IIUM Engineering Journal, Vol. 23, No. 2, 2022 Saparudin et al. 
https://doi.org/10.31436/iiumej.v23i2.2293 

IMPROVEMENT OF PROBLEMATIC SOIL USING 

CRUMB RUBBER TYRE 

NURAIN ASRIN SAPARUDIN1, NORHIDAYU KASIM1*, KAMARUDIN ABU TAIB2,

WAN NUR AIFA WAN AZAHAR1, NUR AISYAH KASIM3 AND MAISARAH ALI1 

1
Civil Engineering Department, International Islamic University of Malaysia, 

PO Box 10, 50728 Kuala Lumpur, Malaysia.  
2
Civil Engineering Department, National University of Malaysia, Selangor, Malaysia. 

3
Civil Engineering Department, MARA University of Technology, Selangor, Malaysia. 

*
Corresponding author: ayukasim@iium.edu.my

(Received: 16th January 2022; Accepted: 26th March 2022; Published on-line: 4th July 2022) 

ABSTRACT:  Construction on problematic soil that has low bearing capacity, low shear 

strength, high compressibility, and high water-content will interfere with the smooth 

construction process and will affect time and cost due to repetitive maintenance. Pavement 

built on problematic soil as its subgrade is exposed to pavement failures, such as fatigue 

cracking, longitudinal cracking, and pumping, owing to swelling or shrinkage due to 

moisture variation and differential settlement. Therefore, improvement of the ground 

needs to commence so as to improve its load bearing capacity, in order to sustain the load 

on top of it. Consequently, the main aim of this study is to determine the effectiveness of 

crumb tyre rubber mixed with soil samples as one of the soil stabilisation techniques and 

to establish the optimum usage percentage of crumb tyre rubber as a stabiliser. Clayey 

sand soil was mixed with 5%, 10% and 15% of crumb tyre rubber by weight of the soil 

sample and was tested for physical properties, such as particle size distribution and 

plasticity index. In obtaining the changes in strength, mixed clayey sand-crumb tyre rubber 

samples were subjected to compaction and California Bearing Ratio (CBR) tests. The 

results showed that the increment of crumb tyre rubber percentage as an additive, increased 

the CBR value and therefore enhanced the strength of the modified soil. However, the 

crumb tyre rubber stabiliser affected the optimum moisture content and maximum dry 

density of the modified samples by decreasing their values. The optimum percentage of 

crumb tyre rubber mixture was found to be 10% by weight at the end of this study. These 

findings indicate that the measured crumb tyre rubber is suitable for supporting the clayey 

sand soil for the subgrade of pavement construction. 

ABSTRAK: Pembinaan di atas tanah bermasalah yang mengandungi kapasiti galas rendah, 

kekuatan ricih rendah, kebolehmampatan tinggi dan kandungan air tinggi akan 

mengganggu kelancaran proses pembinaan dan akan menjejaskan kekangan masa dan 

wang akibat penyelenggaraan berulang. Jalan raya yang dibina di atas tanah yang 

bermasalah akan mengalami kegagalan turapan seperti keretakan, rekahan membujur dan 

pengepaman, disebabkan oleh subgrednya terdedah kepada pembengkakan atau 

pengecutan akibat perubahan kelembapan dan pemendapan berbeza. Oleh itu, penambah 

baikan tanah perlu dilakukan bagi mencapai kapasiti galas beban lebih baik untuk 

menampung beban di atasnya. Oleh itu, tujuan utama kajian ini adalah bagi menentukan 

keberkesanan serpihan tayar getah yang dicampur dengan sampel tanah sebagai salah satu 

teknik penstabilan tanah dan menentukan peratusan optimum penggunaan tayar getah 

sebagai penstabil. Tanah pasir liat sebagai bahan utama dalam kajian ini dicampur dengan 

5%, 10% dan 15% serbuk tayar getah mengikut berat sampel tanah dan telah diuji sifat 

fizikalnya, seperti taburan saiz zarah dan indeks keplastikan. Perubahan dalam kekuatan 

ditentukan dengan cara menggaul sebatian sampel tayar getah bersama pasir tanah liat dan 

