The Effect of Crumb Rubber Substitution and Utilization of Local
Materials Laterite on Asphalt Concrete - Binder Course
Karminto
1a
, Ashadi Putrawirawan
1b
, Ibayasid
1c
and Sakti Adji Adisasmita
2d
1
Civil Engineering, Samarinda State of Polytechnic, Jln. Ciptomangungkusumo, Samarinda, Indonesia
2
Civil Engineering, Hasanudin University, Jln. Perintis Kemerdekaan No. KM. 10, Makassar, Indonesia
Keywords: Crumb Rubber, Laterite Stone, Asphalt Concrete, Marshall, Optimum Asphalt Content.
Abstract: The opportunity to use crumb rubber for pavement layers is still minimal, while the waste generated is
increasing, one way to reduce and utilize the tire material is to add asphalt-concrete mixture - binder course
(AC-BC). To increase flexibility, one of them is by using Crumb Rubber from waste tires that pass the No.
filter. 4 (4.75 mm) as additive. This study aims to determine the effect of Crumb Rubber as a material and
the use of laterite stone as a substitute for coarse aggregate on asphalt mixtures based on the properties of
the Marshall mixture. In this study, Marshall test specimens were made with variations of laterite stone as a
substitute for coarse aggregate at a level of 50% and the addition of Crumb Rubber at a level of 1%, 2%, 3%
and the planned asphalt content was 4%, 4,5%, 5%, 5.5%, and 6% which will then determine the optimum
asphalt content, stability, flow, VIM, VMA, VFA and MQ in the Asphalt Concrete – Binder Course. Based
on the research results obtained. The best variation isthe use of Crumb Rubber as an additive to Asphalt
Concrete – Binder Course by 1% and the addition of Crumb Rubber and the value of Optimum Asphalt
Content is 5.58% with Marshall characteristics including stability values of 1082 kg, flow 2.91%, VIM
4.83%, VMA 14.82%, VFA 65.80% and MQ 438 kg/mm. The results showed that the mixture of AC-BC
with a substitute for coarse aggregate using 50% laterite stone and Crumb Rubber the requirements for the
Asphalt Concrete - Binder Course.
a
https://orcid.org/0000-0002-9373-2942
b
https://orcid.org/0000-0001-6163-4187
c
https://orcid.org/0000-0001-7805-0380
d
https://orcid.org/0000-0003-1732-4098
1 INTRODUCTION
Asphalt pavement is a large road leading through
one place to another, specifically with a prepared
roof that can be used by vehicles. Roads play a
significant role with in social and economic growth
of a nation (Alakhali, Yahya, 2021). Use of
materials for road pavement construction in East
Kalimantan is still very dependent on Palu stone and
sand, so that road construction costs in East
Kalimantan are expensive (Putrawirawan, Ibayasid,
2020). So it is necessary to makeaneffortsothat
howto utilize local natural resources in East
Kalimantan as an alternative material for making
asphalt. One of the natural resources owned by East
Kalimantan is Laterite Stone.
The purpose of this research is to find out how
much influence the use of laterite stone and Crumb
Rubber has on Masrhall characteristics in the
Asphalt Concrete - Binder Coarse (AC-BC). To
determine the optimum asphalt content (KAO) in the
Asphalt Concrete-Binder Coarse (AC-BC). Use of
laterite as a substitute for coarse aggregate on AC-
BC maximum of 50% and Optimum Asphalt
Content value of 5.48% with Marshall
characteristics including stability values 1980 kg,
flow 3.95%, VIM 4.96%, VMA 16.42%, VFA
72.07% and MQ 510.63 kg/mm. The results showed
that the mixture of AC-BC with a substitute for
coarse aggregate using laterite met the requirements
for Asphalt Concrete – Binder Course (AC-BC)
(Putrawirawan, Tristo, Ibayasid, 2019). The addition
of 0.75% of Activated Crumb Rubber (ACR)
Karminto, ., Putrawirawan, A., Ibayasid, . and Adisasmita, S.
The Effect of Crumb Rubber Substitution and Utilization of Local Materials Laterite on Asphalt Concrete - Binder Course.
DOI: 10.5220/0010940200003260
In Proceedings of the 4th Inter national Conference on Applied Science and Technology on Engineering Science (iCAST-ES 2021), pages 69-75
ISBN: 978-989-758-615-6; ISSN: 2975-8246
Copyright
c
2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
69
additive, improved the resistance to fatigue cracking
and rutting about 20% and 32% respectively but
susceptible to stripping, even though the addition of
ACR additive showed insignificant improvement
between ACR and control mixture in Marshall
properties, but based on the mechanical
performance, the ACR additive eligible to apply and
provide the same or better performance compared to
conventional and non-ACR mixtures (Kamarudin et
al, 2020). The recycled aged Crumb Rubber
Modified (CRM) mixtures (with 15%, 25%, and
35% rubberized RAP) can satisfy the current
Superpave mixture requirements, including moisture
susceptibility and rutting resistance, and in general,
there was no significant difference between the
control and the recycled CRM mixtures for the
properties evaluated (Lee J, S et al, 2008).
