 |
Description  |
|
|
BACKGROUND OF THE INVENTION
The present invention relates to a coextrusion multi-layer tubular film.
More particularly, it is concerned with a coextrusion multi-layer tubular
film which is superior in mechanical strength and transparency, and
further which is free from curling even in the high-speed quenching
molding method and does not cause blocking.
Heretofore, tubular films produced by inflation molding of low density
polyethylenes produced by the high-pressure polymerization method have
been widely used as packaging films for various purposes. These films,
however, have a disadvantage in that the mechanical strength is not
sufficiently high, although they are superior in transparency.
Compared with the above low density polyethylene films, those films made of
linear low density ethylene .alpha.-olefin copolymers are superior in
mechanical strength. In recent years, therefore, such linear low density
ethylene .alpha.-olefin copolymer films have received increasing attention
from a viewpoint of saving resources through a reduction in film
thickness, and they are expected to be utilized in various fields. When,
however, such linear low density ethylene .alpha.-olefin copolymers are
molded by the commonly used inflation molding method, i.e., up blow
air-cooling inflation molding, the ultimate tubular films are not always
satisfactory in optical properties such as transparency and gloss.
Moreover, in this air cooling method, the quenching effect is low, and if
the air speed is increased, a fluctuation in resinous bubble occurs
vigorously and the molding cannot be performed stably. In any case, films
having superior transparency cannot be molded at high speeds and in a
stabilized manner.
It has, therefore, been proposed to quench the resinous bubble by the down
blow water-cooling inflation molding method which is known to have a high
quenching effect. In accordance with this method, films can be produced
which are greatly improved in transparency. On the contrary, the films are
reduced in antiblocking properties. Thus they suffer from disadvantages
that opening properties are poor and molding itself becomes difficult
owing to the occurrence of blocking. This blocking may be prevented by
increasing the amount of antiblocking agents added. If, however, the
amount of antiblocking agents added is increased, they inevitably exert an
adverse influence on transparency.
In the down blow water-cooling inflation molding method, the transparency
of films can be further improved by increasing the degree of quenching. In
this case, however, a fundamental and serious problem arises in that the
film is curled toward the inside thereof. If this curling occurs, there
can be obtained only films which have a appearance. Thus the films are low
in product value. Moreover they have disadvantages in that handling during
the molding and cutting process is difficult, workability for printing and
production of bags drops, and the ultimate bags are bad in appearance due
to the formation of stains, for example, in the production thereof. In the
down blow water-cooling inflation molding method, although an improvement
in transparency of films can be attained, the above problems of blocking
and curling are undesirably involved.
As described above, tubular films of linear low density ethylene
.alpha.-olefin copolymers, which are superior in transparency, have good
opening properties and anti-blocking properties, and further are reduced
in curling, have not yet been produced.
SUMMARY OF THE INVENTION
As a result of extensive investigations to develop linear low density
ethylene .alpha.-olefin copolymer films which are superior in transparency
and are usable for practical purposes, it has been found that if an inner
layer made of a polypropylene-based resin or a resin composition composed
mainly of the polypropylene-based resin is provided, there can be obtained
tubular films which are superior in transparency, opening properties, and
anti-blocking properties, for example, and are reduced in the formation of
curl.
The present invention relates to a coextrusion multi-layer tubular film
comprising:
an outer layer made of a linear ethylene .alpha.-olefin copolymer having a
density of from 0.900 to 0.945 gram per cubic centimeter; and
an inner layer made of a polypropylene-based resin, or a resin composition
comprising a polypropylene-based resin and an ethylene .alpha.-olefin
copolymer having a density of from 0.850 to 0.945 gram per cubic
centimeter.
BRIEF DESCRIPTION OF THE DRAWING
The figure is a schematic illustration of an embodiment of the down blow
multi-layer water-cooling inflation molding method.
1, 1'. . . extruders, 2 . . . circular die, 3 . . . air ring, 4 . . .
cooling water, 5 . . . resinous bubble
DETAILED DESCRIPTION OF THE INVENTION
The outer layer of the coextrusion multi-layer tubular film of the present
invention is made of a linear ethylene .alpha.-olefin copolymer having a
density of from 0.900 to 0.945 gram per cubic centimeter, preferably from
0.910 to 0.940 gram per cubic centimeter. The melt index of the linear
ethylene .alpha.-olefin copolymer is from 0.5 to 20 grams per ten minutes
and preferably from 1.0 to 10 grams per ten minutes.
