JPH03121825A - Manufacture of low temperature heat-sealing polyester film - Google Patents

Abstract

PURPOSE:To manufacture a low temperature heat-sealing polyester film economically by feeding raw melting point polyester resin pellets in the uncrystalline and undried state into a biaxial extruder directly, carrying out melting and dehydrating simultaneously, and then laminating with a high melting polyester layer in a die and coextruding. CONSTITUTION:When a low temperature heat-sealing polyester film composed of a high melting point polyester layer having the melting point of 230 deg.C or over and a low melting point polyester layer having the melting point of 150 deg.C or under formed at least on one surface of said high melting polyester layer, first, low melting polyester resin pellets in the uncrystalline and undried state are fed directly into a biaxial extruder provided with a vacuum vent device and melting and dehydrating simultaneously. Also, dried pellets of the high melting polyester resin are fed into a conventional high speed discharge extruder and melt extruded. High melting polyester resin and low melting point polyester resin in the molten state are guided to a multimanifold type or feed-block type multi-layer die and laminated therein. A film extruded out of the multi-layer die is solidified on a cooling roll, and then stretched in the vertical and horizontal directions simultaneously by a tenter type simultaneous biaxial stretching machine.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an economically advantageous method for producing a polyester film having excellent low-temperature heat-sealability.

[Conventional technology]

Polyester films, typified by polyethylene terephthalate, have excellent mechanical and thermal properties and are relatively easy to mold, so they are widely used as a typical plastic film in industrial and packaging applications. Furthermore, films in which a resin with a special function is laminated on the surface of a base polyester film have been widely used as an application example that takes advantage of the characteristics of the base polyester film.

In particular, a film in which a heat-sealable resin is laminated on the surface of a base polyester film can be completed as a packaging material without laminating a sealant film such as polyethylene in a post-process, so it is particularly important to use this film in-line in the polyester film manufacturing process. This manufacturing method is now attracting attention as a low-cost packaging material manufacturing method. Typical methods for laminating a heat-sealable low melting point resin layer on the surface of a polyester film in-line during the polyester film manufacturing process include coating the surface of the base polyester film with an aqueous dispersion of a low melting point resin, or This is a method of multilayer coextrusion of a melting point resin and a polyester resin serving as a base material.

[Problem to be solved by the invention]

However, in the case of the method of coating the surface of the base polyester film with an aqueous dispersion of a low melting point resin, it is necessary to dry the water after coating the aqueous dispersion of a low melting point resin. If is large, the time required for drying will be longer, so it is necessary to reduce the thickness or reduce the line speed. Furthermore, if the thickness of the coating layer is thin, the heat-sealing strength will generally be weak, so it is difficult to produce a film with excellent heat-sealing strength at high speed, that is, in an economically superior manner, using this method.

Next, in the case of multilayer coextrusion of a low melting point resin layer and a polyester resin layer serving as a base material, there are two choices as the low melting point resin: a different polymer such as polyolefin, and a low melting point polyester copolymer. When using the former type of different polymers, it is difficult to economically produce it because an adhesive resin is required to bond the two together, and it is difficult to collect and reuse waste film. Also,
The problems when using the latter polyester copolymers are the drying of the raw material pellets and the difficulty of extrusion techniques for low-melting copolymers. A polyester copolymer with a melting point of 150° C. or lower does not crystallize easily, and the pellets are susceptible to blocking at high temperatures, making it necessary to dry for a long time using a low-temperature dryer, which impedes economic efficiency. Also,
Low melting point polyester copolymers generally have low viscosities when produced by economically reasonable polymerization processes, and these two properties make them difficult to melt form in conventional extruders.

Next, when a polyester film is biaxially stretched, the excellent properties of the resin are revealed, so most polyester films can be said to be biaxially stretched films.

Biaxial stretching of polyester film is generally carried out by the biaxial stretching method, that is, stretching in the vertical direction is carried out using a vertical stretching machine consisting of a group of hot rolls, and stretching in the horizontal direction is carried out by gripping both ends of the film with clips and widening the width. A method using a stretching machine is adopted. A film with a low-temperature heat-sealable resin layer laminated on its surface tends to stick to the hot roll of a vertical stretching machine, so either limit the melting point of the heat-sealable resin, or vertically stretch only the base film first, and then A low-temperature heat-sealable resin is laminated on the vertically stretched film using a coating method,
It is necessary to horizontally stretch this laminated film. However, if a copolyester with a high melting point that does not stick to the hot rolls of a vertical stretching machine is selected, the heat sealing performance will deteriorate. Advanced drying technology is required, and the equipment is complex.
As the size increases, it becomes difficult to say that it is an economical method.

