![/kNm10*74.6
632.01
10*1.1
e1
a
m 25
4
v
v
−
−
=
+
=
+
=
and
312.0
100
1500log
577.0632.0
Δlogσ'
Δe
cc =
−
−=−=
Example 3:
Compute the expected settlement of a building constructed on a soil layer of 2.5m
thick its e = 0.72, the pressure increased from 1.5 kg/cm2
to 3.8 kg/cm2
and caused
reduction in void ratio by 15%.
Solution:
e1 = 0.72(1 – 0.15) = 0.612
method 1
cm15.7m157.05.2*
72.01
0.6120.72
H.
e1
Δe
S
o
c
==
+
−
=
+
=
method 2
047.0
5.18.3
612.072.0
Δσ'
Δe
av =
−
−
==
027.0
72.01
047.0
e1
a
m
o
v
v =
+
=
+
=
cm15.5m0.1551.5)(3.8*2.5*0.027σHmS **vc
===′∆= −
Example 4:
For the system shown below, determine the primary consolidation settlement if cs =
0.05 for the following:
1) σ'c = 100 kPa 2) σ'c = 150 kPa 3) σ'c = 175 kPa 4) σ'c = 250 kPa
Solution:
1) σ'c = 100 kPa
σ'o at midpoint of the clay layer
2
o
kN/m150.85
9.7*19.81)5(19.718.7*5'σ
=
++= −
1663.0
85.150
100
σ
σ
OCR '
o
'
c
<=== therefore, under
]
'Δσσ'
σ
log
σ'
σΔσ
[log
e1
Hc
S
avo
'
o
o
'
o
o
c
c
−
+
′+
+
=
425.25)10085.150(
2
1
)σσ(
2
1'Δσ '
c
'
oav
=−== − kPa](https://image.slidesharecdn.com/examplesontotalconsolidation-180320122215/85/Examples-on-total-consolidation-3-320.jpg)
![162mm0.162m]
25.425150.85
150.85
log
150.85
50150.85
[log
1.11
2*0.83
Sc
==+
+
+
=
−
2) σ'c = 150 kPa
1
85.150
150
σ
σ
OCR '
o
'
c
≈== normal
o
'
o
o
c
c σ'
σΔσ
log
e1
Hc
S
′+
+
=
mm98m098.0
150.85
50150.85
log
1.11
2*0.83
Sc
==
+
+
=
3) σ'c = 175 kPa
16.1
85.150
175
σ
σ
OCR '
o
'
c ===
kPa200.855085.150σΔσ'
o =+=′+
σ'c = 175 kPa
Because kPa200.85σΔσ'
o =′+ > σ'c = 175 kPa
c
'
o
o
c
o
'
c
o
s
c σ'
σΔσ
log
e1
Hc
σ'
σ
log
e1
Hc
S
′+
+
+
+
=
mm50.4m.05040
175
50150.85
log
1.11
2*0.83
150.85
175
log
1.11
2*0.05
Sc
==
+
+
+
+
=
4) σ'c = 250 kPa
Because kPa200.85σΔσ'
o =′+ < σ'c = 250 kPa
o
'
o
o
s
c σ'
σΔσ
log
e1
Hc
S
′+
+
=
mm6m0.006
150.85
50150.85
log
1.11
2*0.05
Sc
==
+
+
=
Example 5:
A soil profile shown in figure below, if a uniform distributed load,Δσ , is applied at
the ground surface, what is the settlement of the clay layer caused by primary
consolidation if:
1. The clay is normally consolidated
2. The preconsolidation pressure (σ'c) = 190 kN/m2
3. σ'c = 170 kN/m2
Use cs=1/6 cc
Solution:
1. The clay is normally consolidated
the average effective stress at the middle](https://image.slidesharecdn.com/examplesontotalconsolidation-180320122215/85/Examples-on-total-consolidation-4-320.jpg)
Examples on total consolidation
- 1. Example 1: Given d = 5 cm, Ho = 1.9 cm, Ws = 58 g, Gs = 2.7, constant, c = 1*10-4 cm σ' (kg/cm2 ) 0 0.25 0.5 1.0 2.0 4.0 R 100 199 256 358 520 635 Determine: 1) void ratio for loading 2) compute parameters of consolidation Solution: cm094.1 1*2.7(2.5)*π 58 γAG W H * 2 ws s s === 806.0094.19.1HHH sov =−=−= 737.0 1.094 0.806 H H e s v o === 009.0 094.1 10*1*)100199( H H e 4 s 1 1 = − = ∆ =∆ − 728.0009.0737.0eee 1o1 =−=∆−= 014.0 094.1 10*1*)100256( H H e 4 s 2 2 = − = ∆ =∆ − 723.0014.0737.0eee 2o2 =−=∆−= And so on σ' (kg/cm2 ) 0 0.25 0.5 1.0 2.0 4.0 R 