The linear ethylene .alpha.-olefin copolymer is a linear low density
polyethylene as produced by the medium or low pressure polymerization
method. .alpha.-Olefins (excluding ethylene) which are to be copolymerized
with ethylene are not critical in the present invention. Usually,
.alpha.-olefins having from 3 to 15 carbon atoms, preferably from 4 to 12
carbon atoms, such as propylene, butene-1, pentene-1, hexene-1, octene-1,
4-methylpentene-1, decene-1, and dodecene-1 are used. The .alpha.-olefin
content of the linear low density ethylene .alpha.-olefin copolymer is
usually from 1 to 20 percent by weight, and its melting point is from
110.degree. to 130.degree. C. As well as a single linear low density
ethylene .alpha.-olefin copolymer, a mixture of copolymers having
different densities and/or melt indexes can be used.
In the preparation of the inner layer of the co-extrusion composite tubular
film of the present invention, a polypropylene-based resin or a resin
composition comprising a polypropylene-based resin and an ethylene
.alpha.-olefin copolymer having a density of from 0.850 to 0.945 gram per
cubic centimeter is used. This polypropylene-based resin includes, as well
as a propylene homopolymer, block and random copolymers of propylene and
20 percent by weight or less of one or more other .alpha.-olefins such as
ethylene, butene-1, hexene-1, and 4-methylpentene-1. Usually those
polypropylene-based resins having a density of from 0.895 to 0.915 gram
per cubic centimeter, a melting point of from 130.degree. to 175.degree.
C., and a melt index of from 0.5 to 20 grams per ten minutes, preferably
from 1.0 to 15 grams per ten minutes are used.
The objects of the present invention can be attained by using the
above-defined propylene-based resin alone in the preparation of the inner
layer of the coextrusion multi-layer tubular film of the present
invention; that is, even if the inner layer is made of the
polypropylene-based resin alone, there can be obtained a coextrusion
multilayer tubular film which is superior in transparency and antiblocking
properties, and further in which the formation of curl is prevented. In
some cases, however, melt sealability during the bag-production process is
not always sufficiently satisfactory depending on the type of the
polypropylene-based resin, molding conditions, ratio of inner layer and
outer layer, and so forth. It is preferred, therefore, that the inner
layer of the coextrusion multi-layer tubular film of the present invention
be made of a resin composition comprising the polypropylene-based resin
and an ethylene .alpha.-olefin copolymer having a density of from 0.850 to
0.945 gram per cubic centimeter.
The ethylene .alpha.-olefin copolymer includes the above-described linear
ethylene .alpha.-olefin copolymers, and ethylene .alpha.-olefin copolymers
which are of low crystallinity or are non-crystalline. When a linear low
density ethylene .alpha.-olefin copolymer is used in the preparation of
the inner layer, it may be the same as or different from that used in the
preparation of the outer layer. Low crystallinity or non-crystalline
ethylene .alpha.-olefin copolymers include copolymers of ethylene and
.alpha.-olefins haivng from 3 to 12 carbon atoms, such as propylene,
butene-1, and hexene-1, and terpolymers of the above copolymers and a
third component, such as butadiene, 1,4-hexadiene, and
5-ethylidene-2-norbornen. For these ethylene .alpha.-olefin copolymers,
the density is from 0.850 to 0.910 gram per cubic centimeter, preferably
from 0.860 to 0.900 gram per cubic centimeter, the melt index is from 0.1
to 50 grams per ten minutes, the degree of crystallization is 40 percent
or less, and the melting point is 100.degree. C. or less. Typical examples
of these ethylene .alpha.-olefin copolymers are an ethylene propylene
copolymer, an ethylene butene-1 copolymer, and an ethylene propylene
5-ethylidene-2-norbornene terpolymer.
The resin composition for the inner layer of the co-extrusion multi-layer
tubular film of the present invention is composed of from 60 to 98 percent
by weight of the polypropylene-based resin and from 40 to 2 percent by
weight of the ethylene .alpha.-olefin copolymer, and preferably from 70 to
97 percent by weight of the polypropylene-based resin and from 30 to 3
percent by weight of the ethylene .alpha.-olefin copolymer. If the
proportion of the ethylene .alpha.-olefin copolymer is less than 2 percent
by weight, the melt sealability is improved only insufficiently. On the
other hand, if it is in excess of 40 percent by weight, transparency and
antiblocking properties of the film are reduced and melt sealability is
not always increased.
In the coextrusion multi-layer tubular film of the present invention, it is
necessary that the thickness of the outer layer be at least 50 percent of
the total thickness of the film. The ratio of outer layer and inner layer
is usually from 50:50 to 98:2 and preferably from 60:40 to 95:5. If the
ratio of outer layer and inner layer ratio is less than 50:50, the best
use cannot be made of the superior characteristics of the film of linear
low density ethylene .alpha.-olefin copolymers. On the other hand, if the
ratio is more than 98:2, the formation of curl cannot be prevented in
molding by the down blow water-cooling inflation molding method.
