[0001] This invention relates to a method of forming graft copolymers by attaching pre-polymerised
side chains to a natural or unsaturated synthetic rubber backbone and to the resulting
graft copolymers. A major use for such graft copolymers is thermoplastic rubbers;
but other uses also are envisaged, such as for example solvent-based or hot-melt adhesives.
[0002] Graft copolymerisation of vinyl monomers onto natural rubber has been extensively
studied in the past. The work has resulted in commercial production of materials known
as Heveaplus MG which contain natural rubber-methyl methacrylate graft copolymer.
Such materials have achieved some commercial success; but this has been limited by
the difficulty of controlling the reaction of the methyl methacrylate with the rubber
and the properties of the resulting product. The present invention adopts the alternative
approach of reacting pre-formed side chains with the rubber molecules and this provides
greater control of the of the structure of the graft copolymer.
[0003] More recently there has been rapidly growing commercial interest in a general class
of materials known as thermoplastic elastomers. These materials-have a range of physical
properties varying from the truly elastomeric behaviour of the Kraton styrene-butadienestyrene
block copolymers (Shell Chemical Co.) to the flexible plastic properties of the Hytrel
polyester- polyether block systems (E.I. DuPont de Nemours). The range of types is
continually increasing and their popularity stems largely from the typical combinations
of physical properties which are available from directly moulded products without
the need for chemical crosslinking and its associated complex mixing and curing cycles.
[0004] The importance of microphase separation in relation to the physical properties of
block copolymer systems is well established. The copolymer structure has considerable
influence on how this phase separation takes place and hence plays a primary role
in determining the physical properties. It has been shown that physical properties
comparable to those of such block copolymers can be obtained by graft polymerisation
of a glassy pre-polymer onto a rubbery backbone, provided the relative molecular weights
of.the hard and soft polymers are properly chosen. Thermoplastic rubbers of the block
copolymer type have previously been prepared in solution. A disadvantage of such techniques
is the need to recover the product from the solvent. The method of the present invention
avoids this disadvantage.
[0005] This invention provides a method of forming a graft copolymer, which method comprises
providing a reaction mixture of an ethylenically unsaturated-natural or synthetic
rubber in the solid state with a pre- polymer having one end group reactive towards
ethylenically unsaturated groups of the rubber, and maintaining the mixture at an
elevated temperature at least equal to the glass transition temperature of the pre-
polymer but below the decomposition temperature of the rubber with intimate blending
of the reactants, whereby the pre-polymer molecules react with and become attached
to the rubber molecule backbone.
[0006] The preferred chemical reaction for combination of a functionalised pre-polymer with
an unsaturated backbone polymer is the 'ene' reaction:
wherein -X=Y may be for example a suitably activated azo group.
[0007] An 'ene' reactive group in the form of an azodicarboxylate function can be constructed
on the end of a pre-polymer chain as follows:
where Q is the pre-polymer and R is C
1 to C
6 alkyl.
[0008] The pre-polymer, apart from its functional end group, does not take part in the reaction.
It should be substantially inert to the end group and to the rubber with which it
is to be heated. Suitable materials are poly (vinyl aromatic monomers) such as polystyrene,
poly(p-t-butylstyrene) or poly (α-methylstyrene).
[0009] The invention also provides a graft co-polymer prepared as described above having
a backbone derived from an ethylenically unsaturated natural or synthetic rubber and
side-chains of a poly-(vinyl aromatic monomer) and having the properties:-
M 100 (Modulus at 100% extension) 0.1 to 8 MPa
Tensile Strength 4 to 30 MPa
Elongation at Break more than 200%
Normally the pre-polymer is a linear molecule with a single functional group at one
end of the chain. It is possible, though not preferred, for the pre-polymer to have
branched chains. It is also possible, though again not preferred, for a minor proportion
of the pre- polymer molecules to have two functional groups; in this case, such molecules
will be liable to effect crosslinking in the rubber, but a limited degree of crosslinking
may be acceptable for some purposes.
[0010] For this reaction it is essential to use natural rubber or a highly unsaturated synthetic
rubber. Suitable rubbers include styrene-butadiene copolymers, acrylonitrile-butadiene
copolymers, polyisoprene, polybutadiene, and polychloroprene. The reaction is not
effective with materials having a saturated carbon backbone, nor even with hydrocarbon
rubbers of low unsaturation level. The molecular weight of the rubber is not critical.
