An Experimental Investigation on CMA

International Journal of Trend in Scientific Research and Development (IJTSRD)
Volume 5 Issue 5, July-August 2021 Available Online: www.ijtsrd.com e-ISSN: 2456 – 6470
@ IJTSRD | Unique Paper ID – IJTSRD45088 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1332
An Experimental Investigation on CMA
Manoj Sheoran1
, Ms. Shivani2
1
M Tech Scholar, 2
Assistant Professor,
1,2
Sat Priya Group of Institutions, Rohtak, Haryana, India
ABSTRACT
There are various roadway construction activities and plans that
involve the use of flexible pavement having hot mix technique. This
hot mix technique is a traditional method for the construction of road
that has fulfilled the performance evaluation from infrastructure point
of view throughout the past years. The various processes which are
involved in this technique are: providing heat to the aggregate and
binder, proper mixing, provision of tack coat as per the
specifications, laying of the mixed, the process of compaction. The
cold mixed technique having use of bitumen emulsion on large scale
should be epicenter of the study such that this technology may
advance its application in present as well as future with proper
specifications, testing throughout. The Hot mixed based techniques
have gone through the significant advancements with time. The Cold
mixed based technology is somewhere lagging in terms of
applications which might be observed in the developing countries. In
the present study, it has been the primary motivation that underlies
the selection of cold mixed technique.
KEYWORDS: Hot Mix Technique, Flexible Pavement, Bitumen,
Emulsion
How to cite this paper: Manoj Sheoran |
Ms. Shivani "An Experimental
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GENERAL
The hot mix technique is a traditional method for the
construction of road that has fulfilled the performance
evaluation from infrastructure point of view
throughout the past years. The various processes
which are involved in this technique are: providing
heat to the aggregate and binder, proper mixing,
provision of tack coat as per the specifications, laying
of the mixed, the process of compaction. All these
processes usually takes place at higher range of
temperature having variations between 120ºC to
165ºC. This technique is considered to be the most
suitable one for the formation of pavements as per the
performance point of view but it always said that
every good thing has some consequences. The major
drawbacks involved in this technique are like higher
consumption of energy, degradation of environment,
rapid growth of footprints of carbon, limited period of
construction available per annum, oxidation of binder
during its hardening, health problems to labours,
safety hazards (Pundhir et al., 2012). Apart from this,
some parts of India like J & K, North-East states,
Himachal Pradesh, Uttrakhand and others consist of
large number of projects involving rural roads having
investment in millions. As far as the mountainous
terrain is concerned, the area has huge constraints in
terms of weather, rainfalls, etc. and as a result, it
becomes very hard to with the hot mix technique /
technology. Eventually, it becomes inadvertently
essential or mandatory to determine the most
appropriate alternative of this technique. The cold mix
technique is based upon the use of emulsions. It
involves the use of wetting of aggregates prior to
work, often termed as pre-wetting phenomenon
followed by the use of emulsions to the aggregates,
mix production, laying of mix and process of
compaction. All the above said processes are usually
performed at room temperature (25º ± 2 º C).
Moreover, it has already been proved that this cold
mixes may be produced easily by the use of hot mix
plants and these laid in the similar fashion too. It is
also considered to be the labor friendly technique.
PAST STUDIES ON BITUMINOUS EMULSION
IN COLD MIX ASPHALT
As per TRB (2006), A circular named as “Asphalt
Emulsion Technology” under the category of
transportation research provided the essential
information related to the bitumen based emulsions.
Emulsion is defined as the dispersion of tiny droplets
IJTSRD45088

