z
, a depth factor dimensionless number
2
dr
v
v
H
tc
T
, a time factor is a nondimensoinal number
Because consolidation progresses by the dissipation of excess
pore water pressure, the degree of consolidation at distance z at
any time t is
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
199
drH
z
Z
, a depth factor dimensionless number
2
dr
v
v
H
tc
T
, a time factor is a nondimensoinal number
Because consolidation progresses by the dissipation of excess
pore water pressure, the degree of consolidation at distance z at
any time t is
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
200
o
z
o
zo
z
u
u
u
uu
U
1
uz = excess pore pressure at time t
The variation of excess pore pressure within the layer is shown
in Figure below
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
200
o
z
o
zo
z
u
u
u
uu
U
1
uz = excess pore pressure at time t
The variation of excess pore pressure within the layer is shown
in Figure below
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
201
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
201
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
202
The average degree of consolidation for the entire depth of the
clay layer at any time t can be written as
¦
³
f
¸
¸
¹
·
¨
¨
©
§
m
m
TM
o
H
z
dr
c
tc
v
dr
e
Mu
dzu
H
U
0
2
2
0)(
22
1
2
1
1
G
G
U = average degree of consolidation
/c(t) = settlement of the layer at time t
/c = ultimate (final) primary consolidation settlement
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
202
The average degree of consolidation for the entire depth of the
clay layer at any time t can be written as
¦
³
f
¸
¸
¹
·
¨
¨
©
§
m
m
TM
o
H
z
dr
c
tc
v
dr
e
Mu
dzu
H
U
0
2
2
0)(
22
1
2
1
1
G
G
U = average degree of consolidation
/c(t) = settlement of the layer at time t
/c = ultimate (final) primary consolidation settlement
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
203
The U – Tv relationship is represented in the figure below for the
case where uo is uniform for the entire depth of the
consolidating layer.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
203
The U – Tv relationship is represented in the figure below for the
case where uo is uniform for the entire depth of the
consolidating layer.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
204
The values of Tv and their corresponding average U for the case
presented above may also be approximately by the following
relationship:
For U = 0 to 60%
2
100
%
4
¸
¹
·
¨
©
§
U
T
v
S
For U > 60%
%)100log(933.0781.1 UT
v
The following Table gives the variation Tv – U according to the
above equations
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
204
The values of Tv and their corresponding average U for the case
presented above may also be approximately by the following
relationship:
For U = 0 to 60%
2
100
%
4
¸
¹
·
¨
©
§
U
T
v
S
For U > 60%
%)100log(933.0781.1 UT
v
The following Table gives the variation Tv – U according to the
above equations
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
205
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
205
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
206
x Coefficient of Consolidation
¾ Logarithm of Time method
It is particularly useful when there is significant secondary
compression (creep). The do point is located by selected two points
on the curve for which the times (t) are in the ratio 1:4, e.g. 1 min
and 4 min; or 2 min and 8 min.; the vertical intervals DB and BC
will be equal. The d100 point can be located in the final part of the
curve flattens sufficiently (i.e. no secondary compression). When
there is significant secondary compression, d100 may be located at
the intercept of straight line drawn through the middle and final
portions of the curve. Now d50 and log t50 can be located.
The coefficient of consolidation is therefore:
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
206
x Coefficient of Consolidation
¾ Logarithm of Time method
It is particularly useful when there is significant secondary
compression (creep). The do point is located by selected two points
on the curve for which the times (t) are in the ratio 1:4, e.g. 1 min
and 4 min; or 2 min and 8 min.; the vertical intervals DB and BC
will be equal. The d100 point can be located in the final part of the
curve flattens sufficiently (i.e. no secondary compression). When
there is significant secondary compression, d100 may be located at
the intercept of straight line drawn through the middle and final
portions of the curve. Now d50 and log t50 can be located.