Natural and unsaturated synthetic rubbers generally have a molecular weight of from
70,000 to 300,000 after solid state compounding such as is required for performing
the method of this invention.
[0011] For block and graft copolymers which are thermoplastic rubbers, the glass transition
temperature of the hard component is important, for the rubbery properties are predominant
below that glass transition temperature and the plastic properties above it. In the
preparation of materials that are to be used as thermoplastic rubbers at ambient temperature,
it is accordingly necessary that the prepolymer should have a glass transition temperature
above ambient and preferably of at least 60°C. An upper limit of about 220°C is placed
on the glass transition temperature by the fact that the reaction temperature of the
pre- polymer with the rubber has to be at least as high as the glass transition temperature
and most unsaturated rubbers begin to decompose around 200-220°C. In the present invention
the molecular weight range of the polystyrene gives a range of glass transition temperatures
from 70 to 95
0C.
7-
[0012] The number average molecular weight of the pre- polymer should preferably be in the
range 500 - 50,000, particularly 3,000 - 15,000. Molecular weights in this range are
sufficiently high to achieve the advantageous properties resulting from phase separation
in the graft copolymer and no further advantage is gained by using polystyrene having
a molecular weight above 20,000. Polystyrene may be conveniently prepared in a narrow
molecular weight range by anionic polymerisation; this technique is much easier to
use at lower pre-polymer molecular weights, because the viscosity of the system increases
very much as the molecular weight rises. If the polystyrene is prepared by emulsion
polymerisation, viscosity considerations do not arise to the same extent. But at molecular
weights above 20,000, it becomes progressively more difficult to purify and characterise
the product, and so more difficult to control the properties of the graft copolymer.
[0013] In the preparation of thermoplastic rubbers, it is necessary that the prepolymer
should be incompatible with the rubber. Compatibility for this purpose may be determined
by forming an intimate blend of the two polymers; if the blend shows two separate
glass transition temperatures, then the two polymers are incompatible. Of course,
if the graft copolymer is not intended for use as a thermoplastic rubber, then it
is not essential that the pre-polymer be incompatible with the backbone-forming rubber,
nor is it essential that the pre-polymer have a glass transition temperature above
60°C.
[0014] The method by which the functionalised pre-polymer is prepared is not critical to
this invention.
[0015] Polystyrene carrying a hydroxyl group at one end only of each molecular chain can
be conveniently prepared by anionic polymerisation of styrene in solution using n-butyl
lithium in the presence of tetramethyl ethylene-diamine (TMEDA) as an initiating system
and ethylene oxide followed by acid for chain termination.
[0016] Any other appropriate procedure for producing polymers with one end only of each
chain carrying a hydroxyl group or other group forming part of the synthetic schemes
outlined above may be used e.g. emulsion polymerisation in the presence of a chain
transfer agent carrying the appropriate functional group.
[0017] The reaction mixture preferably contains from 40 - 90% by weight of the rubber and
correspondingly from 60 - 10% by weight of the pre-polymer, on the weight of the two
reactants. While it is perfectly possibla to make graft copolymers containing more
than 60% by weight of the pre-polymer side chains, the properties of such products
may not differ significantly from those of materials obtained by more accessible routes.
Graft copolymers containing less than 10% by weight of side-chains have properties
not very different from those of the unmodified rubber. We prefer to use reaction
mixes containing from 15 - 55%, particularly from 25 - 45%, by weight of the pre-polymer.
It is possible, though not necessary, to include other materials in the initial reaction
mixture. Thus it is possible, though not preferred, to include a minor proportion
of water or organic liquid as a solvent or dispersant. Since the reaction appears
to be auto catalytic, it may be advantageous to include in the initial reaction mix
a proportion of the desired graft copolymer. If the resulting graft copolymer is to
be used in a compounded state, it will often be convenient to incorporate the compounding
ingredients in the reaction mixture during or even before reaction.
[0018] Very intimate mixing of the reactants during at least a part of the reaction is essential.
If the reactants are blended under low shear conditions near ambient temperature and
then heated under static conditions efficient grafting does not take place. Mixing
under high shear conditions should be continued for at least 30% and preferably more
than 60% of the reaction. Provided the reaction has been allowed to proceed under
high shear conditions for part of the reaction time subsequent high temperature handling,
e.g. compression moulding, injection moulding or extrusion, can increase the extent
of the reaction.