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diuji dengan eksperimen pemadatan dan ujian Nisbah Bearing California (CBR). Dapatan 

kajian menunjukkan bahawa penambahan peratusan serbuk tayar getah sebagai bahan 

penstabil telah meningkatkan nilai CBR dan sekaligus meningkatkan kekuatan tanah yang 

diubah suai. Walau bagaimanapun, penstabil tayar getah mempengaruhi kandungan 

lembapan optimum dan ketumpatan kering maksimum sampel yang diubah suai dengan 

nilai berkurang. Pada akhir kajian ini, peratusan optimum bancuhan serbuk tayar getah 

yang diperolehi adalah sebanyak 10% berat sampel. Dapatan ini menunjukkan bahawa 

tayar getah remah adalah sesuai dalam menyokong tanah pasir liat bagi subgred 

pembinaan turapan. 

KEYWORDS:  California bearing ratio; crumb rubber tyre; ground improvement; 

problematic soil 

1. INTRODUCTION

In geotechnical work applications, the existing ground will normally form the

foundation of the building and road structure. Weak and poor ground conditions cause 

delays in completing the project and incur huge additional costs. The poor soil often consists 

of a soft type of soil, such as clay, silt, or peat soil, which have the possibility for differential 

settlement to occur and are prone to flooding. Ground improvement is important to 

overcome the poor performance of the site area in order to fulfil the project specification. 

One of the methods for the improvement of soil is adding a biopolymer mixture, such as 

rice husk ash, wood ash, crumb rubber tyre and banana fibre to the soil. Biopolymer 

mixtures are natural polymers created by living organisms and are viewed as 

environmentally friendly and reasonable materials. Therefore, numerous researchers have 

carried out research work related to the utilisation of biopolymer mixed with the soil to 

enhance the stability of the soil. Ample works have succeeded in their findings.  

The effectiveness of adding crumb tyre rubber has been found in some research works 

carried out by Banzibaganye [1]. Shredded rubber tyre with two types of sand and, as a 

result, the materials produced showed a decrease in weight, adequate stability, low 

settlement, better drainage, and the preservation of energy and resources. The utilisation of 

the stabiliser also enabled proper waste disposal and tyre management that subsequently led 

to a positive effect on the environment [1]. The use of crumb rubber as a stabiliser 

substantially lessened the burden of waste tyre disposal and encouraged the establishment 

of an economical method for soil stabilisation purposes [2]. Therefore, this initiative also 

contributed to the reduction of construction costs and would lead to a cleaner environment 

without worrying about environmental degradation due to the improper disposal of solid 

waste tyre. Rubber tyres posed serious negative effects on the environment, health and 

aesthetics due to the huge quantity of rubber tyre waste. These non-biodegradable materials 

are often left to pile up in disposal sites, and provide a conducive place for mosquito 

breeding, as well as posing a fire risk [3]. As a result, it is advantageous to investigate crumb 

tyre rubber, as soil stabiliser material because it is one of the options for converting waste 

tyres for beneficial use. 

According to Al-Neami [4], the specific gravity test, compaction test, direct shear test, 

and California Bearing Ratio (CBR) test were conducted to identify the properties of the 

mixed soil-crumb tyre rubber. As a result, when the percentage of crumb rubber increased, 

the specific gravity, dry density, and optimum content also decreased. However, the shear 

strength and CBR value increased. The author also mentioned that lateral earth stress on 

retaining walls was reduced when using the tyre chips as fill material [4]. Besides, Hambirao 

and Rakaraddi [5] stated that the compressive strength of mixed cement-crumb tyre rubber 

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increased from 74 kPa to 201 kPa for 2% cement replacement and 246 kPa and 328 kPa for 

4% and 5% cement replacement, respectively, by adding waste tyre rubber chips. The 

cement replaced by 5% of rubber tyres had the highest compressive strength. 