2 MATERIALANDMETHOD
2.1 Asphalt Concrete – Binder Course
(AC-BC)
Asphalt Concrete – Binder Course (AC – BC) is a
pavement layer located below the wear layer
(Wearing Course) and above the foundation layer
(Base Course). This layer is not directly related to
the weather, but must have sufficient thickness and
adhesiveness to reduce stress/strain due to traffic
loads which will be transmitted to the lower layers,
namely Base course and Sub grade (Subgrade).
2.2 Ingredient of Asphalt Concrete -
Binder Course (AC-BC)
Flexible pavement consists of coarse aggregate, fine
aggregate, sand, filler and additives. However, the
materials used must first be tested according to
standards and meet the specifications set by Bina
Marga. This is in order to obtain pavement that has
good quality and is in accordance with the plan.
2.3 Laterite Stone
Laterite stones is a hardened soil formed naturally
resembling rock from the deposition of substances
such as nickel and iron. Laterite itself is naturally
formed in which there are many elements and
nutrients that make up the soil layer hardened like
stone. The term Lateriteis derived from the Latin
word - later, meaning brick. It was first used in 1807
by Buchanan to describe a red iron-rich material
found in the southern parts of India. Laterites are
widely distributed throughout the world in the
regions with high rainfall, but especially in the inter-
tropical regions of Africa, Australia, India, South-
East Asia and South America, where they generally
occur just below the surface of grasslands or forest
clearings. Alexander et al., (1962) (West,
Jenbarimiema, Nyebuchi, & Azeruibe, 2020)
compiled the physical, chemical and morphological
definitions fromvarious researchers and then
redefined laterite as a highly weathered material,
rich in secondary oxides of iron, aluminum, or both,
it is nearly void of bases and primary silicates, but it
may contain large amounts of quartz and kaolinite,
and it is either hard or capable of hardening on
exposure to wetting and drying (West,
Jenbarimiema, Nyebuchi, & Azeruibe, 2020).
Figure 1: Laterite stone.
2.4 Crumb Rubber
Crumb rubber is made of tyres or vulcanized rubber.
Tyres are basically formed by combining natural and
synthetic rubber and carbon black. The tyres are
shredded into smaller particle sizes to remove wire
and fabric reinforcement. The actual chemical
composition of crumb rubber derived from tyres is
difficult to assess because of the large variation in
tyre types produced by different manufacturers.
However, crumb rubber is typically referenced by its
size together with basic compositions such as natural
and synthetic rubber, steel, fibre and carbon black
(Hassan et al, 2015). Crumb Rubber is an
environmentally friendly recycled rubber product
because it is obtained from recycling waste made
from used tire rubber. Crumb Rubber has advantages
such as good adhesion, sturdy, durable and long-
lasting, more resistant to gasoline and lubricating oil
and resistant to weather. Crumb Rubber can be
obtained by recycling ambient grinding. Ambient
grinding is a process method where used tires are
grated, ground and processed at room temperature.
iCAST-ES 2021 - International Conference on Applied Science and Technology on Engineering Science
70
The main ingredients of Crumb Rubber generally
come from waste tire rubber (Julián, 2005).
Figure 2: Crumb Rubber.
Chemical content Crumb Rubber has the
constituent elements shown in Table 1.
Table 1: Chemical content Crumb Rubber.
Material Com
p
otition (%)
Rubbe
r
48
Karbon blac
k
22
Lo
g
a
m
15
Tekstil 5
Zinc Oksida 1
Sulfu
r
1
AditiveMaterial 8
Crumb rubber is produced through refining the scrap
tires of cars, trucks, busses and other transporter tires,
steel and synthetic fibers, which account for
approximately 40 percent of the structure of the tyres
are extracted via a magnetic system and an air gravity
system. Crumb rubber is an efficient material to be
used as an additive to asphalt binder since it
contributes in better performance by increasing the
strength and stiffness of pavement and can be used for
future development (Alakhali, Yahya, 2021). Crumb
rubbers (CRs) have been proposed as pavement
components because they are waste materials.
Previous studies have attempted to find alternative
material in pavement construction that act as additives
or property modifier (Hamad, S, Jaya, 2014). The hot
mix asphalt modification process in which crumb
rubber is initially mixed with mineral aggregate
before addition of a binder is known as dry process.
