E-ISSN : 2541-5794  
   P-ISSN : 2503-216X  

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 03 No 01 2018 

 

 
Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018  1 

 

Experimental Study to Reinforce The Weak Subgrade Soil for 
Low-Volume Roads by Coir Geotextile Mats 

D Harinder 
1
*, S. Shankar 

2
 

1
 National Institute of Technology, Warangal, India.   

 
* Corresponding author: hariatnitw@gmail.com 
Tel.:+918106857040 
Received: Nov 08, 2017. Revised : Feb 15, 2018, Accepted: Feb 26, 2018, Published: 1 March 2018  
DOI: 10.24273/jgeet.2018.3.01.882 

 
Abstract 

The construction and maintenance of pavement over the weak subgrade soil become the challenging task to the 
pavement engineering. One of the major reasons of subgrade failure of pavement is weak subgrade. The weak subgrade soil 
noticed a Black Cotton (BC) soil. The BC soil subgrade poses several serious problems to the pavement such as rutting, fatigue, 
reflecting crack and undulation of the pavement. To minimize this problem of pavement, there are many conventional 
stabilization techniques were adopted and reported. But these techniques are not applied effectively into the pavement to 
stabilize the weak subgrade. To address this problem, to give the additional strength to the pavement geosynthetics are taken 
as alternate material for stabilization of pavement. In the present study, an attempt is made in the laboratory with four types 
of coir mats by using the fabricated mould. The study is conducted in the form of two-layer pavement system. The pavement 
model layer is prepared as subgrade and sub-base with BC soil and sandy gravel soil respectively. The prepared fabricated 
mould is tested by using the Wheel Tracking Test (WTT) under moving traffic loading condition. This study concluded that 
the suitable placement position and the types of coir mats can be affect 
the suitable coir mats can effectively reduce the deformation, so that it can be used over the weak subgrade to improve the 
performance of the LVRs. 
 
Keywords: Coir mats, Reinforcement, Separation, Subgrade, Sub-base, WTT. 

 

 

1. Introduction  

The performance of the roads largely depends 
on the properties and types of soil for the 
construction pavement. The larger numbers of 
factors are affecting the service life and 
maintenance of the pavement. This includes the 
environmental factors, traffic loading, ageing and 

occupied in large area of the country. The BC soil 
subgrade poses several problems to the roads in 
the form of rutting, fatigue, reflecting, and uneven 
or undulation in pavement structure. In this case, 
particularly the replacement of subgrade soil or to 
stable the weak subgrade is necessary to provide 
the stable pavement. But due to local constraint, 
the adoptions of both the techniques are 
unsuitable. In a particular case, alternate, past 
construction and stable locally available materials 
become necessary in pavement engineering. In 
view of the above consideration, an alternate 
material such as geosynthetics are used in 
pavement application to provide the additional 
strength and improve the performance of the weak 
subgrade. The use of geosynthetics in pavement 
application have been starting form 
many of the studies were conducted on the 
pavement using the polymeric materials. Few of 

the studies were also adopted with natural 
geotextile in pavement application. The uses of 
geotextile in pavement application are gain 
governing promises entire the world, due to their 
function and easy installation process over the 
weak subgrade. The function of geotextile are 
reinforcement, separation, drainage and filtration 
help in settling the pavement, provide additional 
strength and improved the service life of the 
pavement. In view of the above associate problem 
and benefits with geotextile, an attempt is made in 
the laboratory to evaluate the performance of the 
coir mats and its benefits to the pavement by 
conducting WTT under moving load condition.  

The present study is conducted with the four 
types coir geotextile are coir composite (CC), 
geogrid + non-woven coir mat (GG+NWCM), 
woven coir mats (WCM) and non-woven coir mats 
to the reinforcement of weak subgrade for LVRs. 
The test was conducted using the fabricated mould 
size are 300mm x 300mm x 200mm and 300mm x 
300mm x 300mm. The samples are prepared in the 
fabricated mould with BC soil as subgrade and 
sandy gravel as sub-base soil (two-layer pavement 
section) with varying thickness of pavement layer 
as per the modified CBR test protocol. The sample 
was tested using the WTT apparatus under moving 
load condition.  