Ravichandran et al. [2] analysed the properties of mixed clay-crumb tyre rubber by 

carrying out a compaction test and CBR test. Based on the compaction test, increase in the 

percentage of crumb rubber resulted in a decrease of maximum dry density and optimum 

moisture content of the clay. However, the CBR value increased when the addition of crumb 

tyre rubber was added up to 10% [2]. Furthermore, Singh et al. [6] mentioned that the 

strength of soil increased with no effect on the strain when the percentage of crumb rubber 

was increased. The value of unconfined compressive strength increased for soil at 20% 

mixture of crumb rubber.   

Based on the presented literature, the objective of this research was to determine the 

effectiveness of crumb tyre rubber when blended with clayey sandy soil.  Generally, clayey 

sand attributes provide significant engineering properties and have high plasticity, 

cohesiveness, high water absorbency, high compressibility, and low shear strength, which 

makes the soil unsuitable for construction. The clayey sand properties were improved by 

the application of 5%, 10%, and 15% of the soil weight in each testing standard. Laboratory 

testing was performed to test the physical properties of soil samples, as well as to investigate 

the additive’s performance in improving the efficiency of soil samples. From the data 

collection and analysis, the optimal percentage design of crumb tyre rubber to be mixed 

with the soil samples in order to produce an excellent mixture proportion for practical 

purposes could be established. Additionally, the crumb tyre rubber mixtures were observed 

to be aligned with the Specification for Road Works (JKR/SPJ/2014) set by the Malaysian 

Public Works Department (PWD), whereby the recommendation for pavements in Traffic 

Class T2 until T5 is not to be less than 5%. While, for large traffic volume, such as Traffic 

Class T4 and T5, the required minimum subgrade strength of 12% CBR value should be 

ascertained [7].  

2. METHODOLOGY 

2.1  Desktop Study 

A desktop study was carried out to identify the best soil stabiliser and to select a suitable 

site to collect weak soil samples. The crumb tyre rubber was chosen as a soil stabiliser for 

this study because of its performance in terms of improving the properties of the soil sample, 

such as reducing the dry density, specific gravity, and optimum moisture content. This is 

due to the lightweight crumb rubber tyre properties and its ability to decrease the lateral 

earth pressure of retaining walls when it is used as a fill material [8,9]. Furthermore, Tiwari 

et al. [10] stated that the crumb tyre rubber had a partial gluey attribute that could stick the 

materials together for long-term hardiness. Meanwhile, Keerthi and Doodala [11] assumed 

that the flexibility of rubber tyres and their adaptability to nature, combined with the 

properties of difficult decomposition and flammability, drew the attention of geotechnical 

engineering researchers.   

2.2  Sample Collection and Preparation 

The soil samples collected for this study were weak ground soil with a soft texture and 

cohesive soil properties that primarily consisted of clay, clay loam, sandy clay loam, and so 

forth. The soil sample was collected from the Sungai Pusu riverbank at the International 

Islamic University Malaysia (IIUM), Gombak campus, as shown in Fig. 1.  

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Fig. 1: Location of soil sample collected. 

The crumb tyre rubber, which was processed and supplied by Yong Fong Rubber 

Industries Sdn Bhd in Port Klang, Selangor, was the other main material used in this study. 

Unwanted elements other than granular rubber were sorted and eliminated during the 

processing. The granular rubber was shredded into various sizes according to its functional 

ability. This research used 40 mesh sizes of crumb tyre rubber, as depicted in Fig. 2, to 

provide decent interlocking properties between the tyre rubber and soil sample. The crumb 

tyre rubber was added, consisting of 5%, 10%, and 15% by weight of samples for each 

testing standard.   

 

Fig. 2: 40 mesh of crumb tyre rubber. 

As the soil samples were taken from three different spots in the selected areas, the 

average result for each sample is considered to represent the type and properties of weak 

ground. Table 1 simplified the ratio of soil samples and crumb tyre rubber to be prepared 

for the experimental study. 