100 199 256 358 520 635 ΔH, cm 0 0.0099 0.0156 0.0258 0.042 0.0535 e 0.737 0.728 0.723 0.713 0.699 0.688 From figure (1) 014.0 12 713.0699.0 Δσ' Δe av = − − −=−= cm2 /kg 0081.0 737.01 014.0 e1 a m o v v = + = + = cm2 /kg From figure (2) 047.0 1 2log 713.0699.0 Δlogσ' Δe cc = − −=−= and σ'c = 0.7 kg/cm2 Example 2: The following compression readings were obtained in an oedometer test on a specimen of saturated clay: σ' (kN/m2 ) 0 54 107 214 429 858 1716 3432 0 Dial Guage after 24 hrs, mm 5.00 4.74 7 4.49 3 4.108 3.44 9 2.608 1.676 0.737 1.480 The initial thickness of the specimen was 19.0 mm and at the end of the test the water content was 19.8% and the specific gravity was 2.73. Plot e-logσ curve and determine
- 2. the coefficient of compressibility between 100-200 and 1000-1500 kN/m2 . What is the value of cc for the latter increment? Solution: Void ratio at the end of the test = ef = ωGs= 0.198*2.73 = 0.541 Void ratio at the start of the test = eo = ef + ∆e Now, ee1 e e1 e H H foo ∆++ ∆ = + ∆ = ∆ 350.0e e0.5411 e 0.19 48.15 =∆⇒ ∆++ ∆ = − eo = ef + ∆e = 0.541 + 0.35 = 0.891 In general the relationship between ∆e and ∆H is given by: 891.01 e 19.0 H e1 e H H oo + ∆ = ∆ ⇒ + ∆ = ∆ H0995.0e ∆=∆⇒ , and can be used to obtain the void ratio at the end of each increment period. σ' (kN/m2 ) 0 54 107 214 429 858 1716 3432 0 Dial Guage after 24 hrs, mm 5.00 4.74 7 4.49 3 4.108 3.44 9 2.608 1.676 0.737 1.480 ∆H, mm 0 0.25 3 0.50 7 0.892 1.55 1 2.392 3.324 4.263 3.520 ∆e 0 0.02 5 0.05 0 0.089 0.15 4 0.238 0.331 0.424 0.350 e 0.89 1 0.86 6 0.84 1 0.802 0.73 7 0.653 0.560 0.467 0.541 e1 = eo – ∆e = 0.891 – 0.025 =0.866 0.891 – 0.05 = 0.841 The e-logσ curve using these values is shown in figure below. Using Casagrande’s construction the value of the preconsolidation pressure is 325 kN/m3 . Between the pressure range 100 and 200 kN/m2 e100= 0.845 e200= 0.808, therefore /kNm10*7.3 100200 808.0845.0 Δσ' Δe a 24 v − = − − −=−= /kNm10*005.2 845.01 10*7.3 e1 a m 24 4 v v − − = + = + = Between the pressure range 1000 and 1500 kN/m2 e1000= 0.632 e1500= 0.577, therefore /kNm10*1.1 10001500 577.0632.0 Δσ' Δe a 24 v − = − − −=−=
- 3. /kNm10*74.6 632.01 10*1.1 e1 a m 25 4 v v − − = + = + = and 312.0 100 1500log 577.0632.0 Δlogσ' Δe cc = − −=−= Example 3: Compute the expected settlement of a building constructed on a soil layer of 2.5m thick its e = 0.72, the pressure increased from 1.5 kg/cm2 to 3.8 kg/cm2 and caused reduction in void ratio by 15%. Solution: e1 = 0.72(1 – 0.15) = 0.612 method 1 cm15.7m157.05.2* 72.01 0.6120.72 H. e1 Δe S o c == + − = + = method 2 047.0 5.18.3 612.072.0 Δσ' Δe av = − − == 027.0 72.01 047.0 e1 a m o v v = + = + = cm15.5m0.1551.5)(3.8*2.5*0.027σHmS **vc ===′∆= − Example 4: For the system shown below, determine the primary consolidation settlement if cs = 0.05 for the following: 1) σ'c = 100 kPa 2) σ'c = 150 kPa 3) σ'c = 175 kPa 4) σ'c = 250 kPa Solution: 1) σ'c = 100 kPa σ'o at midpoint of the clay layer 2 o kN/m150.85 9.7*19.81)5(19.718.7*5'σ = ++= − 1663.0 85.150 100 σ σ OCR ' o ' c <=== therefore, under ] 'Δσσ' σ log σ' σΔσ [log e1 Hc S avo ' o o ' o o c c − + ′+ + = 425.25)10085.150( 2 1 )σσ( 2 1'Δσ ' c ' oav =−== − kPa
