EXTRUDED POLYOLEFIN MOULDING
The invention relates to an extruded moulding, prepared from a polyolefm-based composite material .
Such an extruded polyolefm-based moulding is generally known, for instance from Kunststoff
Handbuch , Becker et al . , Carl Hanser Verlag, Munich, 1990.
Within the context of the present application an 'extruded moulding' is understood to be any object to be obtained by means of extrusion, m particular a film (for instance a flat or a blown film), a foam, a thm-walled object (for instance a bottle, a tube or a hose), a thick-walled object (for instance a profile, tube or plate) , a fibre, a monofilament or a thread, for instance cable sheathing. 'Film' is understood to be a material with a thickness that is small in comparison with the length and/or width of the material, its maximum thickness being about 250 micrometres. A 'thm-walled object' is understood to be an object at least part of which consists of a material with a thickness of more than about 250 micrometres and less than about 1 mm. A ' thick-walled object' is understood to be an object at least part of which consists of a material with a thickness of more than about 1 mm.
By 'extrusion' is meant a process m which a melt is formed a melting apparatus, from which subsequently a moulding is produced, and which
comprises at least a step m which a cooling melt is shaped to a moulding.
A drawback of the use of polyolef s for preparing extruded mouldings is that in many cases the polyolefin has a high viscosity the melt, which makes rapid processing of the polyolefin to a moulding impossible. The extrusion throughput is consequently low, which implies a less economic process operation. The use of a polyolefin having a low viscosity m the melt for extrusion to a moulding leads to melt fracture and/or sagging of the moulding after the melt has left the melting apparatus, which makes stable process operation impossible. In addition, the mechanical properties of such a moulding are not as good as when a polyolefin having a high viscosity m the melt is used.
The foregoing indicates that with application of the polyolefm-based composite materials according to the state of the art it is not possible to achieve rapid processing to mouldings with good properties .
The aim of the present invention is to provide an extruded moulding prepared from a polyolef -based composite material, which is free of said drawbacks.
The invention relates to a moulding which is prepared from a polyolefm-based composite material comprising 98-50 wt.% of a polyolefin, 1-50 wt.% of another homo- or copolymer and 0.1-70 wt.% of a layered, terstratifled clay.
The fact is that surprisingly it has appeared that such a composite material, hereinafter also called nanocomposite, has a low viscosity the melt at high shear forces, so the melting apparatus, and also a high viscosity m the melt at low shear forces, so after the melt has left the melting device. The term "nanocomposite" denotes the fact that the clay has at least one dimension m the about 1-100 nanometer
size range .
Further advantages are that the balance between rigidity and toughness and the balance between rigidity and transparency of the mouldings are better. Another advantage is that the moulding possesses better barrier properties, i.e. the moulding is less permeable to gases.
Suitable clays are for example smectic clay minerals, vermiculite clay minerals and micas, and synthetic micas. Examples of suitable smectic clay minerals are montmoπllonite, nontronite, beidellite, volkonskoite, hectoπte, stevensite, pyroysite, saponite, sauconite, magadnte, bentonite and kenyaite. Preferably montmoπllonite is chosen. To form the nanocomposite, however, the clay has to be dispersed very thoroughly m the polyolefin.
This is achieved by means of the process described m the following: the nanocomposite is obtained by impregnating a layered, swellable clay which is terstratifled with a tetraalkylonium cation, with at least one polymerizable monomer and then mixing this impregnated clay with a polyolefin and a peroxide, at a temperature above the melting temperature of the polyolefin.
In order to be able to be impregnated with one or more polymerizable monomers, the layered clay first has to be treated with a tetraalkylammonium or tetraalkylfosfonium salt, as described for instance m "Interlayer Structure and Molecular Environment of
Alkylammonium Layered Silicates", R.A. Vaia, T.K. Teukolsky, E.P. Giannelis, Chem. Mater. 1994, Vol 6, No.7, 1017-1022. The result is a so-called mterstratifled clay. The polymerizable monomers that are used m the process according to the invention can be polar, less polar and non-oolar monomers The monomers have at
least one unsaturated C=C-bond. By preference, at least one monomer of a polar nature is used. Polar monomers are monomers having a dipole moment greater than 1.0 D. Less polar monomers are monomers having a dipole moment of less than 1.0 D. Non-polar monomers do not have a dipole moment. The polarity is measured in the gas phase (Handbook of Chemistry and Physics, 66th Edition, CRC Press, pp. E58-E60) .