Table 1: Percentage of soil sample and crumb tyre rubber with sample label 

Soil percentage 

[%] 

Crumb tyre rubber 

percentage [%] 

Soil sample 

CS-Clayey sand 

100 0 CS-CR0 

95 5 CS-CR5 

90 10 CS-CR10 

85 15 CS-CR15 

2.3  Particle size distribution 

A particle size distribution test was carried out to determine the grading characteristics 

of soil samples with a range of different sizes and shapes. In this investigation, two methods 

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were used in finding the particle size distribution: sieve analysis and hydrometer test. 

Sieving analysis is commonly used to determine the particle size distribution of the coarse, 

large-sized particles, while hydrometer test is used for the finer size of particle that passes 

the 75 µm sieve. The results of this testing will be plotted on a particle size distribution 

curve to indicate the percentage of the finer and coarser particles within the soil sample. 

Sieve analysis was conducted in this study to find the distribution of particles larger 

than 75 µm or 0.0075 mm and it was performed for the three raw soil samples collected 

from three separate points. The mechanical shaker, sieve stack, electronic weighing balance, 

and prepared samples were important apparatus and materials in conducting the test. 

Prepared samples that had been oven-dried were poured into a series of sieve stacks in the 

mechanical shaker. The mechanical shaker was left operating for about 5 to 10 minutes to 

separate the soil particles into their appropriate sizes in each stacker. Retained soil on every 

stack was weighed and recorded to enable the particle size distribution graph to be plotted, 

which is the diameter of the particle versus the percentage of the passing particle. Sample 

preparation and test procedures for this sieve analysis complied with the requirements of the 

American Society for Testing and Materials (ASTM) C136 standard. 

A hydrometer test was conducted to determine the finer particle size distribution of soil 

that passed a 0.075 mm sieve. The hydrometer test is more effective when dealing with finer 

grain size of soil samples compared to sieve analysis. It is impracticable to design the sieving 

stack with such a small hole. This test was also conducted due to the presence of clay in the 

soil samples and the standard procedure of this test was based on the ASTM D7928 standard. 

In this study, prepared soil samples that passed a 0.075 mm sieve were selected, and about 

37.5 gm of the sample was mixed with distilled water in a graduated cylinder and allowed 

to suspend. The hydrometer reading was taken by observing the meniscus formed by the 

suspension and the hydrometer stems to the nearest 0.0001 according to the standard elapsed 

time reading schedule and the temperature reading was taken periodically. Moreover, the 

reading for zero correction and meniscus correction were performed to avoid systematic 

errors. The zero correction and meniscus correction for this test were 0.9980 and 0.0002, 

respectively. The results from this test were then averaged to understand the properties of 

the samples, as illustrated in the particle size distribution graph. Both results were combined 

and plotted on one graph of the particle size distribution curve. 

2.4  Atterberg Limits Test 

The Atterberg limits test was performed to describe the consistency and plasticity 

behaviour of the soil samples in which the soil changes between solid, semi-solid, plastic 

and liquid states. The liquid limit (LL) results and plastic limit (PL) values could be obtained 

from the test. The difference between both values resulted in the plasticity index (PI) value, 

which measured the plasticity properties of the soil sample and provided the soil samples 

classification. The procedure of this experiment precisely followed the requirements, as 

stipulated in the ASTM D4318 standard. 

The PL value is the measurement of soil water content at the boundary between the 

semi-solid state and plastic state. It was determined by rolling the soil sample into a thread 

of 3.2 mm diameter on a flat glass surface by hand without breaking the sample. 

Consequently, the soils were mixed with crumb tyre rubber, consisting of 0%, 5%, 10% and 

15% by weight of samples and underwent the process of rolling until the soil disintegrated 

under pressure and could not be moulded into a 3.2 mm diameter measurement. The 

completed rolled soil samples were placed in a container and weighed. Lastly, the water 

content was determined the next day after drying the samples in an oven at 105 ºC. 