 
2  Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018  
 

2. Geosynthetics 

The problem of pavement generally associated 
with the strength of the subgrade and sub-base 
soil. The construction of pavement over the soft 
soil, clay soil, and silt soil poses several problems 
to the pavement, in the form of rutting and fatigue, 
reflection cracks and uneven surface of the 
pavement (Rao, 2000; Brian, 2001; Rama, 2010). 
This problem occurs due to its high swelling, 
shrinkage, settlement characteristic and also 
volume change behaviour of BC soil (Yang, 2007) 
during various seasons under the dry and wet 
condition. To prevent these problems, many of the 
conventional techniques were adopted and restrict 
the problem of pavement. But these conventional 
methods are not eco-friendly neither economical 
for the construction of pavement and also 
difficulties during the construction of pavement in 
the field such as mixing of soil, compaction etc. to 
overcome with this problem, geosynthetics are 
taken as alternate materials is used in pavement 
construction from the past four decades.  

During the past few decades, geosynthetics 
have gained universal attention across all over the 
world, the possible types of soil subgrade either to 
overcome the subgrade deficiency or enhance 
permanent life and performance (Al-Qadi et al 
2008; Jersey et al, 2012,; Khodaii et al, 2008 and 
Zornberg et al, 2009). The geotextile acts a tension 
member and reduce the deformation and the 
vertical stress over the subgrade (Giroud and 
Noiray, 1981) and improve the performance of the 
roads.  The maximum tension effect is available to 
decrease the bearing capacity of the pavement 
when the uses of woven and non-woven coir mats 
are placed over the interface (Babu, 2007). The 
presence of the geosynthetics layer in the 
pavement system increase the later system and 
stiffness of the base/sub-base material while 
reducing the vertical stress and deformation of the 
subgrade (Perkins, 1999) are reported. One of such 
applications can be in the unpaved road over soft 
subgrade where the rate of plastic deformation due 
to repeated traffic loads is faster during the initial 
stage and gets stabilized later (Fannin and 
Sigurdsson, 1996). Various investigators stress the 
high cost of geosynthetics and stringent 
environmental protection requirements make it 
important to explore alternative natural products 
to make the constructions cost-efficient and eco-
friendly (Sarsby, 2007; Chauhan, 2008). The study 
investigated that the polymeric geocell improves 
the performance of the unpaved roads over the 
poor subgrade, quarry dust shown the better 
performance than the other materials (Pokhaerl 
2011). To Studied the performance of the geogrid 
reinforcement, indicates that the use of 
Geosynthetics in pavement over the poor subgrade 

soil tends to reduce the Sub Base thickness with 
increasing traffic volume (Charles, 2014).  To 
addressing the problem of pavement, to prevent 
this problem this study examines the coir 
geotextile mats can effectively serve as 
reinforcement, separation, drainage materials over 
the weak subgrade soil for LVRs. The study is 
conducted under moving loading condition in the 
laboratory, to correlate laboratory study with the 
field study using the accelerated pavement test 
track (APT). 

3. Materials 

The subgrade soil consists of clay having a 
Liquid Limit (LL) of 58% and Plastic Limit (PL) of 
27%. The clay is classified as CH as per Indian 
Standards and had a specific gravity of 2.62. 
Optimum Moisture Content (OMC) and Maximum 
Dry Density (MDD) was obtained as 17% and 17 
kN/m3 respectively in standard Proctor test.  The 
soaked California Bearing Ratio (CBR) value 
obtained is 1 for CH soil.  

