|
PARTICLE SIZE ANALYSIS
Sieve size
|
Actual mass retained
|
% mass retained
|
Cumulative % mass retained
|
% finer
|
4.75 mm
|
88.861
|
8.88
|
8.88
|
91.12
|
2.00 mm
|
155.091
|
15.50
|
24.38
|
75.62
|
1.00 mm
|
264.851
|
26.48
|
50.86
|
49.14
|
600 micron
|
90.181
|
9.01
|
59.87
|
40.131
|
425 micron
|
98.881
|
9.88
|
69.75
|
30.25
|
300 micron
|
61.651
|
6.16
|
75.91
|
24.09
|
212 micron
|
52.871
|
5.28
|
81.19
|
18.81
|
150 micron
|
73.791
|
7.37
|
88.56
|
11.44
|
75 micron
|
80.681
|
8.06
|
96.62
|
3.38
|
From the graph Gravel=24.38%
Sand=73.62%
Silt=2%
Clay=Nil
Uniformity coefficient=245.45 and coefficient of curvature=0.33
As D60 =1.2
D30 =0.43
D10 =0.15
Cu = D60 / D10 =8
Cc = ( D30 × D30)/ D10 × D60=1.03
So from the above we can draw the conclusion that it is a well graded type of soil. 
Direct Shear Test
Test no
|
Normal Stress
|
Shear stress at failure
|
Shear displacement at failure in mm
|
1
|
0.5
|
0.75
|
0.87
|
2
|
1.5
|
1.44
|
1.65
|
3
|
2.5
|
2.25
|
2.58
|
Graph was plotted between normal stress and shear stress and from the graph
Angle of internal friction was found to be 360 and c or cohession value was found to be 0.35.
Unconfined Compressive Strength
Deformation in mm
|
strain
|
Axial strain in %
|
Area(cm2)
|
Proving ring dial reading
|
Applied axial load in Kg
|
Stress in Kg/cm2
|
0
|
0
|
0
|
9.62
|
0
|
0
|
0
|
0.5
|
0.0067
|
0.67
|
9.684
|
6
|
2.127
|
0.219
|
1
|
0.0135
|
1.35
|
9.751
|
8
|
2.83
|
0.290
|
1.5
|
0.020
|
2.0
|
9.816
|
11
|
3.900
|
0.397
|
2
|
0.027
|
2.7
|
9.886
|
13
|
4.609
|
0.466
|
2.5
|
0.033
|
3.3
|
9.948
|
14
|
4.964
|
0.498
|
3
|
0.040
|
4
|
10.02
|
16
|
56.73
|
0.566
|
3.5
|
0.047
|
4.7
|
10.09
|
17
|
6.02
|
0.596
|
4
|
0.054
|
5.4
|
10.169
|
19
|
6.73
|
0.661
|
4.5
|
0.061
|
6.1
|
10.24
|
20
|
7.09
|
0.692
|
5
|
0.067
|
6.7
|
10.31
|
22
|
7.80
|
0.756
|
5.5
|
0.074
|
7.4
|
10.388
|
23
|
8.156
|
0.785
|
6
|
0.081
|
8.1
|
10.467
|
24
|
8.51
|
0.813
|
6.5
|
0.087
|
8.7
|
10.536
|
25
|
8.86
|
0.840
|
7
|
0.094
|
9.4
|
10.618
|
26
|
9.21
|
0.867
|
7.5
|
0.101
|
10.1
|
10.700
|
27
|
9.57
|
0.894
|
8
|
0.108
|
10.8
|
10.78
|
28
|
9.93
|
0.921
|
8.5
|
0.114
|
11.4
|
10.857
|
28
|
9.93
|
0.914
|
9
|
0.121
|
12.1
|
10.944
|
28
|
9.93
|
0.907
|
9.5
|
0.128
|
12.8
|
11.032
|
28
|
9.93
|
0.900
|
A graph was plotted between σ and ε.The maximum stress from this curve gave the value of unconfined compressive strength = qu =90.32KN/m2
Shear strength c= qu/2 =45.15KN/m2
Newson et al. (2006) carried out investigations on physiochemical and mechanical properties of red mud at a site in the United Kingdom. Based on a set of laboratory tests conducted on the red mud, the compression behaviour found to similar to clayey soils, but frictional behaviour closer to sandy soils. The red mud appears to be “structured” and has features consistent with sensitive, cemented clay soils. Chemical testing suggests that the agent causing the aggregation of particles is hydroxyl sodalite and that the bonds are reasonably strong and stable during compressive loading and can be broken down by subjecting the red mud to an acidic environment. Exposure of the red mud to acidic conditions causes dissolution of the hydroxyl sodalite and a loss of particle cementation. Hydration of the hydroxyl sodalite unit cells is significant, but does not affect the mechanical performance of the material. The shape, size, and electrically charged properties of the hydroxyl sodalite, goethite, and hematite in the red mud appear to be causing mechanical behaviour with features consistent with clay and sand, without the presence of either quartz or clay minerals.
behaviour closer to sandy soils. The red mud appears to be “structured” and has features consistent with sensitive, cemented clay soils. Chemical testing suggests that the agent causing the aggregation of particles is hydroxyl sodalite and that the bonds are reasonably strong and stable during compressive loading and can be broken down by subjecting the red mud to an acidic environment. Exposure of the red mud to acidic conditions causes dissolution of the hydroxyl sodalite and a loss of particle cementation. Hydration of the hydroxyl sodalite unit cells is significant, but does not affect the mechanical performance of the material. The shape, size, and electrically charged properties of the hydroxyl sodalite, goethite, and hematite in the red mud appear to be causing mechanical behaviour with features consistent with clay and sand, without the presence of either quartz or clay minerals.
Liu et al. (2006) observed that pH value of red mud decreases with increase in duration of storage time and Oxygen(O) accounted for about 40% with other major elements included Calcium(Ca), Iron(Fe), Silicon(Si), Aluminium(Al), Titanium(Ti), Sodium(Na), Carbon, Magnesium(Mg) and Potassium(K) . XRD analysis shows calcite, perovskite, illite, hematite and magnetite are present in red mud and the old red mud also contained some kassite and portlandite. In addition, there are about 20% of amorphous materials in all red mud.
Sundaram and Gupta (2010) have some in-situ investigations on red mud to be used as a foundation material and they have observed that red mud is highly alkaline (9.3-10.2) with liquid limit of 39-45 %, plastic limit of 27-29% and shrinkage limit of 19-22%. They also found that undrained shear strength is 0.4 to 1.4 kg/cm2, specific gravity is 2.85-2.97, cohesion is 0.1 to 0.2 kg/cm2 and angle of internal friction is 26-280.
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