Polar monomers are for instance monomers which contain at least one nitrogen and/or oxygen atom. Examples of such monomers are monomers containing a carboxylic acid group, an ester group, a hydroxyl group, an epoxy group, an anhydride group, a nitrile group, an amide group, an imide group or a pyridine group. Examples are, for instance, acrylic acid, methacrylic acid, maleic acid, fumaric acid, itaconic acid, citric acid, maleic anhydride, itaconic anhydride, glycidyl acrylate, glycidyl methacrylate, allyl glycidyl ether, allyl amine, aminoethyl methacrylate, 2-hydroxyethyl acrylate, maleimide, 2- vinyl pyridine and 1 -vinyl -2 -pyrrolidone . Preferably, monomers containing an epoxy group are selected from this group of monomers, with particular preference being given to glycidyl methacrylate. Examples of less polar monomers and non- polar monomers are stryrene-containing monomers or diene-containing monomers. Examples of these are styrene, α-methylstyrene, p-methylstyrene, 1,3- butadiene and isoprene. Preferably, a styrene- containing monomer is chosen from this group of monomers. By special preference, these are styrene and α-methylstyrene .
The layered, interstratified clay is preferably impregnated with a mixture of two monomers which are copolymerizable, the first monomer being a polar monomer and the second one being a monomer that is non-polar or less polar than the first one. The
mixture of two monomers preferably consists of a mixture of a styren -containing monomer and a monomer containing an epoxy group.
As peroxide can be used the known and commercially available peroxides. Examples of peroxides that can be used are: t -butyl peroxybenzoate, t -butyl peroxy-2 -ethylhexanoate, bis (t-butyl peroxyisopropyl) benzene, acetyl cyclohexane sulphonyl peroxide, t -butyl hydroperoxide, di-lauroyl peroxide and di-cumyl peroxide. The peroxides are generally used m an amount of 0.01 -0.5 wt.% relative to the amount of the polyolefin m the polyolefm-based composite material, preferably m an amount of 0.05-0.3 wt.%. The peroxide can be mixed together with the monomer during the impregnation of the clay; it can also, and with preference, be added during the mixing of the impregnated clay with the polyolefin, or be present m the polyolefin. It is preferred that also the polyolefin contains at least part of the monomer (s), before the mixing of the impregnated clay with the polyolefin. As a result of the process of the present invention, the polymerizable monomer (s) is (are) polymerized to form the corresponding homo- or copolymer, as well as to a graft (co) polymer of the polyolefin.
Suitable polyolefmes are homo- or copolymers of α-olefmes, internal defines, cyclic defines and di-olef es. In particular, the process is suitable for enhancement of the rigidity of homo- or copolymers of α-olefmes. The α-olefme is preferably chosen from the group comprising ethylene, propylene, n-butene, n-pentene, n-heptene and n-octene (substituted or non-substituted) , mixtures thereof being also suitable. More preferably, a homo- or copolymer of ethylene and/or propylene is used as polyolefin. Examples of such polyolefmes are homo- and copolymers of (semi-) crystalline polyethylene of both
high and low density (for instance HDPE, LDPE and LLDPE) and polypropylene homo- and copolymers (PP and EMPP) . It is also possible to use as polyolefin amorphous or rubber- like copolymers on the basis of ethylene and another α-olefme; for instance EPM rubber (ethylene/propylene rubber) , EADM rubber (ethylene/ α-olefm/diene rubber) , and m particular EPDM rubber (ethylene-propylene/diene rubber) .
It is also possible to make use of mixtures of polyolef es.
When linear polyolef es, such as HDPE, LLDPE and isotactic polypropylene are used, the effect of the application of the nanocomposite instead of only the polyolefin on the speed of processing to mouldings with good properties is greatest.
The polyolefm-based composite material may contain the usual additives for polyolef es, such as for instance UV stabilizers, flame retardants, antioxidants, nucleating agents, colorants and plasticizers .
