Slit film yarn based on propylene polymer and its use for the manufacture of synthetic lawn

Slit film yarn based on propylene polymer, resistant to postfibrillation. The propylene polymer is a block copolymer of propylene and ethylene made up of chain segments consisting of propylene homopolymer and of chain segments consisting of random copolymer of propylene and ethylene. This slit film yarn is suitable for the manufacture of synthetic lawn.

The present invention relates to slit film yarn based on propylene polymer 
and resistant to postfibrillation. It also relates to the use of this slit 
film yarn for the manufacture of synthetic lawn. 
It is known to manufacture slit film yarn based on crystalline propylene 
polymers by slitting films extruded from compositions comprising such 
polymers. In the majority of the common usages for which this slit film 
yarn is intended (weaving, rope and string manufacture, etc), the 
mechanical properties which are imparted to them by the crystalline 
propylene homopolymers have been found sufficient. For some usages of this 
slit film yarn, in particular when an exceptional resistance to crushing 
and/or to tearing is demanded (floor coverings, etc), propylene 
homopolymers are not, however, wholly satisfactory. For particularly 
demanding usages of this slit film yarn, such as the manufacture of 
synthetic lawn, described in European Patent Application EP-A-0,259,940 
(Koninklijke Nijverdal-Ten Cate N.V.), a polypropylene such as employed in 
the examples of this application is not suitable: the strands obtained by 
mechanical fibrillation of the slit film yarn do not sufficiently 
withstand crushing and tearing, which give rise to a phenomenon of 
"postfibrillation" of the slit film yarn after periods of time which are 
unacceptably short for an article of this type. 
The present invention is aimed at providing slit film yarn which does not 
exhibit these disadvantages. 
The present invention relates, therefore, to slit film yarn based on 
propylene polymer and resisting postfibrillation, the propylene polymer 
being a block copolymer of propylene and ethylene, made up of chain 
segments consisting of propylene homopolymer (which are called more 
briefly "propylene homopolymer" hereinafter) and of chain segments 
consisting of random copolymer of propylene and ethylene (which are called 
more briefly "random copolymer" hereinafter). 
The block copolymers forming part of the composition of the slit film yarn 
according to the invention can be manufactured by any known process, in 
the presence of catalyst systems of the type known as Ziegler-Natta, based 
on organometallic compounds and on solids containing titanium trichloride. 
Propylene is generally first polymerized by itself in a first stage and 
propylene and ethylene are then polymerized, in a second stage, in the 
presence of the polymer obtained during the first. Each of these stages 
can be carried out, for example, in suspension in a hydrocarbon diluent, 
in suspension in liquid propylene, or else in gaseous phase, continuously 
or noncontinuously, in the same reactor or in separate reactors. 
Additional information relating to these block copolymers and to their 
manufacture may be found particularly in chapters 4.4 and 4.7 of the work 
"Block Copolymers" edited by D. C. Allport and W. H. Janes, published by 
Applied Science Publishers Ltd in 1973, which are incorporated by 
reference in the present description. 
The conditions of manufacture of the block copolymers forming part of the 
composition of the slit film yarn according to the invention are chosen so 
that these copolymers contain more than 50% by weight of propylene 
homopolymer, relative to their total weight. 
These block copolymers preferably comprise between 60 and 95% by weight of 
propylene homopolymer and between 40 and 5% by weight of random copolymer. 
The best results are obtained when these block copolymers comprise between 
75 and 90% by weight of propylene homopolymer and between 25 and 10% by 
weight of random copolymer. 
The ethylene content of the random copolymer is such that the weight of 
ethylene, relative to the total weight of the block copolymer, is between 
2 and 20% by weight, preferably between 4 and 15% by weight. The best 
results are obtained when 5 to 10% of the total weight of the block 
copolymer consists of ethylene. 
The conditions of manufacture of the block copolymers forming part of the 
composition of the slit film yarn according to the invention are 
preferably chosen so as to make their average molecular weight, expressed 
through the melt flow index (MFI), sufficiently high. In general, the MFI 
(measured at 230.degree. C. under a load of 2.16 kg/cm.sup.2 according to 
ASTM standard D-1238) of these block copolymers is between 0.1 and 10 g/10 
min. The MFI is preferably between 0.3 and 3 g/10 min. It has been found 
that block copolymers of too high MFI produce slit film yarn whose 
resistance to fibrillation is not sufficient. 
In addition to the block copolymers defined above, which form its main 
constituent (preferably at least 80% by weight), the slit film yarn 
according to the invention may also contain other polyolefins and 
conventional ingredients. 
Ethylene polymers may be mentioned by way of other polyolefins which can 
form part of the composition of the slit film yarn. All commercial 
ethylene polymers can be suitable, such as high-density (above 0.960), 
medium-density (between 0.930 and 0.960) and low-density (below 0.930) 
polyethylenes. Linear low-density polyethylenes are preferred because they 
contribute to improving the abrasion resistance and the flexibility of the 
slit film yarn. 
When present in the slit film yarn according to the invention, these other 
polyolefins generally constitute 1 to 20% of the total weight, preferably 
2 to 15% of the total weight. 
The conventional ingredients which can also be incorporated in the slit 
film yarn include, without any limitation being implied, antioxidants, 
light stabilizers, processing aids, reinforcing agents, pigments, 
colorants, fillers, antistatic agents and, especially in the case of the 
application of the slit film yarn to the manufacture of synthetic lawn, 
agents lowering the friction coefficient, especially those (polyethylene 
terephthalate and polytetrafluoroethylene) disclosed in the document 
EP-A-0,259,940, referred to above, the entire content of which is 
incorporated by reference in the present application. 
These conventional ingredients may be present in the slit film yarn 
according to the invention in quantities which are generally between 0.01 
and 15% by weight, preferably between 0.1 and 10% by weight. 
The optional incorporation of the other polyolefins and of the conventional 
ingredients in the compositions based on block copolymer from which the 
slit film yarn according to the invention is manufactured can be carried 
out by any other known process. This incorporation can be carried out, for 
example, by dry blending, by extruding a mixture of the various 
constituents, by the conventional masterbatch technique, or the like. 
The manufacture of the slit film yarn itself from the compositions 
described above can also be carried out according to any known methods. It 
is possible, for example, to manufacture a primary film by extruding the 
said compositions using so-called "blown film" or "flat die" methods. 
According to the latter, the film leaving the die is cooled by rolls 
containing internally circulating fluid (chill roll) or by a water bath. 
This primary film is then slit into slit film yarn which is drawn before 
being reeled up. 
Alternatively the primary film may be a multi-layer composite obtained by 
coextrusion so as to obtain a central layer of a composition similar to 
that described above and one or more surface layer(s) based on the "other 
polyolefins" also described above. 
In the case of the use of this slit film yarn for the manufacture of 
synthetic lawn, in particular, the yarn may be fibrillated mechanically 
into finer strands having the appearance of lawn blades and capable of 
being subjected to any one of the known treatments conferring suppleness, 
disclosed, for example, in document EP-A-0,259,940. 
The production of the synthetic lawn may be carried out conventionally from 
this slit film yarn, optionally mechanically twined and fibrillated, as 
already said, by tufting through a synthetic substrate such as a woven or 
nonwoven cloth, both based on thermoplastic polymer (for example 
polypropylene).