- 4. 162mm0.162m] 25.425150.85 150.85 log 150.85 50150.85 [log 1.11 2*0.83 Sc ==+ + + = − 2) σ'c = 150 kPa 1 85.150 150 σ σ OCR ' o ' c ≈== normal o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm98m098.0 150.85 50150.85 log 1.11 2*0.83 Sc == + + = 3) σ'c = 175 kPa 16.1 85.150 175 σ σ OCR ' o ' c === kPa200.855085.150σΔσ' o =+=′+ σ'c = 175 kPa Because kPa200.85σΔσ' o =′+ > σ'c = 175 kPa c ' o o c o ' c o s c σ' σΔσ log e1 Hc σ' σ log e1 Hc S ′+ + + + = mm50.4m.05040 175 50150.85 log 1.11 2*0.83 150.85 175 log 1.11 2*0.05 Sc == + + + + = 4) σ'c = 250 kPa Because kPa200.85σΔσ' o =′+ < σ'c = 250 kPa o ' o o s c σ' σΔσ log e1 Hc S ′+ + = mm6m0.006 150.85 50150.85 log 1.11 2*0.05 Sc == + + = Example 5: A soil profile shown in figure below, if a uniform distributed load,Δσ , is applied at the ground surface, what is the settlement of the clay layer caused by primary consolidation if: 1. The clay is normally consolidated 2. The preconsolidation pressure (σ'c) = 190 kN/m2 3. σ'c = 170 kN/m2 Use cs=1/6 cc Solution: 1. The clay is normally consolidated the average effective stress at the middle
- 5. of the clay layer is 2 o kN/m79.14 9.81)-2(199.81)-4(1814*2'σ = ++= cc = 0.009(LL-10) = 0.009 (40 – 10) = 0.27 o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm132m321.0 79.14 10079.14 log 0.81 4*0.27 Sc == + + = 2. The preconsolidation pressure (σ'c) = 190 kN/m2 2' o kN/m179.14σΔσ =′+ σ'c = 190 kN/m2 Because 2' o kN/m179.14σΔσ =′+ < σ'c = 190 kN/m2 o ' o o s c σ' σΔσ log e1 Hc S ′+ + = , cs = 1/6 cc = 1/6 * 0.27 = 0.045 mm36m0.036 79.14 179.14 log 0.81 4*0.045 Sc == + = 3. σ'c = 170 kN/m2 Because ' o ' c ' o σσσΔσ >>′+ c ' o o c o ' c o s c σ' σΔσ log e1 Hc σ' σ log e1 Hc S ′+ + + + = mm46.9m.04690 170 179.14 log 0.81 4*0.27 179.14 170 log 0.81 4*0.045 Sc == + + + = Example 6: For the foundation shown, estimate the consolidation settlement. Solution: The average effective stress at the middle of the clay layer is 2 o kN/m52.833 9.81)-(16 2 2.5 9.81)0.5(17.516.5*2.5'σ = ++= − Using approximate method to calculate the 'Δσ at mid-point of clay layer 2 v kN/m445.13 )25.32)(25.31( 1*2*150 z)z)(L(B qBL Δσ = ++ = ++ = Or using m,n method 15.0 25.3 5.0 z L m === , and 31.0 25.3 1 z B n === f(m,n) = 0.02 2 kN/m124*150*02.0'Δσ == 1.0 0.5 2.5 Sand B*L=1m*2m G.W.T ?=16.5kN/m3 ?sat=17.5kN/m 3 Sand Clay(N.C.) q=150kN/m 1.5 ?sat=16kN/m3 cc=0.32 cs=0.09 eo=0.8 2