Table 1. The basic properties of the coir geotextile 

The Properties of the coir Values 

Length (mm) 15-30 

Density (g/cc) 1.14-1.41 

Breaking elongation (%) 27 

Diameter (mm) 0.1-1.5 

Specific Gravity 1.12 

Modulus of elasticity (GPa) 8.14 

Water soluble (%) 5.20 

 
Similarly, the sub-base materials are sandy 

gravel were used. The properties of these materials 
are Optimum Moisture Content (OMC=8.0), 
Maximum Dry Density (MDD= 18.7kN/m3), shear 
parameter (C=0and φ=31o). The soaked and un-
soaked California Bearing Ration (CBR) is 6 and 13 
are presented respectively. The four types of coir 
mats were used in the study. The properties of the 
coir geotextile mats are given in table1. The types 
of coir geotextile used in the study shown in the 
below Fig. 1. The notations of the coir geotextile as 
follow: CC=Coir Composite, WCM= Woven Coir 
Mat.  

The mechanism of coir geotextile mats over the 
weak subgrade as shown in Fig. 2. The conventional 
pavement load distribution characteristics and 
separation of two-layer material are shown. The 
Fig 2B shown the reinforcement and separation of 
layer material, without possibility of intermix with 
the composite mats.

 



 
Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018 3 

 

 
 

Fig. 1. Types of coir geotextile mats used in the study 

 
Similarly lower the reinforcement and 

improper mixing of two-layer material is given in 
Fig 2C. The CC and GG+NWCM significantly reduce 
the settlement and also effectively work to possess 
the separation function than the WCM.  The WCM 
gives the less reinforcement than the CC and 
GG+NWCM and also in sufficient to give the 
separation function due to its opening mesh size. 

4. Experimental Setup  

The Wheel Tracking Test apparatus (WTT) are 
used for this investigation with varying contact 
pressure of moving load to simulate the field 
condition. It was developed by British National Rail 

Road Research Institute (Generally used for 
measuring the plastic deformation of bituminous 
asphalt concrete). The WTT apparatus height of the 
loading lever has been raised using the fabricated 
angle sections. The fabricated angles are 
controlling the enable to the loading onto 
pavement model section. The maximum load 
applied on to the pavement has 55 Kg, through the 
moving wheel of diameter 200mm, width of 50mm 
made of solid rubber. To run the wheel over the 
model section three phase motor with 75kw, 400v 
power motor is used. The experimental setup is 
shown in Fig. 3. 

 

 
 

Fig.3. Experimental setup with the data accusation system 

 
Fig. 2. Mechanisms of Coir Geotextiles 

 

 



 
4  Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018  
 

5. Result and Conclusion  

In the laboratory, the model pavement layers 
were prepared as two-layer pavement system. The 
pavement layer was prepared as subgrade and sub-
base with and without placement of coir mats 
between the subgrade and sub-base layer 
(reinforcement and un-reinforcement of coir 
geotextile mats). The subgrade as a BC soil and the 
sub-base as a sandy gravel soil are prepared and 
compacted in the fabricated mould of size 
thickness as 200 mm. As shown in above Table 2 
the maximum and the minimum number of wheel 
passes are variable, the number of wheel passes 
depends on the position of the coir mats and also 
the types of the coir geotextile. The maximum 
number of wheel passes (800) at 40 mm rut depth 
was found at the H/4 position with reinforcement 
of CC. The varying thickness of subgrade  and sub-

base with and without reinforcement of coir mats 
along with rut depth and wheel passes also are 
given in Table 2 with sandy gravel sub-base soil.  

In the laboratory study, the placement of coir 
mats at H/2 position the number of wheel passes 
with sandy gravel sub-base soil and without 
provision of the coir mats. From the study it was 
observed that the higher repetition is occurs with 
(GG+NWCM) at H/4 position compared with other  
types of coir geotextile mats. It was also noticed 
that the performance of the coir mats are uniform 
due to placing of higher thickness of sub-base soil. 
The repetition were found at H/2 position is occurs 
due to the sub-base soil, the failure are notice in 
sub-base soil due to lower shear strength and CBR 
values. Fig. 3 shows the rut depth and a number of 
wheel passes at the H/2 position of sandy gravel 
soil.  