This process has the advantage of using conventional
blends and, at least in principle, that there is no limit
to the content of the rubber introduced (Silvrano, et al,
2005). The dimension of crumb rubber particles used
in the dry process is generally bigger than for those
used in the wet process. Besides, in the dry process,
the crumb rubber substitutes part of the aggregate
mineral (Silvrano, et al, 2005). The CRDryprocess is
the method wherethe CR particles are partially
replaced with the portion of fine aggregates in the
mix. In addition, there are several treated dry rubber
technologies where the crumb rubber particles are
pre-mixed with low viscosity petroleum-based
products or aromatic oils compatible with the lighter
fractions of asphalt binder. Treated rubber
technologies are also integrated in to mixture as a
CRDry process (Salih, K, M. Emin, K., 2017).
3 RESULTS AND DISCUSSION
3.1 Result of Testing Material
Based on the results of testing in the asphalt testing
laboratory, the values of specific gravity,
penetration, softening point and ductility meet the
requirements of asphalt, then the results of testing
the physical characteristics of aggregates that meet
the requirements of technical specifications can be
seen in the following tables.
Table 2: The result of Asphalt properties.
No. Type of testing Requirement Result
1
Penetration, 25
o
C
60-70 67.7
2
Softening point (
o
C)
Min. 48 52.25
3
Ductility 25
o
C (cm)
Min. 100 126.7
4 Spcific Ggrafity Mi. 1 1.040
Table 3: The results of testing the specific gravity and
absorption of coarse aggregate.
Type of testing Requirement Result
Dry bulk density Min. 2.5 2.63
Saturated surface dry (SSD) Min. 2.5 2.68
Apparentdensity Min. 2.5 2.75
Absorption Maks. 3% 1.58
Abration Maks. 40% 20.63
Table 4: The results of testing the specific gravity and
absorption of medium aggregate.
Type of testing Requirement Result
Dry bulk density Min. 2.5 2.55
Saturated surface dry (SSD) Min. 2.5 2.62
Apparentdensity Min. 2.5 2.74
Absorption Maks. 3% 2.69
The Effect of Crumb Rubber Substitution and Utilization of Local Materials Laterite on Asphalt Concrete - Binder Course
71
Table 5: The results of testing the specific gravity and
absorption of Filler.
Type of testing Requirement Result
Dry bulk density Min. 2.5 2.52
Saturated surface dry (SSD) Min. 2.5 2.54
Apparentdensity Min. 2.5 2.58
Absorption Maks. 3% 1.01
Table 6: The results of testing the specific gravity and
absorption of Laterite stone.
Type of testing Requirement Result
Dry bulk density Min. 2.5 2.54
Saturated surface dry (SSD) Min. 2.5 2.59
Apparentdensity Min. 2.5 2.67
Absorption Maks. 3% 2.93
Abration Maks. 40% 29.63
All material tests which include asphalt, coarse
aggregate, fine aggregate, filler and laterite stone
have met the requirements of the 2018 Bina Marga
technical specifications.
3.2 Marshall Characteristic
3.2.1 Relation of Crumb Rubber with
Stability
The average value of the AC-BC in the mixture with
crumb rubber content of 0%, 1%, 2%, 3%
respectively was1980kg,1082kg,1004kg,1002kg.
Figure 3: Graph of the relationship between stability and
variations in use of Crumb Rubber.
The stability value has decreased. The lowest
stability value was obtained at 1% crumb rubber,
which was 1082 kg and the highest value was
obtained at 0% crumb rubber, which was 1980 kg.
However, after that the stability value decreased at
levels of 1% to 3%. The decrease in stability was
caused by the addition of crumb rubber content in
the mixture which resulted in a lack of interlocking
between the aggregates and crumb rubber, causing
the asphalt to no longer effectively cover the
aggregates which could lead to a decrease in the
stability. Pavement layers with a stability of less
than 800 kg will easily experience rutting, because
the pavement is soft so it is less able to support the
load.
3.2.2 Relation of Crumb Rubber with Flow
The average flow value of the AC-BC mixture in the
mixture with crumb rubber content of 0%, 1%, 2%,
3%, respectively, was 3.90 mm, 2.91 mm, 3.12 mm,
3.98 mm.
Figure 4: Graph of the relationship between Flow and
variations in use of Crumb rubber.
Flow value decreased and increased. The highest
flow value was obtained at a content of 3% crumb
rubber, which was 3.98 mm, but all crumb rubber
content still meet the requirements of the 2018
General Specification, which was a minimum of 2.0
mm. The increase in the average flow value can be
caused by the increasing amount of asphalt required
so that the properties of the mixture are plastic and
easily deformed when loaded.
3.2.3 Relation of Crumb Rubber with Void
in Mix (VIM)
VIM value decreased or increased. This is due to the
increasing content of laterite stone causing the
asphalt to not optimally fill the voids in the
aggregate because it has larger voids and the less
asphalt content is filled, making the mixture less
dense because the aggregates are interconnected and
break due to imperfect compaction. The value of
VIM in all variations of crumb rubber content still
meets the minimum requirements of 3% and a
maximum of 5%.
iCAST-ES 2021 - International Conference on Applied Science and Technology on Engineering Science
72
Figure 5: Graph of the relationship between VIM and
variations in use of Crumb rubber.
