Effect of Fly-ash on Strength Behavior of Clayey Soil

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 04 Issue: 07 | July -2017 www.irjet.net p-ISSN: 2395-0072
© 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 2506
Effect of Fly-ash on Strength Behavior of Clayey Soil
Tinku Kalita1, Anita Saikia2, Bhaskarjyoti Das3
1PhD Student, Assam Engineering College, Guwahati (Assam)
2Lecturer in Selection Grade, Assam Engineering Institute, Guwahati (Assam)
3Associate Professor, Assam Engineering College, Guwahati (Assam)
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Abstract - Stabilization includes various methods for
improving the engineering properties of soil. Stabilization is
used to increase the strength or stability of soil. With addition
of fly-ash in the soil, the index properties of soil are foundto be
improved. It is found that the optimum moisture content
decreases while maximum dry density increases with addition
of fly ash. The unconfined compressive strength of the soils
increases with the addition of fly ash content. This paper
presents the effective use of fly ash in improving the
engineering properties of clayey soil. A series of tests were
conducted on clayey soil treated with fly-ash alone (i.e. 2%,
4%, 6%, 8% and 10%). From the test results, it was observed
that with the increase in fly ash content the Maximum Dry
Density (MDD) increased up to 5.81% at 6% fly ash content.
The optimum fly ash content was determined based on
Standard Proctor test and Unconfined Compressive Strength
(UCS) test results. The maximum UCS value was observed at
6% of fly-ash content. The increase in UCS at 6% fly ash
content was 10.9%.The use of fly ash as the stabilizer with soil
is a cost-effective and environment-friendlytechniquetomake
the soil mixes strong.
Key Words: Maximum dry density, Optimum moisture
content, Unconfined compressive strength, Fly ash, Cost
effective.
1. INTRODUCTION
Clayey soil generally possesses volumetric changes when
subjected to changes in moisture content because of the
seasonal water fluctuations. Also, low strength and high
compressibility behavior of most clays can cause severe
damage to civil engineering structures.Therefore,thesetype
of soil must be treated before commencing the construction
operation. Various methods are available to improve the
engineering properties of these soils such as densification,
reinforcement, chemical stabilizationandtechniquesofpore
water pressure reduction. The chemical stabilizationofclays
using fly ash is one of the best alternatives as it improves
various engineering properties of soil such as maximum dry
density and unconfined compressive strength.
2. LITRETURE REVIEW
Soil stabilization technique is done on relatively weak soil to
improve its shear strength, load bearing capacity, filter,
drainage system etc. The improvement behavior of soil by
geo-textile technique conducted by Krishnaswamy et al
(1988) concluded with the increase in reinforcement aspect
the soil strength ratio increases. Ramanatha Ayyar et al.
(1989) performed tests on coir fiber reinforced clay and it
was observed that the discrete fibre of small diameter offer
greater resistance to swelling than the larger diameter fibre
placed similarly. Kolay et al. (2010) explained the soil
stabilization of locallyavailablepeatsoilfromSarawak,using
fly ash and gypsum. The unconfined compressive strength
test results showed that the peat soil got strengtheneddueto
the addition of different proportions of gypsum and fly ash
and it was also observed that the strength of peat soil
increases with the increase in curingperiod.Ramlakhanetal.
(2013) observed that with the increase in lime and fly ash
content in the soil the optimum moisture content and
California bearing ratio of soil increases. R. Chavali and R. K.
Sharma (2014) carried out a study on influence of sand and
fly ash on clayey soil stabilization. The results show
significant improvement in California bearing ratio of
composite containing clay, sand and fly ash as (70: 30: 10).