[Means to solve the problem]

The present inventors have discovered that a suitable twin-screw extruder with a screw configuration has a surprising effect on the melt extrusion of polyester resin, that is, it performs drying of the resin, which is generally indispensable during melt extrusion of polyester resin. I learned that extrusion molding is possible without Polyester resin is easily hydrolyzed, so it is usually reduced to 50pP of moisture etc. before extrusion.
It is known that the viscosity decreases during melting unless it is lowered to below m. However, if the resin is rapidly melted using a twin-screw presser equipped with an appropriate screw shape and vacuum vent system, and the resin is degassed immediately after melting, the moisture content can be reduced to about 0.4%, which is the equilibrium moisture content of polyester. There is almost no change in viscosity even when pellets containing the I learned that with a shaft press ratio machine, stable biting is possible without blocking.

By utilizing this knowledge, the present inventors found that a low-temperature heat-sealable polyester film could be manufactured by an economically superior method, and thus arrived at the present invention. That is, in a method for producing a low temperature heat-sealable polyester film comprising a high melting point polyester layer having a melting point of 230° C. or higher and a low melting point polyester layer having a melting point of 150° C. or higher applied to at least one side of the core layer, uncrystallized, Undried pellets of low-melting polyester resin are directly fed into a twin-screw extruder equipped with a vacuum vent device to perform melting and dehydration at the same time, then led to a multilayer extrusion die, where they are laminated with a high-melting polyester layer. This is a method for producing a low-temperature heat-sealable polyester film, which is characterized by coextruding the film.

The screw shape of the twin-screw extruder needs to be selected optimally according to the properties of the low-melting point polyester resin, but the most typical combination is a screw shape that restricts the feed amount from the upstream of the screw to the F flow. Some parts, such as a screw with a small lead, a kneading disk for rapidly melting the resin, a brake device installed just before the vacuum vent part, such as a reverse thread screw, a reverse thread kneading disc, a sealing ring, etc. are preferably used. 1OT
Vacuum vent 1-device that can realize a vacuum state of orr or higher,
It consists of a part of the feeding screw.

In addition, by installing vacuum vent equipment in two stages, dehydration,
It is also suitable to carry out the degassing more completely.

It is also possible to improve film thickness accuracy by introducing pellets into the twin-screw extruder through a measuring device such as a screw feeder or rotary valve, and by installing a melt measuring device such as a gear pump after the twin-screw extruder. This is a preferred method for the purposes of the invention.

The high melting point polyester resin constituting the base film is melt-extruded by charging a dry pellet into a conventional high-speed extruder, such as a single-screw extruder or a tandem extruder.

The molten high melting point polyester resin and low melting point polyester resin are introduced into a multi-manifold type or foot flock type multilayer die, and the polyester resin is laminated on one or both sides of the polyester resin. The thickness ratio of the high melting point resin and the low melting point resin is generally in the range of 1/1 to 10/1.

The film extruded from the multilayer die is solidified on a cooling roll, and then simultaneously stretched in the vertical and horizontal directions using a tenter-type simultaneous biaxial stretching machine.

A tenter-type simultaneous biaxial stretching machine grips both ends of an unstretched film with clips running in an oven, and increases the distance between opposing crimps in the vertical direction by expanding the clip pitch in the vertical direction in the stretching zone. Stretch simultaneously in the horizontal direction by expanding the , and after stretching,
This device is equipped with a zone for heating and setting the film while holding both ends with clips, and a zone for cooling.

In the stretching zone, the stretching speed ratio between the longitudinal direction and the transverse direction is suitably in the range of 0.5 to 2.0, and the final stretching ratio is preferably 3.0 to 4.5 times in both the longitudinal direction and the transverse direction.

In the simultaneous biaxial stretching machine, since the film is heated by blowing hot air, the low melting point film layer does not deform even if the film temperature exceeds the melting point of the low melting point polyester resin. Films laminated with low melting point resins by coextrusion are stretched by tenter simultaneous biaxial stretching, which does not require contact with hot rolls, thereby eliminating constraints related to low melting point resins, such as melting point and melting point with the base film. This makes it possible to freely select resins according to quality goals.