[0019] The grafting reaction takes place in the type of internal mixing machine normally
used for compounding of rubber prior to vulcanization. For experimental work, use
has been made of the mixing ability of the Hampden - Shawbury Torque Rheometer, which
consists of a pair of contra-rotating paddles within a heated cavity, the paddles
being driven by an electric motor mounted in a torque-sensitive mounting. For larger
scale operation, an internal mixer such as a Banbury mixer is suitable.
[0020] The temperature conditions of mixing are such that the initial cavity temperature
is approximately equal to or in excess of the glass transition temperature of the
prepolymer. The work expended on mixing results in a subsequent rise in temperature,
the amount of temperature rise depending to some extent on the composition of the
mixture and on mixing severity.
[0021] The severity of mixing is not readily defined without specific reference to the particular
machine being used. In general, the mixing severity is comparable to that required
to give carbon black reinforcement in conventional rubber mixing. Unnecessarily high
mixing severity can lead to a decrease in tensile strength and modulus in the product.
[0022] The preferred time of mixing is such as to result in substantially complete reaction
of the functional groups of pre-polymer. Mixing times of 2 - 30, preferably 5 - 20,minutes
are generally sufficient. Disappearance of azo functional groups can, in many cases,
be assessed by infra-red spectroscopic measurements on thin pressed films. The azodicarboxylate
group has a characteristic carbonyl absorption at 1785 cm 1 which disappears on reaction.
[0023] The grafting efficiency can be measured by gel permeation chromatography, whereby
prepolymer which has become chemically bound to the rubber backbone can be distinguished
from prepolymer which has not reacted.
[0024] The reaction efficiency depends, not only on the temperature and mixing conditions,
but also on the impurities present in the reactants. Synthetic cis- polyisoprene can
be provided in a relatively clean state, and can accordingly be caused to react with
the pre-polymer at high efficiency. The reaction with natural rubber is generally
somewhat less efficient. Reaction efficiencies of from 40 to 100% are typical, based
on the azodicarboxylate contents of the pre-polymers. Because of cumulative inefficiencies
in the synthetic procedures, the prepolymer does not have a functional group at the
end of every chain and there is always a proportion of the prepolymer sample which
is incapable of chemical combination with the rubber backbone. Overall grafting efficiencies
are defined as the percentage of the total prepolymer charge which becomes chemically
bound to the rubber backbone in the course of the reaction. Grafting efficiencies
are in the range 10-80%, in most cases, better than 30%. It is surprising that reaction
between two incompatible polymers should take place at all under these conditions.
[0025] As previously stated, many of the products of this invention have properties which
make them valuable for use, either as such or compounded with fillers, stabilisers,
pigments etc., as thermoplastic rubbers. The products are useful without vulcanization
because the pre-polymer side chain domains act as crosslinks and filler particles.
They may be used for example as hot melt adhesives, solution adhesives, or for injection
moulding, compression moulding or extrusion. The use of stable pre-polymers which
can be isolated and characterised makes it very easy to control the reaction with
the rubber so as to obtain desired properties in the graft copolymers.
[0026] The following examples illustrate the invention.
EXAMPLE 1
[0027] Natural rubber, SMRSL (19.5g), and polystyrene of number average molecular weight
(Mn) 3200 having 79% of the polymer chains terminated with azodicarboxylate functional
groups (10.5g) were added to a small internal mixer heated to 90°C. Mixing was carried
out at 150 r.p.m. for 10 min. to give a final mix temperature of 140°C. As the reaction
proceeded the initially opaque reaction mixture gradually became transparent. A sample
of the product (5.6g) was pressed at 150°C for approximately 5 sec. to give a sheet
approximately 0.5 mm thick. The sheet was cut into pieces and the sample again pressed
into a coherent sheet under the same conditions. The same sample was then formed into
a sheet 100 x 100 x 0.5 mm by compression moulding at 150°C for 45 sec. Standard tensile
test dumbells (BS 903 Part A2, Type C) were cut from the sheet and tested at an extension
rate of 500 mm/min. at 23°C. Analysis of the reaction mixture by gel permeation chromatography
showed that the overall grafting efficiency (i.e. the proportion of the total added
polystyrene which became chemically bound to the rubber backbone) was 66%.
[0028] In the same way, products were prepared with different proportions of the natural
rubber and of the polystyrene. These preparations are summarised in Table I.
EXAMPLE 2
[0029] As for Example 1, with polystyrene of Mn 5450 having 75% of the polymer chains terminated
with azodicarboxylate functional groups. These preparations are summarised in Table
II.