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The LL test is to identify the ability of water content in the soil that changes the soil 

properties from plastic to liquid states. This test was measured using the Casagrande cup 

method. The samples were moistened with about 25 drops of water prior to laying them in 

the Casagrande cup and cutting the soil into a V-shaped line in the centre using flat grooving 

tools with a gauge. The mechanical Casagrande cup was raised and dropped from a height 

of 10 mm at the rate of two drops per second. The process was repeated until the cutting 

section joined at about 13 mm in length. The number of drop-offs required to connect the 

cutting edge should be counted, which should be between 15 and 35 drops. Connected 

samples were taken and weighed. Next, water content was obtained after drying the sample 

in the oven at 105 ºC for 18 to 24 hours. 

The PI measures the plasticity properties of the soil sample. The plasticity index value 

could be calculated from the difference between the LL index and PL index as stated in Eq. 

(1). 

  PI = LL - PL         (1) 

2.5  Proctor Compaction Test 

The Proctor compaction test is the procedure of densification of soil to decrease the air 

voids. In this present study, the test investigated the soil samples by mixing of crumb tyre 

rubber to identify its compaction attributes of the optimum moisture content and maximum 

dry density [12]. The standard procedure for this experiment was according to the ASTM 

D698 standard. The soil samples were thoroughly mixed with crumb tyre rubber consisting 

of 5%, 10%, and 15% by weight of the prepared soil samples, together with the calculated 

amount of water. The moist crumb tyre rubber-soil mixture was inserted into an empty 

mould in three layers. Uniformly distributed, 25 blows were imposed on the surface of each 

layer using a 2.6 kg rammer. Some of the compacted layers were extracted to test for the 

moisture content of the soil sample by oven-drying the soil sample overnight. 

Based on the data collected from the experiment, a chart was drawn between the water 

content and dry density to achieve maximum dry density and optimum water content. The 

findings can be used to develop test samples for the CBR test. 

2.6  California Bearing Ratio (CBR) Test 

The CBR test was performed to decide the CBR value by accomplishing a laboratory 

load penetration test, as specified in the ASTM D1883 standard procedure. The CBR value 

indicated the mechanical strength of the soil sample and crumb tyre rubber mixtures due to 

the applied pressure from a plunger on the top surface of the soil. A higher CBR value 

indicates harder soil that can withstand more load. 

In this research, prepared samples were taken at about 5 kg in weight for every sample 

and blended evenly with 0%, 5%, 10% and 15% of the crumb tyre rubber. An amount of 

water was added to the mixture according to the result obtained in the Proctor compaction 

test. The modified soil was then poured into a mould in five layers and each layer was 

compacted with 56 evenly distributed blows from a 4.89 kg hammer. The CBR is the 

proportion of force per unit area required to infiltrate a soil sample using a round hammer 

at a rate of 1.25 mm/min. The compacted modified soil in the mould was positioned on the 

CBR machine for data collection of the plunger force that the soil could bear.  

From the CBR results, a graph was produced. The percentage of crumb tyre rubber that 

best illustrated the effect of the added crumb tyre rubber on the soil was plotted against the 

CBR value in order to determine the ideal percentage of added crumb tyre rubber. The CBR 

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value was used as an index of soil strength and bearing capacity. Eq. (2) was used to 

calculate the CBR value. 

 CBR(%) =
load carried by specimen

load carried by standard specimen
x100    (2) 

     where, 

  Load carried by standard specimen: 

  For 2.5 mm penetration = 13.2 kN 

  For 5.0 mm penetration = 20 kN 

3.   RESULTS AND DISCUSSIONS 

The soil samples collected from the riverside of Sungai Pusu were mixed with crumb 

tyre rubber with different percentages by weight (0%, 5%, 10%, and 15%) and were tested 

in several experiments based on a standard procedure. Before mixing, the weights of the soil 

sample and crumb rubber tyre were calculated in order to prepare for the soil-rubber tyre 

mix proportion that was utilised in the sieve analysis, hydrometer test, Atterberg limits, 

Standard Proctor compaction, and CBR tests. The goal of the investigation was to verify the 

effectiveness of crumb tyre rubber as soil sample stabilisers. 