Figure 5 shows that the VIM value decreased at 4%
plastic bag content. This is because the increasing
content of plastic sacks causes asphalt to fill voids in
the aggregate because it has smaller voids and the
more asphalt content filled in the mixture can make
the mixture denser. The VIM value in all variations
of the plastic bag content still meets the minimum
requirements of 3% and a maximum of 5%
3.2.4 Relation of Crumb Rubber with Void
in Mineral Agregat (VMA)
Mixing crumb rubber as an added ingredient causes
the VMA value to decrease. The value of VMA on
the use of crumb rubber 0%, 1%, 2%, 3%, decreased
by 15.80%, 14.82%, 14.37%, 13.98%. Aggregates
form a thick blanket, as a result, the voids between
aggregates are getting smaller.
Figure 6: Graph of the relationship between VMA and
variations in use of Crumb Rubber.
The decrease in VMA value was due to the increase
in crumb rubber content so that the asphalt covering
the aggregate formed a thick blanket, as a result the
voids between the aggregates were getting smaller.
3.2.5 Relation of Crumb Rubber with Void
Filled Agregat (VFA)
Void filled with asphalt (VFA) value decreased and
increased. Values at levels of 0%, 1%, 2%, 3%
crumb rubber respectively are 72.00%, 65.80%,
72.63%, 77.80%. VFA value for each laterite stone
content still meets the general specifications for
2018 which is at least 65%. VFA value that is too
high will cause bleeding.
Figure 7: Graph of the relationship between VFA and
variations in use of Crumb rubber.
VFA value that is too small will cause the mixture to
be less water and airtight. This will cause the asphalt
film layer to become thin so that the pavement will
crack easily when it receives a load so that the
asphalt mixture is easily oxidized.
3.2.6 Relation of Crumb Rubber with
Marshall Quotient (MQ)
Figure 8: Graph of the relationship between MQ and
variations in use of plastic bags.
Along with a decrease in stability causes a decrease
in the valueof MQ and causesan increase in thevalue
of flow. As a result of the decrease in the MQ value,
the mixture will become less brittle and soft when
the mixture will be increased the amount of
compaction.
The Effect of Crumb Rubber Substitution and Utilization of Local Materials Laterite on Asphalt Concrete - Binder Course
73
The use of crumb rubber resulted in the Marshall
Quotient value decreased.
3.2.7 Relation of Crumb Rubber with
Optimum Asphalt Content (OAC)
The optimum asphalt content of each proportion of
the use of crumb rubber as an additive can be seen in
Table 4.28. From the results of the Marshall test, the
optimum asphalt content for each variation was
5.48% for 0% crumb rubber; 5.58% for 1% crumb
rubber; 5.73% for 2% crumb rubber; 5.87% for 3%
crumb rubber.
Figure 9: Graph of the relationship between Optimum
Asphalt Content (OAC) and variations in use of Crumb
rubber.
The effect of using crumb rubber as an additive in
the mixture will increase the value of the optimum
asphalt content in the AC-BC asphalt mixture.
Judging from the OAC value which continues to
show an increase in the OAC value. This means that
the use of crumb rubber greatly affects the value of
KAO, the more use of crumb rubber as an added
material, the value of the optimum asphalt content
will also be higherfor each variation of the content
of crumb rubber which can be seen in Table 7.
Table 7: Value of Characteristic Marshall Asphalt
Concrete – Binder Course.
Crumb Rubber (%)
0% 1% 2% 3% Spec.
OAC (%) 5.48 5.58 5.78 5,87 -
Stability (kg)
1980 1082 1004 1002
Min. 800
Flow (mm)
3.90 2,91 3.12 3,98 2 – 4
VIM (%) 4.52 4,83 4.92 3,74 3 – 5
VMA (%) 16,08 14,82 14,37 14,31 Min. 14
VFA (%) 72.00 65,80 72,63 75,08 Min. 60
MQ (kg/mm)
510 438 376 253
Min 250
4 CONCLUSIONS
Based on the test results of the Asphalt Concrete –
Binder Course (AC-BC) mixture using 50% laterite
stone as a substitute for coarse aggregate and crumb
rubber as an added ingredient, the maximum
addition of crumb rubber is 3% with an KAO value
of 5.58% and the value of the Marshall test
properties. namely stability = 1082 kg, flow = 2.91
mm, VIM = 4.83%, VMA = 14.82%, VFA =
65.80%, and MQ = 438 kg/mm. All variations of the
mixture meet the standards according to the
technical specifications of Bina marga 2018, the
greater the addition of crumb rubber, the lower the
stability value but still within the recommended
technical specification standards.
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