- 6. 1.5 1.5 2.5 Sand B*L G.W.T ?=15kN/m 3 ?sat=18kN/m 3 Sand Clay(N.C.) Gs=2.7,LL=38% ?=35% Q o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm43.8m3804.0 52.833 13.44552.833 log 0.81 2.5*0.32 Sc == + + = Example 7: In the previous example, if the foundation is circular in shape with diameter of 2.5m, estimate the consolidation settlement. Solution: Using approximate method to calculate the 'Δσ at mid point of clay layer 2 2 2 2 2 kN/m355.28 )25.35.2( 5.2*150 Z)(D qD σΔ = + = + =′ or using 2.6 1.25 3.25 R z == , and 0 1.25 0 R x == from figure 0.18 q Δσv ≈ 2 kN/m27150*18.0σΔ ==′ mm82.9m8290.0 52.833 28.35552.833 log 0.81 2.5*0.32 Sc == + + = Example 8: Refer to figure shown below, given that B=1.5m, L=2.5m, and Q=120 kN. Calculate the primary consolidation settlement of the foundation. Solution: 0.945 1 2.7*0.35 S sωG eo === 3 w s sat clay kN/m18.49.81* 0.9451 0.9452.7 γ e1 eG γ = + + = + + = 2 o kN/m5.5234 9.81)-(18.4 2 2.5 9.81)-1.5(1815*1.5'σ = ++= 'Δσ at the base of the foundation = 2 32kN/m 2.5*1.5 120 = To determine the net consolidation pressure at mid height of clay layer under the center of the foundation, the foundation's base must be divided into four equal 0.75*1.25 rectangular areas. z = 1.5+2.5/2 = 2.75m from the foundation's base 45.0 75.2 25.1 z L m === , and 27.0 75.2 75.0 z B n === f(m,n) = 0.047 2 kN/m016.64*32*047.0'Δσ == 2' o kN/m51.5396.01645.523σΔσ =+=′+ cc = 0.009(LL-10) = 0.009 (38 – 10) = 0.252 o ' o o c c σ' σΔσ log e1 Hc S ′+ + =
- 7. mm4.17m0174.0 45.523 51.539 log 0.9451 2.5*0.252 Sc == + = Example 9: A building is supporting on a raft 45m x 30m, the net foundation pressure being 125 kN/m2 . The soil profile is shown in figure below. The value of mv = 0.35 m2 /MN. Determine the final settlement under the center of the raft due to consolidation of the clay. Solution: at mid point of clay layer, z = 24 – 3.5 + 2 = 23.5m 96.0 5.23 5.22 z L m === , and 64.0 5.23 15 z B n === f(m,n) = 0.14 2 kN/m704*125*14.0'Δσ == mm98m0.09870*4*10*0.35σHmS 3- **vc ===′∆= Example 10: A stratum of normally loaded clay of 7m thick is located at a depth 12m below ground level. The (ωn) of the clay is 43% and its LL is 48%. The Gs of the solid particles is 2.76. the water table is located at a depth of 5m below the ground surface. The soil is sand above the clay stratum. The submerged unit weight of sand is 11 kN/m3 and the same weighs 18 kN/m3 above water table. The average increase in pressure at the center of the clay stratum is 120 kN/m2 due to the weight of a building that will be constructed on the sand above the clay stratum. Estimate the expected settlement of the structure. Solution: 1) Determination of e and γsub for clay s w W W ω = , kN076.2781.9*76.2*1γGVW wsss ===
- 8. kN643.11076.27*43.0ωWW sw === kN719.38076.27643.11WWW swt =+=+= 187.1 1 76.2*43.0 S ωG e s o === 3 o t t kN/m704.17 187.11 719.38 e1 W γ = + = + = , equal to γsat or wsat γ e1 esG γ + + = 3 sub kN/m7.8949.8117.704γ =−= 2) Determination of overburden pressure ' oσ 2' o kN/m194.6293.5*7.8947*1118*5σ =+++= 3) Compression index cc = 0.009(LL-10) = 0.009(48-10) = 0.342 4) Excess pressure ∆σ' = 120 kN/m2 5) Total Settlement o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm228m228.0 194.629 120194.629 log 1.1871 7*0.342 Sc == + + = Example 11: Soil investigation at a site gave