International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470
of one medium (specifically liquid) into the other one.
It may be formed by the mixing of any two
immiscible liquids; however, in most of the cases of
emulsions, one of the two phases is liquid. The
Bituminous emulsion is considered to be the product
available in the liquid state which contains the
considerable given quantity of bitumen when
suspended in water in form of the finely divided
product in the presence of a specific emulsifier. The
size of bitumen droplets varies from 0.1 micron to 20
micron. A standard type of bitumen emulsion consists
of a liquid brown in colour having bitumen in the
range of 40 to 75 % by weight, water in the range of
25 to 60 % by weight, emulsifier in the range of 0.1 to
2.5 % along with some minor compounds.
A study had been conducted in 1993 by Uemura and
Nakamori in laboratory as well as field based on the
use of cold mixes. It was concluded that the use of
cold mix is very highly eco-friendly in nature due to
no involvement policy dust and zero level emission of
gases. It was also observed that there is no need to try
off the aggregates and asphalt before its use and the
performance of cold mix is found to be very
satisfactory.
Dittmar (2011) considered that the self repairing of
cracks takes place with time only in cold mixed
asphalt based pavement. This study also recommends
that the surfaces formed by cold mixed asphalt are
more stable and flexible, as it may retain the
comparative longer life on the roads having low traffic
volume.
It was also concluded that the cold mixed asphalt
production has very wide range of differential
applications. The cold mixes may be primarilyused in
base courses, wearing courses or binders, etc. These
asphalt mixes may be implemented on roads by the
numerous methods such as by grader applications,
pavers applications, self contained laying plants, etc.
As per the suggestion of Oke (2010), there have been
a wide range of methods of compaction but the most
appropriate method is the use of steel rollers. For
commercial scale purposes, the pneumatic tyred
rollers are used initially and then, finished the steel
rollers.
There have been so many studies conducted by
various researchers (Needham 1996, Ibrahim 1998,
Thanaya 2003, Thom 2008) that concluded in the
favour of use of cold mixed asphalt as compared to the
hot mixed asphalt in terms of saving of energy, use
efficiency, durability, etc. It was also concluded that
these cold mixes based asphalts are found to be
satisfactory globally for the traffic conditions varying
from low volume to medium volume range, for the
pavement construction in the remote areas, etc.
Categorization and Designation of Bituminous
Emulsion: There are large numbers of emulsifiers
available in market on the basis of which nature of
emulsion is determined in terms of anionic or cationic.
The anionic emulsion contains some droplets of
bitumen having some negative charge. The cationic
emulsion consists of some droplets of bitumen
having some positive charge. On the basis of their rate
of settlement, both the kinds of emulsions such as
cationic and anionic emulsions are divided into three
categories i.e., slow setting (SS), medium setting (MS)
and rapid/fast setting (RS). The rate of settlement may
be controlled by use of emulsifier, its type and
concentration. The prime difference lies between
cationic and anionic emulsions is the faster giving up
of water by cationic emulsions as compared to that of
anionic emulsions. As per ASTM-D977 & ASTM-
D2397, the emulsion nomenclature states the cationic
emulsions into subcategories as CRS (cationic rapid
setting), CMS (cationic medium setting), CSS
(cationic slow setting). The emulsion nomenclature
states anionic emulsions into subcategories as RS
(anionic rapid setting), MS (anionic medium setting),
SS (anionic slow setting). All of the above said types
of emulsions are followed by a number among 1 & 2
and a text which indicates the viscosity of emulsion
and their residual properties. The numbers 1 & 2
represents lower level viscosity and higher level
viscosity respectively. The text H represents the high
grade of asphalt residue. For example, CRS-2H can be
named as rapid-setting (representing lower rate of
reactivity) cationic emulsion with higher viscosityand
high grade of asphalt residue. The quick setting
emulsions whether cationic or anionic in nature are
included in the intermediate range of reactivity that
lies between SS and MS. These emulsions do not
require passing any cement-mix test. These are used
mainly slurry based surface finishing applications.
The local vendors mainly form their own schemes of
classification that relates the emulsions with some
particular characteristics. The above nomenclature is
further followed by some other letters which have
their own meaning. For example, PM represents
polymer - modified asphalt emulsion, LM represents
latex – modified emulsion, S represents the higher
solvent concentration. Based on their uses, AEP
shows the asphalt emulsion prime, ERA indicates the
recycling agent emulsion and PEP shows the
penetrating emulsion prime.
Mechanism of Breaking: Most of the emulsions are
found to be inadvertently highly unstable in nature.
During larger time span in terms of years, the phase of
asphalt eventually gets separated from its solvent. The
asphalt is considered to highly insoluble in water and
as a result, the breaking of emulsion includes the