Gyanen et al. (2013) considered the effect of both coarse and
fine fly ash in unconfined compressive strength of black
cottonsoil. It was observed that the peak strength isattained
by fine fly ash composite was 1.25 times the strength
obtained with coarse fly ash composite. Cokca Erdal (2001)
added Soma fly ash and Tuncbilek fly ash to the expansive
soil at 0-25%. The optimum content of fly ash to reduce the
swell potential was found to be 20%. Jirathanathworn and
Chantawarangul (2003) found that by using fly ash mixed
with small amount of lime, the engineering properties of
clayey soil such as strength and hydraulic conductivity
improved. Bose (2012) found that the maximum dry density
of soil increases till 20% flyashcontentandthenitsgradually
decreases, however the optimum moisture decreases with
increase in fly ash content. Kaushik and Ramasamy (2006)
investigate the different properties of coal ash to be used as
construction material. It was found that the fly ash exhibits
high strength at optimum moisture content but poor shear
strength at saturated conditions.
3. MATERIAL USED
Clayey soil samples were collected from six different sites of
Guwahati city, Assam, from a depth of 1m below the ground
surface. The soil was pulverized to break lumps and then air
and oven dried before conducting the test. The physical
properties of various soil samplesare as giveninTable1.The

fly-ash was collected from Hindustan Paper Corporation
Limited (HPCL), Jagiroad, Assam. The specific gravity of fly
ash is 1.91.
Table -1: Physical properties of soil
SL
no
Sample SL 1 SL 2 SL 3 SL 4 SL 5 SL 6
1 Liquid
Limit (%)
46 44 37 39 41 43
2 Plastic
Limit (%)
21 20 19 21 18 22
3 Plasticity
Index
(%)
25 22 18 18 23 21
4 Specific
Gravity
(G)
2.63 2.65 2.63 2.60 2.59 2.58
5 OMC
(%)
14.6 14.1 15.2 15.6 18.7 18.4
6 MDD
(g/cc)
1.87 1.91 1.86 1.72 1.67 1.64
4. COMPACTION AND UNCONFINED COMPRESSIVE
STRENGTH TEST
The Standard Proctor Test were done as per IS2720(Part 7)
- 1980 to determine the OMC and MDD for all the six
samples. The value of OMC and MDDaregiveninTable2. For
unconfined compressive strength test, samples of 3.8 cm
diameter and 7.6 cm height were prepared by the
compaction of the samples at their optimum moisture
contents and maximum dry density. All the samples were
tested at an axial strain rate of 1.2 mm /min as per IS: 2720
(Part-X). The Unconfined compressive strength of all thesix
samples are given in Table 2.
Table -2: Engineering properties of soil
SL
no
Sample SL 1 SL 2 SL 3 SL 4 SL 5 SL 6
1 Optimum
Moisture
Content (%)
14.6 14.1 15.2 15.6 18.7 18.4
2 Maximum
Dry Density
(g/cc)
1.87 1.91 1.86 1.72 1.67 1.64
3 Unconfined
Compressive
Strength
(kN/m3)
112 119 120 117 111 107
5. EXPERIMENTAL OBSERVATION
Figure -1: Variation of maximum dry density with fly ash
content
From the Figure 1, it can be observed that the maximum dry
density of the soil increases with the increase in fly ash
content and attained a maximum value at 6% of fly ash
content and then further addition of flyashleadstodecrease
in maximum dry density.
Figure -2: Variation of optimum moisture content with fly
ash content
From the Figure 2, it can be observed that with the addition
of fly ash to the soil, the optimum moisture content start
decreasing.
Figure -3: Variation of unconfined compressive strength
with fly ash content

From the Figure 3, it is observed that with the increase in fly
ash content the unconfined compressive strength is
increasing and attained a maximum value at 6% of fly ash
and then on further increase in fly ash content the
unconfined compressive strength decreases.
Table -3: Unconfined compressive strength of soil
UCS (kN/m3)
flyash
(%) SL 1 SL 2 SL 3 SL 4 SL 5 SL 6
0 112.2 119.4 120.1 117.4 111.6 107.4
2 118.1 124.5 127.9 120.4 116.3 112.6
4 128.5 128 131.2 123.9 117.3 117.7
6 134.2 132.3 127.2 126.2 121.7 119.4
8 126.3 129.3 124.6 121.1 122.4 116.1
10 124.4 125.5 122.1 120.2 120.1 117.3
6. CONCLUSIONS
The following salient observations are obtained from the
study:
1. From figure 1, the maximum dry density is obtained
at 6% of fly ash content for the samples (SL 1, SL 2,
SL 3) and the maximum dry density is obtained at
8% of fly ash content for the samples (SL 4, SL 5, SL
6).