the following information. Top soil up to a depth of 10.6m is fine sand, and below this lies soft clay layer of 7.6m thick. The water table is at 4.6m below the ground surface. The submerged unit weight of sand is 10.4 kN/m3 , and wet unit weight above water table is 17.6 kN/m3 . The water content of normally consolidated clay is 40%, its LL is 45% and Gs is 2.78. The proposed construction will transmit a net pressure of 120 kN/m2 . Find the average settlement of the clay layer. Solution: cc = 0.009(LL-10) = 0.009(45-10) = 0.315 112.1 1 78.2*4.0 S ωG e s o === 3 wsat kN/m078.189.81* 1.1121 1.1122.78γ e1 esG γ = + += + + = 3 sub kN/m8.2689.8118.078γ =−= Effective overburden pressure at the mid height of the clay layer is 2' o kN/m174.7783.8*8.26810.4*617.6*4.6σ =+++= o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm257m257.0 174.778 120174.778 log 1.1121 7.6*0.315 Sc == + + = Example 12: Two points on a curve for normally consolidated clay have the following coordinates: Point 1: e1 = 0.7, σ1 = 1 kg/cm2
- 9. Point 2: e2 = 0.6, σ2 = 3 kg/cm2 If the average overburden pressure on a 6m thick clay layer is 1.5 kg/cm2 , how much settlement the clay layer experience due to additional load intensity of 1.6 kg/cm2 . Solution: 21.0 13log 6.07.0 σ σ log ee c 1 2 21 c = − = − = We need the initial void ratio eo at an overburden pressure of 1.5 kg/cm2 . 5.1 3 log21.0)6.0e(21.0 σ σ log ee c o o 2 2o c =−⇒= − = 0.6630.0630.6eo =+=⇒ o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm239m239.0 1.5 1.61.5 log 0.6631 6*0.21 Sc == + + = Example 13: A footing has a size of 3m by 1.5m and it causes a pressure increment of 200 kN/m2 at its base. Determine the consolidation settlement at the middle of the clay layer. Assume 2:1 pressure distribution. Solution: 2 ' o kN/m1.885 5.19*1.58.19*0.516*2.5σ = +++= 2 v kN/m692.27 )5.33)(5.35.1( 3*5.1*200 z)z)(L(B qBL Δσ = ++ = ++ = o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm93m093.0 51.88 27.69251.88 log 0.81 3*0.3 Sc == + + =
- 10. Point 2: e2 = 0.6, σ2 = 3 kg/cm2 If the average overburden pressure on a 6m thick clay layer is 1.5 kg/cm2 , how much settlement the clay layer experience due to additional load intensity of 1.6 kg/cm2 . Solution: 21.0 13log 6.07.0 σ σ log ee c 1 2 21 c = − = − = We need the initial void ratio eo at an overburden pressure of 1.5 kg/cm2 . 5.1 3 log21.0)6.0e(21.0 σ σ log ee c o o 2 2o c =−⇒= − = 0.6630.0630.6eo =+=⇒ o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm239m239.0 1.5 1.61.5 log 0.6631 6*0.21 Sc == + + = Example 13: A footing has a size of 3m by 1.5m and it causes a pressure increment of 200 kN/m2 at its base. Determine the consolidation settlement at the middle of the clay layer. Assume 2:1 pressure distribution. Solution: 2 ' o kN/m1.885 5.19*1.58.19*0.516*2.5σ = +++= 2 v kN/m692.27 )5.33)(5.35.1( 3*5.1*200 z)z)(L(B qBL Δσ = ++ = ++ = o ' o o c c σ' σΔσ log e1 Hc S ′+ + = mm93m093.0 51.88 27.69251.88 log 0.81 3*0.3 Sc == + + =