The coefficient of consolidation is therefore:
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
207
50
2
2
50
50
197.0
t
H
c
H
tc
T
dr
v
dr
v
Ÿ
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
207
50
2
2
50
50
197.0
t
H
c
H
tc
T
dr
v
dr
v
Ÿ
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
208
¾ Square Root of Time method
After the laboratory results curve has been plotted, line AB is drawn,
followed by line AC in such a way that OBOC 15.1 : AC crosses the
laboratory curve at point D and locates 90
t
The coefficient of consolidation is therefore:
90
2
2
90
90
848.0
t
H
c
H
tc
T
dr
v
dr
v
Ÿ
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
208
¾ Square Root of Time method
After the laboratory results curve has been plotted, line AB is drawn,
followed by line AC in such a way that OBOC 15.1 : AC crosses the
laboratory curve at point D and locates 90
t
The coefficient of consolidation is therefore:
90
2
2
90
90
848.0
t
H
c
H
tc
T
dr
v
dr
v
Ÿ
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
209
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
209
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
210
¾ Hperbola method
It gives good results for U =60% - 90%.
The results are plotted on
H
t
'
- t, then identify the straight portion bc of the
curve and project back to point d, and determine the intercept D, then
determine the slope m of bc
The coefficient of consolidation is therefore: ¸
¸
¹
·
¨
¨
©
§
D
mH
c
dr
v
2
3.0
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
210
¾ Hperbola method
It gives good results for U =60% - 90%.
The results are plotted on
H
t
'
- t, then identify the straight portion bc of the
curve and project back to point d, and determine the intercept D, then
determine the slope m of bc
The coefficient of consolidation is therefore: ¸
¸
¹
·
¨
¨
©
§
D
mH
c
dr
v
2
3.0
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
211
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
211
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
212
¾ Earl Stage log-t method
It gives the highest value while the conventional log-t method gives
the lowest value, this is due to the contribution of the lower part of
the consolidation curve in the conventional log-t method that means
the secondary compression plays a role in the value of cv, while in
this method cv obtained from the early stage log-t method, which
gives more realistic values of the fieldwork.
Follow the same steps in log-t method to locate do, draw a
horizontal line DE through do, then draw tangent through the point
of inflection F, the tangent intersects line DE at point G, determine
the corresponding time t corresponding to G, which is the time at U
= 22.14%, The coefficient of consolidation is therefore:
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
212
¾ Earl Stage log-t method
It gives the highest value while the conventional log-t method gives
the lowest value, this is due to the contribution of the lower part of
the consolidation curve in the conventional log-t method that means
the secondary compression plays a role in the value of cv, while in
this method cv obtained from the early stage log-t method, which
gives more realistic values of the fieldwork.
Follow the same steps in log-t method to locate do, draw a
horizontal line DE through do, then draw tangent through the point
of inflection F, the tangent intersects line DE at point G, determine
the corresponding time t corresponding to G, which is the time at U
= 22.14%, The coefficient of consolidation is therefore:
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
213
14.22
2
0385.0
t
H
c
dr
v
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
213
14.22
2
0385.0
t
H
c
dr
v
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
214
” Calculation of Consolidation Settlement under a Foundation
For limited area foundations (circular, square and rectangular), the
increase of effective stress (û1
/
) decrease with depth as shown in figure
below which can be estimated as described before in previous chapter.
Estimate 1
/
o andû1
/
av at the middle of the clay layer, then use the
previous equations in to determine final consolidation settlement.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
214
” Calculation of Consolidation Settlement under a Foundation
For limited area foundations (circular, square and rectangular), the
increase of effective stress (û1
/
) decrease with depth as shown in figure
below which can be estimated as described before in previous chapter.
Estimate 1
/
o andû1
/
av at the middle of the clay layer, then use the
previous equations in to determine final consolidation settlement.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
215
Using Simpson
’
s rule
6
4
bmt
av
VVV
V
c'c'c'
c'
1
/
o
û1
/
m
û1
/
b
û1
/
t
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
215
Using Simpson
’
s rule
6
4
bmt
av
VVV
V
c'c'c'
c'
1
/
o
û1
/
m
û1
/
b
û1
/
t
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
216
Alternative approach
Simply divide the clay layer to a number of sub layers, and
then estimate /c for each sub layer taking into account effective
overburden pressure and an increase in effective stress at the
middle of each sub layer, then get the summation of
settlements of the sub layers to get the final consolidation of
the clay layer.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
216
Alternative approach
Simply divide the clay layer to a number of sub layers, and
then estimate /c for each sub layer taking into account effective
overburden pressure and an increase in effective stress at the
middle of each sub layer, then get the summation of
settlements of the sub layers to get the final consolidation of
the clay layer.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
217
Rate of consolidation
It is important to determine /c – time relationship, which can
be helpful in estimating the differential settlement between
adjacent footings if the drainage condition at one footing
differs from the other.