3.1  Particle Size Distribution 

Before determining the result of the particle size distribution percentage, the three 

samples collected from the chosen areas were subjected to two tests, which were the sieve 

analysis and the hydrometer test. The results from the two experiments were combined to 

plot the particle size distribution graph, as mentioned in the previous chapter. From the 

curve, the dissemination percentage of the particles could be divided into four categories: 

gravel, sand, silt, and clay. The particle size distribution graph for the parent soil is shown 

in Fig. 3. 

 

Fig. 3: Particle size distribution graph. 

The particle size percentage of each category was tabulated in Table 2. Table 2 clearly 

showed that the highest particle percentage was sand (84.54%), followed by clay, gravel 

and silt, which were 6.99%, 5.51% and 2.96%, respectively. 

 

 

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Table 2: Percentage of particle size distribution 

Type of particle Percentage from total amount [%] 

Gravel (>2 mm) 5.51 

Sand (0.06 - 2 mm) 84.54 

Silt (0.002 - 0.06 mm) 2.96 

Clay (<0.002 mm) 6.99 

Based on the particle distribution graph, uniformity coefficient, Cu and coefficient of 

gradation, Cc for the soil samples were calculated and resulted in values of 5.81 and 0.86, 

respectively. As the sample retained more than 50% of the No. 200 sieve, the soil was 

categorised as coarse-grain clayey sand according to the Unified Soil Classification System 

(UCSS) (ASTM Test Designation D2487). The values of Cu and Cc indicated that the soil 

sample was poorly graded sand and prone to settlement and had problematic water-clog 

areas. In order to have good interlocking between poorly graded soil and crumb tyre rubber, 

the waste tyre had to endure the mechanical machine grinding process and passing through 

standard size to achieve finer and more uniform particles of the crumb tyre rubber [4]. 

3.2  Atterberg Limits Test 

The LL test and PL test were conducted in order to determine the plasticity index of the 

soil samples and crumb tyre rubber mixtures. The Atterberg limits test results for the soil 

samples are illustrated in Table 3. 

Table 3: Atterberg limit results 

Soil sample Liquid limit 

[%] 

Plastic limit 

[%] 

Plasticity 

Index 

CS-CR0 63.9 41.4 22.5 

CS-CR5 44.2 27.7 18.6 

CS-CR10 44.0 26.5 17.5 

CS-CR15 25.5 9.8 15.7 

Based on the results shown in Table 3, analysis was performed on the soil characteristic 

identification related to the plasticity traits. It was identified that CS-CR0 was characterised 

as clay with high plasticity (CH), while the modified soil that contained 5% and 10% of 

crumb tyre rubber was found to be clay with intermediate plasticity (CI), followed by CS-

CR15, which was identified as clay with low plasticity (CL). The results showed that the 

soil-crumb tyre rubber combination exhibited a lower plasticity state and a higher add-on 

amount of the additive might lead to an enhanced shear strength of the altered soil compared 

to the basic soil. Overall, it could be seen that LL, PL and PI were all increased as the 

percentage of crumb tyre rubber content increased. The results corresponded with a previous 

study by Sarvade and Shet [13]. This pattern revealed that the properties of the crumb rubber 

tyre, as an additive contributed positively to the changes in the consistency of the soil with 

varying moisture content. 

3.3  Standard Proctor Compaction Test 

The compaction test was carried out for the soil samples supplemented by a crumb tyre 

rubber of size 40 mesh in different mix percentages to determine and compare the optimum 

moisture content (OMC) and maximum dry density (MDD). Heavy tamping using a rammer 

with a weight of 2.6 kg applied with 25 blows was distributed over the surface of each layer. 

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The outcome of the Standard Proctor compaction test for the samples were tabulated in 

Table 4 according to the percentage of the additives mix.  