2. From figure 2, it is observed that with the increase
in fly ash content the optimum moisture content
decreases.
3. From figure 3, it is observed that the unconfined
compressive strength is maximum at 6% of fly ash
content for the samples (SL 1, SL 2, SL 4, SL 6).
4. From figure 3, it is found that the unconfined
content for the sample (SL 3).
5. From figure 3, it is found that the unconfined
content for the sample (SL 5).
REFERENCES
[1] Bairwa Ramlakhan, Anil Kumar Saxena , T.R. Arora
(2013)“Effect of lime and fly ash on Engineering
Properties of Black Cotton soil” International Journal of
Emerging Technology and Advanced Engineering,
Volume 3, Issue 11, November 2013, pp 535-541.
[2] B. Bose,(2012) “Geoengineeringpropertiesofexpansive
soil stabilized with fly ash,” Electronic Journal of
Geotechnical Engineering, Vol. 17, Bund. J, pp. 1339-
1353.
[3] Binquet J, Lee KL.(1975) “Bearing capacity tests on
reinforced earth slabs” J Geotech Eng Div, ASCE
,101:1241 –55 (GT12).
[4] Chavali Rama, R. K. Sharma (2014) - “Influence of sand
and fly ash on clayey soil stabilization.” IOSR Journal of
Mechanical and Civil Engineering (IOSR-JMCE) e-ISSN:
2278-1684, p-ISSN: 2320-334X pp. 36-40.
[5] Cokca Erdal (2001). “Use of Class C Fly Ashes for the
Stabilization – of an Expansive Soil”, Journal of
Geotechnical and Geoenvironmental Engineering Vol.
127, July, pp. 568-573
[6] Garg KG, Saranswami.(1991) ”Behavior of reinforced
sand samples in triaxial shear” Proceedings of Indian
Geotechnical conference, Surat, India,pp.359–361.
[7] Gyanen, Takhelmayum, Savitha, A. L., and Krishna Gudi
(2013). “Laboratory StudyonSoil StabilizationUsingFly
ash Mixtures” International Journal of Engineering
Science and Innovative Technology (IJESIT) Volume 2.
ISSN: 2319-5967 ISO 9001:2008 Certified.
[8] Kolay, P. K., and Pui, M. P. (2010). “Peat Stabilization
using Gypsum and Fly Ash”, UNIMAS E-Journal of Civil
Engineering, Vol. 1.
[9] N.P. Kaushik and G. Ramasamy (2006), “Strength
characteristics of compacted coal ash”, Unpublished
thesis, Department of Civil Engineering, Engineering
College Kota.
[10] Ramanatha Ayyar TS, Krishnaswamy NR, Viswanadhan
BVS.(1989) “Geosynthetics for foundation on a swelling
clay”, Proceedings of International Workshop on
Geotextiles. Bangalore, India, pp. 176–180.
[11] Saeid. Amiralian, Amin. Chegenizadeh, Hamid.
Nikraz,(2012) “A Review on The Lime and Fly ash
Application in Soil Stabilization”.International Journal of
Biological, Ecological and Environmental Sciences
(IJBEES), vol .1(3), pp. 124-126.
[12] Senol, A.,(2006) “Soft subgrades stabilization by using
various fly ashes” Resources, conservation, and
recycling, 46(4), pp. 365.
[13] Sezer, A.,(2006) “Utilization of a very high lime fly ash
for improvement of Izmir clay” Building and
environment, 41(2), pp. 150.
[14] T.S. Jirathanathworn, Nontananandh and
Chantawarangul (2003), “Stabilization of clayey sand
using fly ash mixed with small amount of lime”, Proc. of
the 9th National Convention on Civil Engg. Engineering
institute of Thailand and Thammasat University,
Petchaburi, 2: GTE, pp. 93-98.

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