The layered swellable clay, treated with a tetraalkylonium cation, can be impregnated with at least one monomer and a peroxide by for instance mixing the monomer with the peroxide and then mixing the resulting mixture with the clay. Then the impregnated clay can be kneaded and mixed together with the olefmic homo- or copolymer. Another possibility is to place the mterstratifled clay on a powder bed of olefmic homo- or copolymer. Next, the monomer and the peroxide are applied onto the clay and then the whole is mixed with the rest of the olefmic homo- or copolymer and subsequently kneaded. Kneading of the impregnated clay and the peroxide with an olefmic homo- or copolymer takes place at a temperature above the melting temperature of the polyolefin, and above the decomposition temperature of the peroxide. This is normally done m a single- or twin-screw extruder, but
it is also possible to make use of for instance a static mixer or a batch mixer.
The amount of clay can be chosen freely within the indicated range; the amount is determined for instance by the desired properties of the extruded moulding to be obtained and depends, among other things, on the polyolefin chosen, the degree of mterstratification of the clay and the degree of dispersion m the polyolefin. Depending on the amount of clay m the nanocomposite, the nanocomposite can either be directly extruded to a moulding or first be mixed with another polyolefin before being processed to a moulding. Said another polyolefin must be (made) compatible with the polyolefin m the nanocomposite; preferably the another polyolefin is the same type of polyolefin as the polyolefin m the nanocomposite.
The nanocomposite can contain 0.1 to 70 wt.% of clay. A nanocomposite which will be extruded directly to a moulding normally contains 0.1 to 30 wt.% of clay. A concentrate of a nanocomposite normally contains 10 to 70 wt.% of clay, preferably 40-60 wt.% of clay. The amount of clay the extruded moulding preferably is 0.1 - 10 wt.%.
If the amount of clay m the nanocomposite is higher than the desired amount of clay m the extruded moulding, further blending of the nanocomposite with the polyolefin prior to production of the extruded moulding is of advantage. This blending can be done m two ways. Granulate or powder of the nanocomposite concentrate can be blended with granulate or powder of another polyolefin, after which it is extruded to a moulding. Such a mixture can also first be extruded to form a granulate, which is then used for extrusion of a moulding. The granulate or powder of the nanocomposite concentrate and the granulate or powder of the another polyolefin can also be extruded to a moulding directly after having been blended.
The polyolefin based composite material for preparing the extruded moulding of the present invention has a unique combination of a low viscosity m the melt at high shear forces, and a high viscosity m the melt at low shear forces.
The nanocomposite has a shear-rate dependant viscosity ratio (SVR) , which has not been shown with prior art products.
The SVR is hereinafter defined as the ratio of the viscosity η* (m Pa.s) at a shear-rate ω
(m rad/s) , of 0.1 and the viscosity η* at a shear rate of 100, the viscosity being determined according to ISO/DIN 6721-10. Defined as such, the SVR of the nanocomposite used the present invention has a value of at least 15, and more preferably a value of at least 25, and even more preferred a value of at least 30. The above m formula form: η*(CD=0 lη)
SVR = > 15; preferably > 25; more preferred > 30 η Cϋ=ιoo)
In the polyolefin based material of the invention an additional polar polymer can be present, like a nylon, styrene/acrylonitπle copolymer (SAN) , acrylonitril/butadiene/styrene terpolymer (ABS) , a styrene/carboxylic acid or styrene/carboxylic acid anhydride copolymer (like styrene/maleic anhydride (SMA) copolymer) . Preferably a nylon (or polyamide) is present; the resulting polymeric composition is, due to its ingredients, a well compatibilized blend of a polyolefin and a nylon. As nylons can be used polycaprolactam (nylon 6), polyhexamethylene adipamide (nylon 6,6), polytetramethylene adipamide (nylon 4,6), as well as other nylons known m the art. The extruded moulded part according to the invention optionally comprises additives, for example other types of fillers and reinforcing materials, for
example glass fibres and talcum, flame retardants, foaming agents, stabilizers, antiblocking agents, slipping agents, acid scavengers, antistatics, flow- promoting agents and colorants and pigments. The extruded moulded part according to the invention may also consist of one or of several other polymeric layers. Examples of suitable other polymeric layers are layers of ethylene-propylene copolymers, ethylene-propylene-butene copolymers and layers containing a copolymer of ethylene and vmyl alcohol (EVA) .