Table 4: Result of compaction test 

Soil sample CS-CR0 CS-CR5 CS-CR10 CS-CR15 

Optimum moisture 

content [%] 

16.18 17.32 17.13 14.74 

Maximum dry 

density [Mg/m3] 

1.64 1.63 1.54 1.57 

Figures 4 and 5 define the OMC and MDD graph of the sample with their percentages 

of modification, respectively. The pattern showed an increasing trend in moisture content 

up to a particular point and began to decrease thereafter. 

 
Fig. 4: Optimum moisture content graph. 

Figure 4 showed the trend of moisture content increasing until 7% of the crumb tyre 

rubber and decreasing afterwards. However, there was a difference between the percentage 

of OMC at 5% and 10% crumb tyre rubber, which were recorded at 17.32% and 17.13%, 

respectively. Further addition of stabiliser to the samples showed a decline in OMC until 

the lowest value was at about 14.74%, similar to the results obtained by Vasavi et al. [14]. 

This was due to the excessive amount of rubber that caused a disruption and led to a 

disturbance in the mixture's ability to absorb [15]. 

The results of the MDD were clarified in Fig. 5, whereby generally the curve 

demonstrated a declining trend with the addition of more crumb tyre rubber. The decrease 

might be due to the benefit possessed by crumb tyre rubber as a fine and light material 

capable of holding 1.02 to 1.27 of specific gravity [16]. Furthermore, Mohammed et al. [3] 

supported the decrease of the crumb tyre rubber dry density of the modified soil mainly due 

to the density of the crumb tyre rubber that was found to be lower than that of raw dune 

sand [3] and it was considered as a lightweight fill material based on its nature [8]. This 

argument was bolstered by Ravichandran et al. [2], who found that the lower specific gravity 

of crumb rubber led to a low maximum dry density. However, the CS-CR15 sample had 

slightly increased the dry density to about 0.03 Mg/m3.Overall, the maximum dry density 

value of the modified sand-crumb tyre rubber did not show significant differences from the 

original soil. The differences were in the range of 1.54 to 1.64 Mg/m3. 

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Fig. 5: Maximum dry density graph. 

 

Fig. 6: Compaction curve. 

Figure 6 illustrates the compaction curve that consists of the dry density-moisture 

content relationship with the altered percentage of crumb tyre rubber at 0%, 5%, 10%, and 

15%. Overall, there was a substantial increase in dry density along with an increase in 

moisture content of about 16% and the graph declined subsequently. Both parameters of 

MDD and OMC revealed minimal differences, with the values varying from 1.68 Mg/m3 to 

1.77 Mg/m3 and 15.09% to 17.45%, respectively. Additionally, the graph displayed that by 

adding the crumb tyre rubber, the maximum dry density of the modified soil was lower 

compared to the parent clayey sand sample. This was because the weight of the crumb tyre 

rubber, which was originally known to be light, affected the density of the modified soil. 

3.4  California Bearing Ratio (CBR) Test 

The results for force on the plunger versus penetration of the CBR test for the clayey 

sand sample with the addition of 0%, 5%, 10%, and 15% crumb tyre rubber is illustrated in 

Fig. 7. The figure demonstrates that the origin sample, as well as the modified sample 

showed a mounting curve through the experiments. It could be seen from the graph that the 

most obvious positive rising trend was the CS-CR10 sample which had 10% of the crumb 

tyre rubber. This positive trend was also proven by Al-Neami [4], who stressed that 

generally, the curve for reinforced sand samples increased as the percentage of crumb rubber 

and soil increased because the mixture tends to create bonds between them, leading to the 

fact that the modified mixture was able to sustain more load compared to raw soil. 

Moreover, the stress applied over the soil surface was dispersed and distributed evenly 

towards the crumb tyre rubber and the soil. Increasing the crumb tyre rubber quantities 

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resulted in less stress being held within the soil. Furthermore, Al-Bared et al. [17] agreed in 

their studies that soil samples supplemented with crumb tyre rubber could enhance the CBR 

value and be directed towards the reduction of pavement thickness and project costs. 