 
Table 2 Pavement Component Layers with Variable Thickness of Subgrade (BC) and Sub-Base (Sandy Gravel) with and 
without Coir Geotextile. 

 
S.NO  pavement model section with      

300 mm x300 mm x 200 mm 
Position of 
Coir Mats  

Absorb Rut 
depth (mm) 

Number of 
wheel pass 

1 BC-SG 
BC-SG-CC 
BC-SG-GG-NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 

H/2 

40.0 
40.0 
40.0 
40.0 
40.0 

280 
350 
190 
290 
150 

2 

3 

4 

5 

6 BC-SG 
BC-SG-CC 
BC-SG-GG+NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 

H/3 

40.0 
40.0 
40.0 
40.0 
40.0 

300 
390 
430 
350 
300 

7 

8 

9 

10 

11 BC-SG 
BC-SG-CC 
BC-SG-GG+NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 
H/4 

40.0 
40.0 
40.0 
40.0 
40.0 

290 
800 
650 
580 
270 

12 

13 

14 

15 

 

 
Fig. 3. Rut depth along with number of wheel passes at H/2 position coir mats. 

0 25 50 75 100 125 150 175 200 225 250 275 300 325 350

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

R
u

t 
D

e
p

th
 i

n
 m

m
 (

4
0
m

m
)

Number of Wheel Passes

 BC soil + sandy Gravel 

 BC soil + WCM + Sandy Gravel

 BC Soil + NWCM + sandy Gravel

 BC Soil + CC + Sandy gravel

 BC Soil + CC+NWCM + Sandy Gravel



 
Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018 5 

 

 
The provision of coir mats at H/3 position in 

between subgrade and sub-base shown the 
differentiate in number of wheel passes depth for 
same rut depth. The woven coir mats increase the 
rut depth due to the higher thickness of coir mat 
than the woven coir mat. The provided coir mats at 
H/3 position taken the maximum load than the H/2 
position with coir composite materials. The coir 
composite material possesses the reinforcement 
and separation functions to the subgrade and 
reduces the deformation of the pavement 
structure. The coir geotextile mats are ensured the 
multi-function in pavement application such as 
reinforcement, separation, and drainage (Ali khodii 
Imadi, 2009). The number of wheel passes and rut 
depth at H/3 position is showed in Fig. 4. 

 
Fig. 4. Rut depth and number of wheel passes at H/3 
position of SG soil 
 

The two-layer pavement model section was 
prepared with the incorporation of coir geotextile 
at the H/4 position in order to reduce the sub-base 
soil materials. During the laboratory study it seen 
that the higher repetition are found at H/4 position 
than the H/2 and H/3 position, the placement of 
coir mats at H/4 position performed as a 
reinforcement material than the H/2 and H/3 
position, and transferred the load towards the edge 
of the pavement. The placement of coir mats at H/4 
position with reducing the sub-base thickness is 

showed the better performance due to its tension 
membranes act immediately due to placing near to 
the tire load from the top of the sub-base. The rut 
depth and number of wheel passes at H/4 position 
is shown in Fig. 5. 

 
Fig. 5. Rut depth and Number of wheel passes at h/4 
position of SG soil 

 
The laboratory study is performed to evaluate 

the effectiveness of coir mats with fabricated 
mould of size 300mmx300x300mm.  the study 
were conducted as a two-layer pavement system 
with and without provision of coir mats at H/2, H/3 
and H/4 position in between subgrade and sub-
base layer tested by using the WTT apparatus. The 
deformation of fabricated mould are noted with 
respective their number of wheel passes. The 
placement of coir mats, rut depth along with the 
number of wheel passes are given in table 3.  

From the table 3 it was notice that the high 
number of repetition was found at H/2 position by 
using the CC and GG+NWCM coir geotextile with 
higher thickness of sub-base soil with same rut 
depth.  The lower number of wheel passses were 
noticed with reinforcement of NWCM at H/3 
position. the reinfoced with CC and GG+NWCM 
coir geotextile mats at H/3  position greatly 
reduced the deformation and sub-base thickness 
and increse the repetetion 1040 and 1160 
respectively. 