EXAMPLE 3
[0030] As for Example 1, with polystyrene of Mn 8200 having 72% of the polymer chains terminated
with azodicarboxylate functional groups. These preparations are summarised in Table
III.
EXAMPLE 4
[0031] As for Example 1, with polystyrene of Mn 8900 having 77% of the polymer chains terminated
with azodicarboxylate functional groups. These preparations are summarised in Table
IV.
EXAMPLE 5
[0032] As for Example 1, with polystyrene of Mn 12700 having 63% of the polymer chains terminated
with azodicarboxylate functional groups. These preparations are summarised in Table
V.
EXAMPLE 6
[0033] As for Example 1, with polystyrene of Mn 17700 having 68% of the polymer chains terminated
with azodicarboxylate functional groups. The mixing conditions were altered to 6 min.
at 150 r.p.m. with an initial mixer temperature of 130°C. These conditions gave better
grafting efficiencies that the standard conditions of Example 1 for polystyrene of
this molecular weight. These preparations are summarised in Table VI.
EXAMPLE 7
[0034] As for Example 3 using SMR10 natural rubber instead of SMR5L. The polystyrene content
of_the mix was 40% by weight. The preparation is summarised in Table VII.
EXAMPLE 8
[0035] As for Example 7, using SMR20 natural rubber instead of SMR10. The preparation is
summarised in Table VII.
EXAMPLE 9
[0036] As for Example 7, using SMR5CV natural rubber instead of SMR10. The preparation is
summarised in Table VII.
EXAMPLE 10
[0037] As for Example 7, using RSS1 natural rubber instead of SMR10. The preparation is
summarised in Table VII.
EXAMPLE 11
[0038] As for Example 1, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table VIII.
EXAMPLE 12
[0039] As for Example 2, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table IX.
EXAMPLE 13
[0040] As for Example 3, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table X.
EXAMPLE 14
[0041] As for Example 4, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table XI.
EXAMPLE 15
[0042] As for Example 5, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table XII.
EXAMPLE 16
[0043] As for Example 6, using Cariflex IR305 synthetic polyisoprene instead of natural
rubber. These preparations are summarised in Table XIII.
EXAMPLE 17
[0044] As for Example 14, using Natsyn 2200 synthetic polyisoprene. The polystyrene content
of the mix was 40% by weight. The final mix temperature was 157°C and the grafting
efficiency was 41%. Tensile testing gave M100, 2.3 MPa; M300, 6.2 MPa; M500, 14.0
MPa; Tensile strength, 15.3 MPa; with the elongation at break 529%.
EXAMPLE 18
[0045] As for Example 2, using Intene 55NF polybutadiene instead of natural rubber. The
preparations are summarised in Table XIV.
EXAMPLE 19
[0046] As for Example 18, using polystyrene of Mn 8500 having 75% of the polymer chains
terminated with azodicarboxylate end groups. The preparations are summarised in Table
XV.
EXAMPLE 20
[0047] As for Example 19, using Europrene-cis polybutadiene. The polystyrene content of
the mix was 40% by weight. The mixer was heated initially to 110°C and the mixing
was continued for 15 min. at 150 r.p.m. The final mix temperature was 149°C and the
grafting efficiency was 41%. Tensile testing gave M100, 1.89 MPa; M300, 3.5 MPa; Tensile
strength, 3.9 MPa; with the elongation at break 369%.
EXAMPLE 21
[0048] As for Example 19, using Intol 1500 styrene-butadiene copolymer instead of Intene
55NF polybutadiene. The preparations are summarised in Table XVI.
EXAMPLE 22
[0049] As for Example 1, using Breon 1041 acrylonitrile-butadiene copolymer instead of natural
rubber. The polystyrene content of the mix was 40% by weight. The mixing time was
extended to 20 min. The final mix temperature was 160°C and the grafting efficiency
was 66%. Tensile testing gave M100, 7.8 MPa; M300, 10.0 MPa; Tensile strength 13.1
MPa; with the elongation at break 444%.
EXAMPLE 23
[0050] As for Example 1, using Neoprene AD20 polychloroprene instead of natural rubber.
The polystyrene content of the mix was 40% by weight. The mixing time was extended
to 15 min. The final mix temperature was 128°C and the grafting efficiency was 45%.