The coextrusion multi-layer tubular film of the present invention basically
comprises an outer layer and an inner layer as described above. If
necessary, a layer of low density polyethylene produced by the high
pressure polymerization method, for example may be further provided on the
outside of the outer layer by coextrusion. That is, the term "coextrusion
multi-layer tubular film" as used herein includes a coextrusion
multi-layer tubular film comprising the above two essential layers and one
or more additional layers.
In the resins constituting the outer and inner layers of the coextrusion
multi-layer tubular film of the present invention may be incorporated
stabilizers (e.g., anti-oxidants and ultraviolet absorbers), lubricants,
anti-blocking agents, antistatic agents, and colorants, for example,
within the range that does not deteriorate the characteristics of the
coextrusion multi-layer tubular film. To the polypropylene-based resin for
the inner layer, nucleating agents can be added. These nucleating agents
function to control a rate of formation of crystal nuclei in the
polypropylene-based resin, to accelerate the rate of crystallization, and
further to control the size of crystals. Organic nucleating agents include
metal salts of organic acids, such as magnesium, calcium, sodium,
aluminum, or titanium salts of benzoic acid, cyclohexanecarboxylic acid,
diphenylacetic acid, isonicotinic acid, adipic acid, sebacic acid,
phthalic acid, benzenesulfonic acid, and glycolic acid; amine salts of
organic acids, such as amines derived from benzoic acid, phthalic acid,
and adipic acid; and dibenzylidene-sorbitol. Inorganic nucleating agents
include finely powdered silica, alumina, and talc. Addition of such
nucleating agents enables an increase in the transparency and
curl-preventing properties of the ultimate film.
In addition to additives as described above, other thermoplastic resins and
elastomers, for example, can be added within the range that does not
deteriorate the characteristics of the coextrusion multi-layer tubular
film of the present invention.
The coextrusion multi-layer tubular film of the present invention can be
produced by various molding techniques. For example, the respective resins
of the outer and inner layers are melt kneaded in an extrusion molding
machine, extruded through a circular die, and then molded by the down blow
water-cooling inflation molding method or the up blow air-cooling
inflation molding method or the spray cooling inflation molding method,
for example. Particularly preferred is the down blow water-cooling
inflation molding method, an embodiment of which is schematically
illustrated in the figure, in view of cooling efficiency, molding speed,
high transparency of the ultimate film, etc.
The blow up ratio in the inflation molding is usually from 0.8 to 3.0 and
preferably from 1.0 to 2.5. Corn starch, for example, may be sprayed on
the outer surface of the produced film for the purpose of preventing
blocking. The thickness of the coextrusion multi-layer tubular film of the
present invention is not critical and usually from 5 to 200 microns; it is
determined appropriately within the above range depending on the purpose
for which the ultimate film is used.
The coextrusion multi-layer tubular film of the present invention has
various advantages. For example, since the above-specified resins are used
in the prepartion of the outer and inner layers of the coextrusion
multi-layer tubular film, even if quenching, particularly water-cooling is
applied in inflation molding of the film, the problem of curling as
encountered in producing a single-layer film of linear low density
ethylene .alpha.-olefin copolymers does not arise. Furthermore the problem
of blocking as involved in quenching does not occur at all; rather the
quenching using water permits to more increase the transparency of the
film.
The coextrusion multi-layer tubular film of the present invention is
superior in moldability, transparency, anti-blocking properties, strength,
and so forth, and further is free from curling. Thus it is superior in
fabricability (conversion characteristics of film) such as printing and
bag-production. In particular, the transparency of the coextrusion
multi-layer tubular film of the present invention is very high compared
with conventional tubular films made mainly of linear low density
polyethylenes. Thus the coextrusion multi-layer tubular film of the
present invention is useful as a packaging material for clothes,
foodstuffs, and general goods, for example. In particular, in view of its
transparency and polyvinyl alcohol film like flexibility, it is very
useful as a cloth-packaging material.
The present invention is described in greater detail with reference to the
following examples.
EXAMPLES 1 TO 10
Resins for the outer and inner layers as shown in Table 1 were supplied to
the respective extruders (diameter: 50 millimeters; L/D=26) where they
were melt kneaded. They were then introduced in a circular die (diameter:
150 millimeters; die lip clearance: 2 millimeters) and coextruded
downwardly therethrough at a rate of 50 kilograms per hour, and molded
into a film by the down blow water-cooling inflation molding method (where
the outer peripheral surface was cooled with cooling water maintained at
25.degree. C.) at a blow up ratio of 1.3 to produce a coextrusion
two-layer tubular film having a thickness of 40 microns.
The melting point of the resin was measured according to ASTM D-3417 by the
use of a differential scaning calorimeter (DSC) and a temperature
corresponding to the peak of an endothermic curve was determined as the
melting point.