Polyethylene terephthalate is typical of the high melting point polyester resin having a melting point of 230° C. or higher in the method of the present invention. A low melting point polyester resin with a melting point of 150°C or less is one that contains a dicarboxylic acid component other than terephthalic acid, for example, a copolymerized component such as isophthalic acid, sebacic acid, adipic acid, etc., or one that contains a diol component other than ethylene glycol. It contains components such as neopentyl glycol, diethylene glycol, hexanediol, etc. as a copolymerized component, and some have a melting point of 150° C. or lower as measured by DSC. In order to obtain practical strength with a general-purpose sealing device, the melting point must be 150°C or lower.

Note that, if necessary, a lubricant, an antistatic agent, etc. can also be added to the polyester resin.

[Effect]

A film in which a low melting point polyester resin with a melting point of 150°C or less is laminated on one or both sides of a base polyester layer is a lamination of the same polyester resin, so an interface that does not peel off even when stretched without an adhesive layer can be easily created, and the lamination Polyester copolymers have the advantages of being easy to control the optical properties of the film and relatively easy to recycle waste film.Moreover, polyester copolymers allow the type and amount of copolymer components to be selected from a wide range. It is possible and
It is easy to design products that suit the purpose. However, molding of these low melting point copolymers has not been easy in the past. The main reason for this is that pellets are difficult to crystallize and have a low melting point, making it impossible to raise the drying temperature and requiring drying at low temperatures with slow drying speeds, resulting in extremely high drying costs and economical costs. It has been extremely difficult to extrude low melting point copolymers in a financially advantageous manner.

According to the method of the present invention, a drying step is not necessary, and as a result, it becomes possible to economically produce a low-temperature heat-sealable polyester film.

In addition, by using a tenter-type simultaneous biaxial stretching machine that can heat and cool without contacting the surface of hot rolls, etc., it is possible to combine coextrusion lamination and biaxial stretching. It becomes possible to produce an axially stretched low-temperature heat-sealable polyester film.

〔Example〕

65 ceramic diameter single screw extruder, 30 mm diameter co-rotating two-stage vented twin screw extruder, rl] A two-layer extrusion device with a 400 mm feed block type two-layer coextrusion die as the basic component is used. The axial extruder has crystallized and dried (moisture content 50)
ppm) high melting point polyester A and undried (moisture content 0.35%) low melting point polyester B were charged into a twin-screw extruder to produce a two-layer coextruded film.

Polyester A: Polyethylene terephthalate Relative viscosity 1.38 Melting point 252°C Polyester B: Polyethylene terephthalate, polyethylene isophthalate copolymer (isophthalate copolymerization rate 40 mol%) Relative viscosity 1.33 Melting point 110°C Obtained The film is stretched at a temperature of 1 using a tenter-type simultaneous biaxial stretching machine.
At 05℃, 3.3 times the vertical direction and 3.5 times the horizontal direction simultaneously 2
After axial stretching, heat treatment was performed at a temperature of 225° C. for 5 seconds. The obtained film had a thickness of 12 μm for the polyester A layer and a thickness of 4 μm for the 8 polyester layers, and when heat-sealed at 160° C., the sealing strength was 600 g/15 trtn width or more.

[Effects of the Invention] According to the present invention, by laminating the same polyester resins, an interface that does not peel off even when stretched can be easily created, the optical properties of the laminated film can be easily controlled, and waste film can be recycled relatively easily. In addition to having the advantage of being easy to carry out, the type and amount of copolymerization components can be selected from a wide range with Bolier and stellate copolymers, making it easy to design products that suit the purpose. is not necessary, making it possible to economically produce a low-temperature heat-sealable polyester film.

Claims (2)

[Claims] (1) A method for producing a low-temperature heat-sealable polyester film comprising a high-melting point polyester layer with a melting point of 230°C or higher and a low-melting point polyester layer with a melting point of 150°C or lower applied to at least one side of the layer. crystal,
Undried low-melting point polyester resin pellets are directly fed into a twin-screw extruder equipped with a vacuum vent device to simultaneously melt and dehydrate, then led to a multilayer extrusion die, where they are laminated with a high-melting point polyester layer. A method for producing a low-temperature heat-sealable polyester film, which comprises coextruding the film. (2) The method for producing a low-temperature heat-sealable polyester film according to claim 1, characterized in that the laminated film obtained in item 1 is simultaneously biaxially stretched to an areal stretching ratio of 600% or more. .