 

Fig. 7: California Bearing Ratio result. 

 

Fig. 8: Effect of percentage of crumb rubber added on CBR value. 

To sum up the graph of crumb tyre rubber -soil mixtures with the CBR value 

relationship, it could clearly be seen that the rising trend in CBR value for the clayey sand 

samples was steadily persistent up to 10% of the crumb tyre rubber mixture, as shown in 

Fig. 8. The increase in the trend of CBR value was due to the small difference between the 

sizes of soil and the sizes of rubber crumb that produced a decent interlocking between them, 

and thus, could fill in the air void. Consequently, this factor resulted in the higher strength 

of the soil to withstand an applied load. However, the upward trend started to decrease after 

further addition of crumb rubber. According to Juliana et al. [7], the fall pattern was due to 

the presence of higher crumb rubber content that might cause greater compressibility in the 

mixture. The highest CBR value achieved was approximately 17 at 10% of crumb rubber 

addition, while the lowest CBR value belonged to the raw clayey sand sample, which was 

at 6. This showed that all mixtures (CS-CR0, CS-CR5, CS-CR10 and CS-CR15) had 

satisfied the minimum condition of PWD‘s standard. 

Furthermore, from the above illustration, it could be stated that the optimum percentage 

of adding rubber crumb to the soil was 10% by weight in order to improve the weak soil. 

This was because the highest peak of each sample was achieved when the addition of 10% 

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crumb tyre rubber to the samples was accomplished by the weight of the samples in each 

testing standard. 

4.   CONCLUSION 

This study was conducted to design the most suitable and ultimate functional samples 

out of a mixture of crumb tyre rubber stabiliser and clayey sand. Crumb tyre rubber was 

expected to improve the problematic soil sample in terms of their strength properties. The 

type of collected soil samples was coarse-grained clayey sand, which was classified as 

poorly graded sand. The sample was found to be unsuitable for construction purposes due 

to its poorly graded soil properties, whereby the soil was lacking in terms of interlocking 

capabilities between the particles. Besides, clayey sand, as well as poorly graded soil have 

higher compressibility and permeability compared to well-graded soil. Based on the tested 

results of crumb tyre rubber -soil sample mixtures, the following conclusions could be 

drawn. The addition of 0%, 5%, 10% and 15% of crumb rubber tyre to the soil samples 

showed the increasing trend in the OMC of up to 7% and decreased afterwards, while MDD 

of the modified soil remained moderately declined. This was due to the lightweight 

properties of the crumb tyre rubber that filled the void between the soil particles. 

By referring to the California bearing ratio test, the graph of CBR value versus 

percentage addition of crumb tyre rubber indicated that the addition of the crumb tyre rubber 

tended to increase the CBR value, as well as cause the strength of the soil to increase. 

However, as the CBR value increased up to 10% of the crumb tyre rubber added to the soil, 

and further addition until 15% of the crumb rubber tyre showed a downward trend in the 

CBR value. It could be concluded that the optimum percentage usage of crumb rubber tyre 

added to the soil sample for soil stabiliser purposes was 10%. Importantly, the CBR value 

for all the mixtures fulfilled the minimum PWD‘s requirement (JKR/SPJ/2014) of 5% CBR 

value. 

For further investigations, more experiments and testing could be carried out to 

determine the efficacy of the crumb tyre rubber and soil mixture, such as the pycnometer 

test, shrinkage limit test, oedometer test, direct shear test, etc., besides using other stabilising 

agents for the mixing materials. 

ACKNOWLEDGEMENT 

The research was carried out under the Fundamental Research Grant Scheme (FRGS-

RACER) project RACER/1/2019/TK01/UIAM//1 provided by the Ministry of Higher 

Education, Malaysia. The authors wish to thank all the staff of the International Islamic 

University Malaysia Research Management Centre and Yong Fong Rubber Industries Sdn 

Bhd, Pelabuhan Klang, Selangor for providing the soil samples and crumb rubber tyre, 

respectively. 

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