EXAMPLE 1 
An extrudable composition is prepared by incorporating linear low-density 
polyethylene and calcium carbonate, by the masterbatch method, into a 
block copolymer of propylene and ethylene, stabilized in a conventional 
manner. The extrudable composition thus obtained contains: 
90% of the block copolymer, which contains 82% by weight of propylene 
homopolymer and 18% by weight of random copolymer of propylene and 
ethylene. This block copolymer, whose ethylene content is 7.75% by weight, 
is marketed by Solvay & Cie under the name Eltex P RF 003 PF and has an 
MFI of 1.1 g/10 min; 
8% by weight of linear low-density polyethylene; 
2% by weight of calcium carbonate. 
This granulated composition is extruded in the form of a film 95 microns in 
thickness, cooled by passing through a water bath at a temperature of 
37.degree. C., slit into slit film yarn, which is drawn at a draw ratio of 
approximately 1:4.1 in a drawing oven heated to a temperature of 
130.degree. C., and is fibrillated mechanically. 
This slit film yarn is tufted through a polypropylene cloth so as to 
produce a synthetic lawn carpet, samples of which (length: 1.2 m, width: 
12 cm) are subjected to a crushing and abrasion test on a Tretrad BMX-B 
apparatus, according to the DIN draft standard 54322 (1000 cycles). The 
crushing and tearing (post-fibrillation) resistance is assessed by 
measuring the proportion (expressed in %) of the initial length of the 
slit film yarn of the sample which has been torn away. 
In the case of the sample of Example 1, only 3.3% of the initial length has 
been torn away. 
This measurement is supplemented by a visual inspection of the sample after 
the crushing test. 
In the case of the sample of Example 1, practically no surface wear can be 
seen. The slit film yarn of the sample is neither flattened nor 
postfibrillated. 
EXAMPLE 1R 
This example is provided by way of comparison. 
Example 1 is reproduced, except that the block copolymer is replaced with a 
homopolymer marketed by Shell under the name Carlona P. 
Samples prepared as in Example 1 are subjected to the test described in 
this example. At the end of this test, 4% of the initial length of the 
slit film yarn of the sample has been torn away. The slit film yarn of the 
sample is flattened and postfibrillated. 
EXAMPLE 2R 
This example is provided by way of comparison. 
Example 1 is reproduced, except that the block copolymer is replaced with a 
random copolymer of propylene and ethylene, containing 1.9% by weight of 
ethylene. 
Samples prepared as in Example 1 are subjected to the test described in 
this example. At the end of this test 15.5% of the initial length of the 
slit film yarn of the sample has been torn away. The slit film yarn of the 
sample exhibits a postfibrillation which is not shown by that according to 
Example 1. 
EXAMPLES 2 AND 3 
Example 1 is reproduced with block copolymers which differ slightly from 
that employed in this example. 
The characteristics of the tests and their results are collated in the 
table below. 
TABLE 
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Example 2 Example 3 
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Content of the propylene 
85 79 
homopolymer in the block 
copolymer (wt %) 
Ethylene content of the 
6.5 9 
block copolymer (wt %) 
MFI of the block 0.65 2.5 
copolymer 
(g/10 min) 
% of the length torn away 
3.5 3.5 
Surface state no slight 
(visual assessment) 
flattening 
post- 
no post- fibrillation 
fibrillation 
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