 
Table 3 Pavement Component Layers with Variable Thickness of Subgrade (BC) and Sub-Base (Sandy Gravel) with and 
without Coir Geotextile. 

S.NO 
pavement model section with      
300mmx300mmx300mm 

Position of 
Coir Mats 

Absorb Rut 
depth (mm) 

Number of 
wheel pass 

1 BC-SG 
BC-SG-CC 
BC-SG-GG+NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 

H/2 

40.0 
40.0 
40.0 
40.0 
40.0 

670 
1400 
1500 
948 
700 

2 

3 

4 

5 

6 BC-SG 
B-SG-CC 
BC-SG-GG+NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 

H/3 

40.0 
40.0 
40.0 
40.0 
40.0 

170 
420 
480 
356 
190 

7 

8 

9 

10 

0 25 50 75 100 125 150 175 200 225 250 275 300 325 350 375

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

R
u

t 
D

ep
th

 i
n

 m
m

 (
4
0
m

m
)

Number of Wheel Passes 

 BC soil + sandy Gravel 

 BC soil + WCM+ Sandy Gravel

 BC soil + NWCM + Sandy Gravel 

 BC soil + CC + Sandy Gravel 

 BC Soil + CC+NWCM + Sandy Gravel
0 50 100 150 200 250 300 350 400 450 500 550 600 650 700 750

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

Number of Wheel Passes

R
u

t 
d

ep
th

 i
n

 m
m

 (
4
0
m

m
)

 BC soil + sandy Gravel 

 BC soil + WCM+ Sandy Gravel

 BC soil + NWCM+ Sandy Gravel 

 BC soil + CC + Sandy Gravel 

 BC Soil + CC+NWCM + Sandy Gravel



 
6  Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018  
 

S.NO 
pavement model section with      
300mmx300mmx300mm 

Position of 
Coir Mats 

Absorb Rut 
depth (mm) 

Number of 
wheel pass 

11 BC-SG 
BC-SG-CC 
BC-SG-GG+NWCM 
BC-SG-WCM 
BC-SG-NWCM 

 
 

H/3 

40.0 
40.0 
40.0 
40.0 
40.0 

345 
1040 
1160 
490 
408 

12 

13 

14 

15 

 

 

 
Fig. 6. Rut depth and number of wheel passes at H/2 
position of SG soil. 
 

The un-reinforced pavement model layer 
system showed the lower repletion at H/3 position 
than the reinforced model layer, which is shown 
with block color trend line in fig. 6. The 
reinforcement of model layer with sandy gravel 
sub-base soil with at H/2 position showed the 
higher repetition than the H/3 and H/4 position. In 
this case, the sub-base soil thickness is increased 
than the other case such as H/3 and H/4 position. 
Due to this increased thickness of sub-base soil 
increase the repetition improved the performance 
of the pavement. The rut depth and the number of 
wheel passes with sandy gravel soil at H/2 position 
is shown in Fig. 6.  

 

 
Fig. 7 Rut depth and number of wheel passes at H/3 
position of SG soil. 

 
The provision of coir mats with lower strength 

of sub-base soil will causes failure pavement and 
reduce the performance of the coir geotextile and 
also the pavement. In this case, the placement of 
coir mat at H/3 position with the sandy gravel soil 

showed the lower repetition 170 with the un-
reinforcement model layer. The reinforcement 
with coir mats at H/3 position is also showed the 
less number of wheel passes 480 with GG+NWCM 
coir mats. It was found that the provision of coir 
geotextile mats at H/3 position with sandy gravel 
sub-base soil inappropriate to improve the 
performance of the pavement. The rut depth and 
number of wheel passes at H/3 position is shown 
in Fig. 7. 

 

 
Fig. 8. Rut depth and number of wheel passes at H/4 
position of SG soil. 