droplets fusion which is termed as coalescence. The
small drops of emulsion contain small charge value
and emulsifier along with some ionisable compound is
found to be the prime source of charge. The small
charged droplets act as the electrostatic barrier
towards their closer approach with respect to each
other. But, the enough level of energy is attained by
the droplets to overcome the electrostatic barrier and
moves towards each other those results into formation
of some flocculates. With the passage of some time
span, the layer of water between the drops in the form
of flocculate gets shrunk and the droplet gets coalesce.
The factors responsible for bringing the droplets
together are vaporization process, sedimentation
process, freezing, shearing, etc. All these factors may
accelerate the process of flocculation as well as
coalescence.
In 1994, Leech stated that the emulsions formed by
the cationic bitumen are proved to be heavily
compatible with most of the aggregates. The type of
bitumen, level of emulsifier, temperature, cement
content and pressure applied are major factors that
affect the droplets of emulsion coalescence [Brown
and Needham (2000)]. Pouliot et al. (2003) concluded
that the mortars made up of the cationic rapid setting
emulsion (CRS-1) gave the higher strength value and
higher value of elastic modulus as compared to the
mortars made up of the anionic rapid setting emulsion
(RS-1). Song et al. (2006) considered determining the
spontaneity and feasibility for the use and benefits of
the given asphalt based emulsion in the form of a
polymeric admixture. It was concluded that proofing
against water dampness, resistance to carbonation
attack and resistance to the chloride-ion penetration of
modified mortars of asphalt were considerably
improved with rise in the value of polymer-cement
ratio. However, the value of compressive strength and
adhesion bond between substrates of mortar gets
decreased with rise in the value of polymer-cement
ratio.
Another research study was conducted in which the
type of aggregate had impacts to determine the nature
of emulsion in terms of anionic or cationic. The rate of
reaction of aggregates completely depends upon the
proportion of negative charge and its random
distribution. E.g. the aggregates constituted of higher
silica content are found to be acidic in nature and has
evenly distribution of negative charges on their
surfaces. Even, these charges are proved to be
responsible for the strong adhesive bonding between
the cationic emulsions and aggregates [Oruc et al.
(2007)].
METHOD OF COLD MIX DESIGN
The binders of bitumen which are primarilyutilized in
the cold mix are essentially to be emulsified in nature
which indirectly represents the liquid form of the
binder. Therefore, it may be implemented at
comparatively low value of temperatures as compared
with that of hot mixed based asphalt. Although, the
cold mix mainly manufactured/produced at ambient
level of temperatures, even some of the processes
might utilize the emulsion asphalts heated to about
60° ± 5°C.
There is no proper method for the design of cold mix
based design and hence there is no specific method or
rule that should be followed. In addition to this, there
is no specification issued by Indian Standard and no
general equipment for the cold mix based emulsion.
However, all of the above said parameters are pre-
defined for hot mixes. There is only one method
namely; Marshall method that has been frequently
used for these design mixes. Now a days, compaction
from this method is replaced with the gyratory
compaction to overcome or reduce the compaction
problems which inertly improves the physical
characteristics of the mixes.
MORTH (Ministry of Road Transport and Highways,
2001) introduced the complete phenomenon for the
bituminous cold mixes during its fourth revision. The
guidelines for the design process were defined in
Manual series No.-14 (MS-14) issued by the Asphalt
Institute. During the background study and analysis, it
was also observed that there are some very useful tips
and tricks which might be used for the preparation of
cold mixed based asphalt design [Thanaya (2007)].
The major difference between the analytical process
issued by Thanaya and MS-14 is the calculation
process of use of optimum total liquid concentration
(OTLC) and optimum residual asphalt concentration
(ORAC). To find the value of ORAC, Thanaya gave
the idea to conduct the stability test in soaked stage
only while MS-14 gave the idea to conduct the
stability test in dry stage as well as soaked stage at
every residual asphalt content (RAC). Among both the
study, the former study is proved to more effective,
economic and highly efficient, but it does not include
determination of OTLC for the design preparation. As
a result, this process is considered to be highly
suitable for the field only. The complete design steps
involved and design specifications required as per
MORTH guidelines are given in table 2.1 and 2.2
respectively.
Table 1: Difference between the Study for MS 14 and Thanaya CMA design procedure
Asphalt Institute MS 14 (1997) Thanaya (2007)

Calculation of
Gradation of aggregate based on
specifications
IEC & IRAC (Based on formula)
Optimum Pre-wetting Water Content
(OPWC) – Coating test
Optimum Total Liquid Content
(OTLC) – Stability Test in Dried
State
Optimum Residual Asphalt Content
(ORAC) - Stability Test for both
RAC in Dried State and Soaked State
Determination of
Gradation of aggregate based on specifications
IEC & IRAC (Based on formula specified by MS-14)
Optimum Pre-wetting Water Content (OPWC) –
Coating test
Optimum compaction to attain the desired value of
porosity followed by Stability Test in Dried State
Optimum Residual Asphalt Content (ORAC) -
Stability Test for Soaked State only
Retained Stability (Dry Stability Test), AFT (As per
formula) and Ultimate strength (fully cured mix) at
ORAC
CONCLUSION
From the above study, the following conclusions
are drawn:
The cold mixes may be primarily used in base
courses, wearing courses or binders, etc. These
asphalt mixes may be implemented on roads by
the numerous methods such as by grader
applications, pavers applications, self contained
laying plants, etc.
The aggregates constituted of higher silica content
are found to be acidic in nature and has evenly
distribution of negative charges on their surfaces.
Even, these charges are proved to be responsible
for the strong adhesive bonding between the
cationic emulsions and aggregates
The proofing against water dampness, resistance
to carbonation attack and resistance to the
chloride-ion penetration of modified mortars of
asphalt were considerably improved with rise in
the value of polymer-cement ratio.
Among both the study i.e. Manual series No.-14
(MS-14) and Thanaya (2007), the former study is
proved to more effective, economic and highly
efficient, but it does not include determination of
OTLC for the design preparation. As a result, this
process is considered to be highly suitable for the
field only
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USA
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An Experimental Investigation on CMA

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