c
tc
U
G
G
)(
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
217
Rate of consolidation
It is important to determine /c – time relationship, which can
be helpful in estimating the differential settlement between
adjacent footings if the drainage condition at one footing
differs from the other.
c
tc
U
G
G
)(
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
218
Examples
The following results were obtained from an oedometer test on
a specimen of saturated clay:
Pressure (kN/m
2
) 27 54 107 214 429 214 107 54
Void ratio 1.243 1.217 1.144 1.068 0.994 1.001 1.012 1.024
A layer of this clay 8m thick lies below a 4m depth of sand, the
water table being at the surface. The saturated unit weight for
both soils is 19kN/m
3
. A 4m depth of fill of unit weight 21
kN/m
3
is placed on the sand over an extensive area. Determine
the final settlement due to consolidation of the clay. If the fill
were to be removed some time after the completion of
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
218
Examples
The following results were obtained from an oedometer test on
a specimen of saturated clay:
Pressure (kN/m
2
) 27 54 107 214 429 214 107 54
Void ratio 1.243 1.217 1.144 1.068 0.994 1.001 1.012 1.024
A layer of this clay 8m thick lies below a 4m depth of sand, the
water table being at the surface. The saturated unit weight for
both soils is 19kN/m
3
. A 4m depth of fill of unit weight 21
kN/m
3
is placed on the sand over an extensive area. Determine
the final settlement due to consolidation of the clay. If the fill
were to be removed some time after the completion of
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
219
consolidation, what heave would eventually take place due to
swelling of the clay?
H
e
ee
o
o
c
1
1
G
Appropriate values of e are obtained from e-log1/ drawn from
the result. The clay will be divided into four sub-layers, hence
H =2000 mm.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
219
consolidation, what heave would eventually take place due to
swelling of the clay?
H
e
ee
o
o
c
1
1
G
Appropriate values of e are obtained from e-log1/ drawn from
the result. The clay will be divided into four sub-layers, hence
H =2000 mm.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
220
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
220
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
221
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
221
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
222
Assuming the fill in pervious example is dumped very rapidly,
what would be the value of excess pore water pressure at the
centre of the clay layer after a period of 3 years? Assume Two-
way drainage condition and the value of cv is 2.4m
2
/year.
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
222
Assuming the fill in pervious example is dumped very rapidly,
what would be the value of excess pore water pressure at the
centre of the clay layer after a period of 3 years? Assume Two-
way drainage condition and the value of cv is 2.4m
2
/year.
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
223
2
/2.35
58.0
84
1
mkNu
u
u
uu
U
z
z
o
zo
z
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
223
2
/2.35
58.0
84
1
mkNu
u
u
uu
U
z
z
o
zo
z
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
224
In an oedometer test a specimen of saturated clay 19mm thick
reaches 50% consolidation in 20 min. How long would it take
a layer of this clay 5m thick to reach the same degree of
consolidation under the same stress and drainage conditions?
How long would it take the layer to reach 30% consolidation?
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
224
In an oedometer test a specimen of saturated clay 19mm thick
reaches 50% consolidation in 20 min. How long would it take
a layer of this clay 5m thick to reach the same degree of
consolidation under the same stress and drainage conditions?
How long would it take the layer to reach 30% consolidation?
University of Anbar
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
225
College of Engineering
Civil Engineering Department
Iraq-Ramadi
Asst. Prof. Khalid R. Mahmood (PhD.)
225
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 9,124
- Slides 68
- Favorites 17
- Age 3916 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
34 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
37 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
34 views
14
Fertility awareness methods for women in the society
Isaiah47
31 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
30 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
31 views