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IRJET - Identification and Remediation of Dispersive Soils
- 1. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 07 Issue: 02 | Feb 2020 www.irjet.net p-ISSN: 2395-0072
© 2020, IRJET | Impact Factor value: 7.34 | ISO 9001:2008 Certified Journal | Page 2094
Identification and Remediation of Dispersive Soils
Linda J1, Rani V2
1Student, Department of Civil Engineering, Marian Engineering College, Kerala, India
2Associate Professor, Department of Civil Engineering, Marian Engineering College, Kerala, India
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Abstract – Soils that are dislodged easily and rapidly in
flowing water of low concentration are called dispersive soils.
Structures such as embankments, channels and other areas
are susceptible to severe erosion, when such soils are used for
construction. Hence it is essential to test the erodability
especially during conditions of high surface flow. Two soils,
lithomargic and laterite were investigated using double
hydrometer, to determine the rate of dispersion. Laterite is a
soil and rock type rich in iron and aluminiumandiscommonly
considered to have formed in hot and wet tropical areas.
Lithomargic soil constitutes an important group of residual
soils under lateritic soils. Laterite soil is non-dispersive in
nature, whereas lithomargic is dispersive in nature.
Key Words: Laterite, Lithomargic, Dispersion, Double
hydrometer test
1. INTRODUCTION
In Earlier days clays were considered to be non-erosive and
highly resistant to water erosion, however recent studieson
clays found that highly erosive clay soils also exist in nature.
The tendency of the clays to disperse or de-flocculate
depends upon certain factors such as mineralogy, soil
chemistry and also on the dissolved salts in the pore water
and the eroding water. Many earth dams, hydraulic
structures and other structures like road wayembankments
have suffered serious erosion problems and have failed due
to the presence of the dispersive soils. Though the problem
has been identified in many parts of the world in recent
times, design advances and technical preventive measures
are yet to be fully developed and practised.
2. LITERATURE REVIEW
Anand B et al. (2015) aims on the characterization of
dispersive soils. Dispersive soils which occur in many parts
of the world are easily erodible and deflocculated in water
causing serious problems of stability of earth and earth
retaining structures. Earth dams constructed on dispersive
soils have suffered internal and surface erosion. This paper
deals with the best possible evaluation of test methods for
confirming and characterizing the dispersive soils. Crumb
test gave the visual identificationonsoil dispersivity.Pinhole
and double hydrometer test was more reliable.
Dinesh et al. (2011) tell that visual classification, atterberg
limits and particle size analysis do not provide sufficient
basis to differentiate between dispersive clays and ordinary
erosion resistant clays. Pinhole test and double hydrometer
test are the only two test that are vogue to identify the
dispersive soils.
Civenlekoglu .B (2009) deal with the performance of the
gypsum as an additive for treatment of the expansive clay
soils by means of swell potential and strength. Optimum
water content for the best compaction of the bentonite was
first determined by standard compaction test. Several
percentages of gypsum was added to bentonite and
compacted in optimum water content.
Bhuvaneshwari.S et al. (2007) studied on Stabilization and
microstructural modification of dispersive clayey soils. The
soil chosen for the study was highly dispersive. The addition
of lime and lime+flyash caused significant decrease in the
dispersive nature of the soil. Thepercentageofdispersion by
double hydrometer for the soil alone was 71% which
decreased to 9.5% after the addition of lime. The soil was
classified as ND4 by the pin hole test, the addition of
optimum percentage of additives changed it to ND1. The
crumb test and chemical tests were also in conjunction with
the above result. The mineralogical and micro structural
changes studied by SEM analyses clearly showthealteration
in the fabric and pore spaces due to the chemical reactions
initiated by the additives.
3. MATERIALS
3.1 Lithomargic Soil
The soil used in this study is collected locally from
Neyyattinkaea,Thiruvananthapuramdistrict. Theproperties
of the soil are studied using standard procedures and the
results are tabulated in table. From the test results, the soil
can be classified as CL according to Indian Standard
Classification system.
Table 1 Properties of Lithomargic soil
Properties Result
Specific gravity 2.75
Liquid limit (%) 32.8
Plastic limit (%) 19.8
Plasticity Index (%) 13
Clay (%) 53
Silt (%) 41
Sand (%) 6
Optimum moisture content (%) 25
Maximum Dry Density(Kn/M3) 16
Indian Standard Classification CL
- 2. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 07 Issue: 02 | Feb 2020 www.irjet.net p-ISSN: 2395-0072
© 2020, IRJET | Impact Factor value: 7.34 | ISO 9001:2008 Certified Journal | Page 2095
3.2 Laterite Soil
The soil used in this study is collected locally from
Neyyattinkara, Thiruvananthapuramdistrict. Theproperties
of the soil are studied using standard procedures and the
results are tabulated in table 2. From the test results,thesoil
can be classified as MI according to Indian Standard
Classification system.
