Generally, the blending of two or m

Generally, the blending of two or more types of polymers
is a useful technique for the preparation and
development of materials with properties superior to
those of individual constituents [1]. The purpose of
blending the rubber is to improve the physical and
mechanical properties as well as modify processing characteristics
and reduce the cost of the final product.
However, most polymer blends are immiscible and usually
exhibit phase separated morphology and poor interfacial
adhesion between the phases [2]. The interfacial adhesioncan be improved by introducing a third component into an
immiscible binary system that will either interact chemically
with both the phases or will have a specific interaction
with one phase and a physical interaction with the
other [3]. This phenomenon can be justified as an
improvement in the compatibilization of the blend.
Commonly, compatibilization can lead to a finer phase
structure and enhanced interfacial adhesion [4]. The
compatibilizer may form an interface between the
immiscible blend components, so that imposed stresses
can be transferred between the phases via the covalent
bonds along the copolymer backbone. However, an
understanding of the blend morphology is important
because the properties of the polymer blends are strongly
dependent on it [5]. Addition of a suitable compatibilizer
was found to result in the development of a finer scale of
dimensions of the dispersed phase in the matrix as well as
enhancement of physico-mechanical properties of the
vulcanizates [6].
Epoxidized natural rubber (ENR) is a chemically
modified form of the cis-1,4-polyisoprene rubber, whereby
some of the unsaturation is converted into epoxide
groups, which are randomly distributed along the polymer
chain [7]. It is known as a compatibilizer for incompatible
blends as well as a processing aid. The incorporation of
ENR-50 into the rubber blends has improved processability,
stiffness, resilience and also shows excellent oil
resistance, reduced air permeability, good damping and
wet grip performance [8].
Considering the economic and environmental advantages,
recycling is one of the best options. A number of
possible applications of various forms of waste rubber in
broad disciplines have been studied and reported [9–11].
Recycled rubber can be generalized as any rubber waste
that has been converted to an economically useful form,
such as reclaimed rubber, ground rubber or reprocessed
synthetic rubber [12]. The manufacturing of powdered
rubber has obvious economic and social benefits, as it
decreases the cost of the product by blending fine
powdered rubber with raw rubber [13]. Recycled latex has
become a focus of attention compared to reclaimed
rubber due to the lightly cross-linked and high quality
nature of rubber hydrocarbon [14]. The use of acrylonitrile-
butadiene rubber (NBR) latex in glove production
has increased all over the world due to its excellent
resistance to puncture and tears as well as the non-existence
of leachable allergenic proteins, unlike natural
rubber latex. Nitrile gloves are currently used in many
areas such as the medical field and, to a greater extent,
the food industry, automotive industry, etc. As a result,
significant quantities of discarded gloves are generated
worldwide daily.
Blending of styrene butadiene rubber/acrylonitrilebutadiene
rubber (SBR/NBR) blends leads to an
incompatible blend [15]. It is well known that the physicomechanical
properties of the pure components SBR and
NBR are very weak in the absence of a reinforcing filler
and, consequently, the physico-mechanical properties of
their blends are also inferior. This originates principally
from the incompatibility of both components with each
other in view of the fact that NBR has more polarity than
SBR [16]. Compatibility of the polymer blends can be
studied by differential scanning calorimetry (DSC), which
measures the glass transition temperature (Tg) and
melting temperature of the polymeric material. Miscible
blends will show a single, sharp transition peak (Tg),
intermediate between those of the blend components.
Separate transitions are obtained for immiscible blends. In
the case of borderline miscible blends, broad transitions
are obtained [17,18].
Styrene butadiene rubber (SBR), known as a non-polar
rubber, has good mechanical properties and does not
easily break down. Particularly, it has better ozone resistance,
weatherability and abrasion resistance than natural
rubber. NBR (polar rubber) has good solvent resistance
compared to SBR, but its mechanical characteristics are
poorer than SBR [19]. To the best of our knowledge, less
work has been done dealing with recycled NBR waste. In
Malaysia, the output of nitrile rubber gloves was found to
be abundant. Most of this material originates from
medical, industrial, and research activities. After a certain
period of time these polymeric materials are not
serviceable and are mostly discarded. To solve this environmental
issue, recycled NBR gloves (waste) obtained
from Juara One Resources (M) Sdn Bhd, a glove manufacturer,
were used in an effort to create value added
materials. The effects of different sizes of recycled acrylonitrile-
butadiene rubber (NBRr) and blend ratios on
curing characteristics, mechanical properties and
morphological properties of styrene butadiene rubber/
recycled acrylonitrile-butadiene rubber (SBR/NBRr)
blends was already highlighted [20]. The effect of some
compatibilizers on compatibility of SBR/NBR rubber
blends has been studied [21,22]. However, no attempt has
been made to investigate the effects of ENR as a compatibilizer
on the properties of SBR/NBRr blends. The effects
on cure characteristics, mechanical properties, FTIR, DSC
analysis and also morphological behavior of SBR/NBRr
blends with and without ENR-50 were examined.