In particular, the known techniques can be used to produce the extruded moulding according to the invention, for example extrusion and coextrusion. With these techniques the following mouldings are obtained for instance: sheets, flat film, blown film, profiles, tubes, foams, fibres and tapes.
After the moulding has been extruded it can be subjected to an additional processing step. Examples of such processing steps are afterstretchmg and thermoform g . Examples of aftertreated mouldings are mono- or biaxially stretched films and stretched fibres .
The extruded moulding according to the invention can be used m particular the form of a film as packaging film, for instance for packaging of foodstuffs such as pasta, flowers, cigarettes, shirts, and as big and small bags, varying from sandwich bags to garbage bags . The extruded moulding can also be a thm- walled packaging material, for instance a bottle, for soft drinks or shampoo for instance, or a tray or a cup .
The extruded moulding is also quite suitable for use m the form of a pipe, for instance for the conveyance of hot and cold water, as well as
waste water and chemicals.
The invention will now be elucidated by means of Examples and comparative experiments without being limited hereto.
Examples I-III and comparative experiments A-B
Starting products
A) Polyolef e Al) Polypropylene homopolymer, Stamylan® P 15M00, DSM; melting temperature Tm = 165 °C (determined with DSC (differential scanning caloπmetry) , at 10 °C/,mm).
B) Monomers Bl) Styrene, 99% stabilized with 10-15 ppm 4-t- butylcatechol , Aldπch
B2) Glycidyl methacrylate, 97% stabilized with 100 ppm monomethyl ether hydroqumone, Aldrich
C) Peroxide
Cl ) Tπgonox C® , t -butyl -peroxi -benzoate , 98% , Aldrich
D) Layered clay
Dl) Montmorillonite modified with dimethyldi (hydrogenated long hydrocarbon chains) ammonium chloride (125 mer), SCPX 1313, Southern Clay Products Inc.
E) Miscellaneous El) Irganox® B225, Ciba Specialty Compounds
Preparation of the nanocomposite
A solution of the monomer or the monomers, the peroxide and optionally a UV stabilizer was prepared. This solution was added dropwise to the layered clay. When the clay had swollen, polymer powder was added, after which the whole was mixed on a mmi- extruder (Cordewener, T=220°C, t=5 mm., 200 rpm) . In the comparative experiments the UV stabilizer was added as a solid substance. The composition of the various polyolefm-based composite materials is shown in Table 1. The viscosity values of the various nanocomposites at different shearing rates are shown m Table 2. The viscosity was determined m accordance with ISO/DIN 6721-10.
Preparation of extruded moulding
The PP nanocomposites were processed to films on a
Gδttfert cast film processing equipment type 015.35.0. The cylinder length is 25D and the diameter is 30 mm.
The slit width was 320 mm (nr 00284112A and 00284112B) .
The chill roll had a wmd-up speed range of 0 - 15 m/mm.
The processing conditions were zone (1) 190, (2) 210, (3) 230 and (4) 240 °C and the split head was 250 °C.
The screw rotation speed was 95 rpm and the film had a thickness of 25 μm. The temperature of the chill roll was 20 °C.
The wind up speed for the PP nanocomposite was 11 m/mm, while the comparative neat PP had a maximum wind up speed of 7 m/mm.
This indicates the improved processability of the product according to the present invention.
Table 1
Example/ Polyolefin Clay Monomer Peroxide Miscellaneous
Comparative (PO) (wt.%) (wt.%) (wt.%) (wt.% rel . to PO) (wt.% rel. to PO) experiment
Al, Dl, 10 Bl, 2 Cl, 0.14 El, 0.0* B2, 1
II Al Dl, 10 Bl, 5 Cl, 0.31 El, 0.1Ϊ B2, 2
III Al, 80 Dl, 10 Bl, 7 Cl, 0.44 El, 0.26 B2, 3
A Al, 100 El, 0.23
B Al, 90 Dl, 10 El, 0.23
Table 2
ω is the shear rate (rad/s) η* is the viscosity (Pa.s) SVR = η* (ω=0.1) η* (ω=100)