Tensile testing gave M100, 0.87 MPa; M300, 2.18 MPa; M500, 3.66 MPa; Tensile strength,
6.54 MPa; with the elongation at break 800%.
EXAMPLE 24
[0051] Cariflex IR305 synthetic polyisoprene was mixed with polystyrene of Mn 8200 having
no terminal azodicarboxylate end group, under the conditions described for Example
1. The polystyrene content of the mix was 40% by weight. The product was opaque and
a compression moulded sheet had a tensile strength of < 0.5 MPa. This example demonstrates
that a simple blend of polystyrene and rubber is a very weak material, even when the
blend is prepared under conditions of high shear.
EXAMPLE 25
[0052] Cariflex IR305 synthetic polyisoprene was blended with polystyrene of Mn 8200, having
72% of the polymer chains terminated with azodicarboxylate functional groups, on a
two-roll mill at 50°C. The polystyrene content of the mix was 40% by weight. A sample
of the mix was pressed at 150°C to give a sheet 0.5 mm thick and was maintained at
150°C for 15 min. The final sheet was opaque and had a tensile strength of <0.5 MPa.
This example demonstrates that static heating of a mix prepared under low shear conditions
is not sufficient to achieve grafting and develop strength in the material.
EXAMPLE 26
[0053] A series of mixes were prepared as in Example 13 with mixing times of 4, 6, 8 and
10 min. The polystyrene content of the mixes was 40% by weight. Samples of the mixes
were analysed for grafting efficiency by gel permeation chromatography then sheets
were prepared by compression moulding as described in Example 1. Samples of the moulded
sheets were analysed for grafting efficiency and the sheets were tested for modulus
and tensile strength under the standard conditions. The results are summarised in
Table XVII. This example demonstrates that, provided the grafting reaction is initiated
and allowed to proceed to some extent under high shear conditions, the remainder of
the reaction can be completed by a subsequent high-temperature handling step, e.g.
by compression moulding.
EXAMPLE 27
[0054] A series of mixes were prepared as in Example 13 at mixing speeds of 75, 105 and
150 r.p.m. The polystyrene content of the mixes was 40% by weight. Samples of the
mixes were analysed for grafting efficiency by gel permeation chromatography then
sheets were prepared by compression moulding as described in Example 1. Samples of
the moulded sheets were analysed for grafting efficiency and the sheets were tested
for modulus and tensile strength under the standard conditions. The results are summarised
in Table XVIII. This example demonstrates that a decrease in the severity of mixing
results in a decrease in grafting efficiency at a given mixing time but provided some
degree of grafting has been initiated the grafting reaction can proceed further during
subsequent high temperature handling, e.g. during compression moulding.
1. A method of forming a graft copolymer, which method comprises providing a reaction
mixture of an ethylenically unsaturated natural or synthetic rubber- in the solid
state with a pre-polymer having one end group reactive towards ethylenically unsaturated
groups of the rubber, and maintaining the mixture at an elevated temperature at least
equal to the glass transition temperature of the pre-polymer but below the decomposition
temperature of the rubber with intimate blending of the reactants, whereby the pre-polymer
molecules react with and become attached to the rubber molecule backbone.
2. A method as claimed in claim 1, characterized in that the end group of the pre-polymer
is an azodicarboxylate group.
3. A method as claimed in claim 1 or claim 2, characterized in that the pre-polymer
is a poly(vinyl aromatic monomer).
4. A method as claimed in any one of claims 1 to 3, characterized in that the rubber
is natural rubber.
5. A method as claimed in any one of claims 1 to 3, characterized in that the rubber
is selected from styrene-butadiene copolymers, acrylonitrile-butadiene copolymers,
polyisoprene, polybutadiene and polychloroprene.
6. A method as claimed in any one of claims 1 to 5, characterized in that the pre-polymer
in polystyrene having a number average molecular weight of from 3,000 to 15,000 and
a glass transition temperature of from 70 to 95°C.
7. A method as claimed in any one of claims 1 to 6, characterized in that the reaction
mixture contains from 40 to 90% by weight of the rubber and-correspondingly from 60
to 10% by weight of the pre-polymers on the weight of the two reactants.
8. A method as claimed in any one of claims 1 to 7, characterized in that the reactants
are intimately blended in an internal mixer.
9. A method as claimed in any one of claims 1 to 8, wherein intimate blending is continued
for at least 60% of the reaction.
10. A graft co-polymer prepared by the method of any of claims 1 to 9, having a backbone
derived from an ethylenically unsaturated natural or synthetic rubber and side-chains
of a poly-(vinyl aromatic monomer) and having the properties:-