 
The reinforcement of pavement model-layer 

system with four type of coir mats at H/4 position 
having the better reinforcement than the H/3 
position with the sandy gravel sub-base soil. In this 
case the placed coir mats at H/4 position act as a 
tension member and the maximum load will take 
place by the coir mats. The thicknesses of coir mats 
also play key role to improve the load bearing 
capacity of the pavement. The higher the thickness 
of coir mats (CC, GG+NWCM, and NWCM) reduces 
the deformation. The thickness of coir mats gives 
the additional strength to the pavement, reduces 
the vertical deformation, help in slow setting of 
pavement with proper separation. The provision of 
coir mat at H/4 position, the rut depth and the 
number of wheel passes are shown in Fig. 8.  

The laboratory study was performed to 
determine the performance of the geotextile with 
varying thickness of fabricated mould and 
evaluated the effectiveness of coir mats. The 
application and its utilization in LVRs. The 
maximum numbers of wheel passes occur at the 
H/3 position with reinforcement of GG+NWCM. In 
this case, the woven coir geotextile mats act as a 

0 100 200 300 400 500 600 700 800 900 1000 1100 1200 1300

0

10

20

30

40

R
u

t 
d

e
p

th
 i

n
 m

m

Number of Wheel passes

 BC soil + sandy Gravel 

 BC soil + WCM + Sandy Gravel

 BC Soil + NWCM + sandy Gravel

 BC Soil + CC + Sandy gravel

 BC Soil + CC+NWCM + Sandy Gravel

0 100 200 300 400 500

0

10

20

30

40

R
u

t 
d

e
p

th
 i

n
 m

m

Number of Wheel Passes

 BC soil + sandy Gravel 

 BC soil + WCM + Sandy Gravel

 BC Soil + NWCM + sandy Gravel

 BC Soil + CC + Sandy gravel

 BC Soil + CC+NWCM + Sandy Gravel

0 50 100 150 200 250 300 350 400 450 500 550 600 650 700 750 800 850

0

10

20

30

40

R
u

t 
d

e
p

th
 i

n
 m

m

Number of Wheel Passes

 BC soil + sandy Gravel 

 BC soil + WCM + Sandy Gravel

 BC Soil + NWCM + sandy Gravel

 BC Soil + CC + Sandy gravel

 BC Soil + CC+NWCM + Sandy Gravel



 
Harinder, D & Shankar S./ JGEET Vol 03 No 01/2018 7 

 

reinforcement material and the non-woven mats 
purely act as separation material. When the non-
woven coir mats attached with the geogrid it gives 
the additional reinforcement to the pavement 
structure. In addition to this, the coir geotextile 
acts as a separation and drainage material over the 
subgrade. 

6. Conclusions  

The results of the study have demonstrated the 
potential of coir geotextile in LVRs over the weak 
subgrade. This paper reviewed the concept of 
utilization of coir geotextile and it composite mats 
for LVRs. 

Maximum repetitions are found with coir 
composite at H/2, H/3 and H/4 position in case of 
200mm thickness of the mould. In case of 300mm 
thickness of mould higher repetition are obtained 
with CC and GG+NWCM at H/2 position as 1400 
and 1500 respectively.   

The CC and GG+NWCM coir mat shown the 
better reinforcement at H/4 position in both cases. 
The CC mats more significant to gives the 
reinforcement and separation of function to 
pavement and improved the performance.  

The sub-base soil parameter such as C and ϕ (0 
and 31

0
) play a key role to place the geotextile 

irrespective of the thickness of sub-base soil.  The 
increase thickness of sandy gravel sub-base soil 
increase the repetition later its fails due to the 
improper shear strength.  

The NWCM mats are more significant in term of 
reinforcement and separation than the WCM. The 
higher thickness of coir mats (NWCM) more 
effecting to reduce the deformation over the weak 
subgrade.  
 

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Rama, Rao, M., and Srirama Rao, A. 2010. Swell-
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	1. Introduction
	2. Geosynthetics
	3. Materials
	4. Experimental Setup
	5. Result and Conclusion
	6. Conclusions
	7. References