Table 2 Properties of Laterite Soil
Properties Result
Specific gravity 2.41
Liquid limit (%) 45.5
Plastic limit (%) 31
Plasticity Index (%) 14.5
Clay (%) 23
Silt (%) 60
Sand (%) 17
Optimum moisture content(%) 24
Maximum dry density (kN/m3) 16.57
Indian Standard Classification MI
4. METHODOLOGY
The index properties of soil were determined as per the
respective IS Codes.
The double hydrometer test also known as soil conservation
service laboratory dispersion test was performedtoidentify
the dispersiveness of soil. The particle size distribution of
the soil is first determined using the standard hydrometer
test where the soil is dispersed in distilled waterwithstrong
mechanical agitation and chemical dispersant. A parallel
hydrometer test is then made on a duplicate soil specimen
but without mechanical agitation and without a chemical
dispersant.
The percent dispersion is the ratio of the dry mass of
particles smaller than 0.005mm diameter of the second test
to the first expressed as a percentage. The value of greater
than 50 is highly dispersive
5. RESULTS AND DISCUSSIONS
5.1 Identification of dispersive soil
Chart-1 Double hydrometer test of lithomargic soil
Chart-2 Double hydrometer test of laterite soil
From chart 1, the rate of dispersion of Lithomargic soil is
67% which is greater than 50%. So the soil is dispersive in
nature and it needs to be remediated. From chart 2, the rate
of dispersion of laterite soil is 28.5% which is less than 30%.
So the soil is not dispersive in nature.
5.2 Remediation of dispersive soil
Once a dispersive soil is exposed to water, clayparticlesmay
disperse and remain as suspended particles in water. In
appearance the dispersive clays are like normal clays that
are stable and somewhat resistant to erosion. But in reality
they can be highly erosive and subject to severe damage or
failure. These soils are highly susceptible to pipingfailure. In
this study lime is used as an additive to decrease
dispersivity.
- 3. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 07 Issue: 02 | Feb 2020 www.irjet.net p-ISSN: 2395-0072
© 2020, IRJET | Impact Factor value: 7.34 | ISO 9001:2008 Certified Journal | Page 2096
Chart-3 Double hydrometer test for Lithomargic soil+2%
lime
Chart-4 Double hydrometer test for Lithomargic soil+4%
lime
Chart-5 Double hydrometer test for Lithomargic soil+6%
lime
From chart 3, the rate of dispersion for Lithomargicsoil+2%
lime was 41.17%. From chart 4, the rate of dispersion for
Lithomargic soil+4% lime was reduced to 26% and for
Lithomargic soil+6% lime was reduced to 12.9% (chart 5).
The mechanism in which the dispersive property is
controlled by the addition of the lime is by the process of
chemical reactions. The beneficial changes are attributed to
the ion exchange and cementation reactions
(Bhuvaneshwari, S. 2007)
6. CONCLUSIONS
From the test results it was noted that:
The percentage of dispersion by the double hydrometer
test for Lithomargic soil was 67% which was greater
than 50%. So it was necessary to remediate the soil.
The percentage of dispersion foe laterite soil was28.5%
which comes under non-dispersive category.
For remediating dispersive soil 2%,4% and 6% lime
were added
By adding 6% lime the percentageofdispersionreduced
from 67% to 12.9%.
REFERENCES
[1] Anand B., Chitra R., Singh N. and Vyas S.,
“Characterization of Dispersive Soils- A Comparative
Evaluation between Available Tests”, International
Journal of Innovative Research in Scientific Engineering
and Technology, Vol.4, 2014, pp 12908-12918.
[2] Bhuvaneshwari S., Soundra B.,RobinsonRG.,GandhiSR.,
(2007). “Stabilization and micro structural modification
of dispersive clayeysoils”.FirstInternational conference
on soil and rock engineering, Colombo, pp 5–11
[3] Civelekoglu B. and Yilmaz I.,”Gypsum: An additive for
stabilization of swelling clay soil”, Journal of Applied
Clay Science, Vol.44, 2009, pp 166-172
[4] Dinesh S. V., Sivapullaiah V. P. and Umesh T. S.,
“CharacterizationofDispersiveSoils”,MaterialsSciences
and Applications, Science Research, Vol.2,2011,pp629-
633.
[5] ASTM D 4221-99,Standard test method for Dispersive
characteristics of clay soil by double hydrometer, ASTM
international, West Conshohocken, 2005