Physical properties and sealability of the films were measured, and the
results are shown in Table 1.
COMPARATIVE EXAMPLE 1
A tubular film was produced in the same manner as in Example 1 except that
the propylene-based resin was replaced by a high density polyethylene
resin. The results are shown in Table 1.
COMPARATIVE EXAMPLE 2
A single layer film of a linear low density polyethylene was produced
following the procedure of Example 1. The results are shown in Table 1.
TABLE 1
__________________________________________________________________________
Tensile Tensile
Outer Layer/
Strength*.sup.1
Elongation*.sup.1
Modulus*.sup.1
Resin of
Resin of Inner Layer
(MD/TD)
(MD/TD) (MD/TD)
Run No.
Outer Layer
Inner Layer
Ratio kg/cm.sup.2
% kg/cm.sup.2
__________________________________________________________________________
Example 1
LLDPE-1 PP-1 90/10 404/310
680/700 2450/2750
Example 2
LLDPE-1 PP-1 80/20 413/352
660/720 3960/3900
Example 3
LLDPE-1 PP-1 70/30 438/369
620/700 4650/4640
Example 4
LLDPE-1 PP-2 80/20 372/367
610/700 2660/3260
Example 5
LLDPE-2 PP-1 80/20 410/348
640/680 3800/3700
Example 6
LLDPE-1 PP-1 95 80/20 425/350
620/680 3900/3800
LLDPE-1
5
Example 7
LLDPE-1 PP-1 90 80/20 439/346
560/640 3810/3740
LLDPE-1
10
Example 8
LLDPE-1 PP-1 90 70/30 -- -- --
LLDPE-1
10
Example 9
LLDPE-2 PP-1 90 80/20 -- -- --
LLDPE-2
10
Example 10
LLDPE-1 PP-1 95 80/20 -- -- --
EPR 5
Comparative
LLDPE-1 HDPE 80/20 475/358
660/770 3010/3000
Example 1
Comparative
LLDPE-1 -- 410/322
620/740 1820/1760
Example 2
__________________________________________________________________________
Tear Anti-
Seal
Strength*.sup.1
Impact
Puncture Blocking
Temper-
Seal
(MD/TD)
Strength*.sup.2
Strength*.sup.3
Haze*.sup.4
Gloss*.sup.5
Anti-
Proper-
ature
Strength*.sup.7
Run No.
kg/cm kg .multidot. cm/cm
kg .multidot. cm/cm
% % Curling*.sup.6
ties .degree.C.
kg/25 mm
__________________________________________________________________________
Example 1
90.0/154
1820 11300 2.3 172 A A 300 0.75
Example 2
76.0/146
1780 12900 2.1 162 A A 300 0.68
Example 3
55.0/163
1890 12700 2.0 161 A A 300 0.65
Example 4
83.0/160
2020 12200 1.2 164 A B 260 0.64
Example 5
74.0/140
1750 12800 1.8 163 A A 300 0.70
Example 6
68.0/170
1900 13200 4.0 130 A A 250 0.95
Example 7
56.8/190
2110 13400 4.1 115 A A 250 1.01
Example 8
-- -- -- 4.2 -- A A 250 1.12
Example 9
-- -- -- 4.2 -- A A 250 0.98
Example 10
-- -- -- 7.4 101 A A 260 1.08
Comparative
116/99.2
1900 9640 6.5 103 B A -- --
Example 1
Comparative
167/212
2800 14300 1.5 140 C C -- --
Example 2
__________________________________________________________________________
Note:
Density
Melt Index
Melting Point
(g/cm.sup.3)
(g/10 min)
(.degree.C.)
LLDPE-1
Ethylene octene-1 copolymer
0.927
4.9 125
LLDPE-2
Ethylene 4-methyl-pentene-1 copolymer
0.925
2.4 124
PP-1 Propylene homopolymer
0.91 8.0 170
PP-2 Propylene random polymer
0.90 7.0 155
EPR Ethylene propylene copolymer
0.86 1.9 --
HDPE High density polyethylene
0.955
0.05 132
*.sup.1 Measured according to JIS Z1702.
*.sup.2 Measured according to JIS P8134.
*.sup.3 Measured by the film impact method. A film specimen is fixed in
the form of a ring and punctured with a pendulum
having a 1-inch impact head, and an amount of energy needed for this is
measured.
*.sup.4 Measured according to ASTM D1003.
*.sup.5 Measured according to ASTM D523.
*.sup.6 Determined by observing the films with the naked eye. The rating
scale is as follows:
A: No curling, B: Curling occurs to a certain extent, C: Curling occurs
seriously.
*.sup. 7 Measured according to JIS Z1707.
* * * * *
|
|
 |
|
 |
Description |
|
