BE632717A - - Google Patents

Description

       

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  '' Improvements in film production. tubular.!
The present invention relates to the manufacture of tubular films and, in particular, to tubular films of thermoplastic organic film forming materials, where the physical properties of the film, such as tensile strength, are formed. are improved by reprocessing at temperatures below the melting point or the softening point of the thermoplastic material, but close to this melting or softening point.

   Examples include tubular films of polypropylene, polyesters and polyvinyl chloride.

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 dandruff that particularly benefits from this treatment *
British Patent No. b40,191 discloses a continuous stretching process of isotactic polypropylene film where a freshly extruded tubular film of isotactic polypropylene is quenched with coolant and is then fine to pass between two spaced pairs of cylinders at clamp where it is heated to a temperature in the range of 12000 to 170 C by infrared heaters and is radially stretched by internally applied air pressure and,

   longitudinally. by the second set of clamp cylinders, which rotate at a peripheral speed greater than that of the first pair of clamp cylinders * The pressurized air is introduced into the film by a probe which passes through a passage formed in the gripper of the first pair of gripper cylinders, thanks to the fact that at least one of the cylinders is created. Since the tubular film must be firmly gripped by the first pair of clamp rollers to trap air in the film which passes through the soft pairs of clamp rollers, the edges of the flattened film are pressed to fold.

   The folds form lines of weakness, and upon stretching the film tends to split or at least stretch preferentially along the fold lines.



   Belgian Patent No. 576,741 describes a process for the production of stretched films in which a molten tube, for example of polyvinyl chloride, is extruded into a cylindrical chamber and internally receives pressurized air. Pressurized air is passed through the chamber at a pressure equal to that inside the tube to serve the dual purpose of preventing the tube from expanding and cooling the tube below its temperature. solidification.

   The tubular film is then introduced into a second chamber through a polished groove with which the outer surface of the tube comes into contact and is heated.

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 at a temperature between 5 and 20 C below the softening point of the film. Due to the absence of a high air pressure in the second chamber, the tube expands and thus stretches the walls, under the effect of the high air pressure prevailing inside the tube.



   One of the objects of the present invention is to provide an improved process for the manufacture of stretched tubular films of organic thermoplastics **
Accordingly, the present invention comprises a process for producing stretched tubular films of organic thermoplastic film-forming materials comprising the operations of extruding an organic thermoplastic film-forming material heated so as to acquire a molten plastic state, through an annular orifice, to form a tube, to rapidly cool the tube so that it passes to the solid state by stretching the tube because above a cooled form .. to apply a gaseous fluid under:

   ression inside the tube and to apply an equilibrium pressure of a gaseous fluid to the outside of the tube, in the region where the tube is plastic, to prevent expansion of the tube, to pull the tube out of the form at a predetermined rate, without squeezing the wall of the tube to a fold and retaining a passage through the tube, heating the tube to a temperature not exceeding 2 C below the transition point defined above, in a zone stretching, an area in which the pressure is lower than the pressure prevailing in the tube, to allow the tube to expand under the influence of internal pressure to form a smooth stretched tubular film,

     pulling the tube away from the stretching zone at a rate equal to or greater than the rate at which the tube was pulled from the cooled form, and flattening the tubular film.



   By the expression &quot; transition point 1 is meant herein, for thermoplastics having a melting point &quot;

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 labeled tallin and, for example, in the case of polypropylene, the tamponade to which the materials melt.

     With regard to thermoplastic materials which do not exhibit a marked crystalline melting point, but which soften over a temperature range (for example, polyvinyl chloride) is meant by the expression '' transition point the temperature at which the tensile strength of the thermoplastic material no longer increases by stretching.
The tube passing through the stretching zone is preferably heated to a temperature not lower than 6000 below the and, y transition point / in the case of thermoplastics. having a distinct crystalline melting point,

   The tube is preferably heated to a temperature in the range of 5 ° C below the transition point to 40 ° C below the transition point.



   The gaseous fluid applied inside the tube and outside the tube in the region immediately following the die, where the tube is plastic, is advantageously constituted by air, although it may be. by nitrogen or by any other inert gas.



   The present invention also includes an apparatus for producing a stretched tubular film of an organic thermoplastic film-forming material, comprising an extrusion die having an annular orifice through which an organic thermoplastic film-forming material can be extruded into it. :

   tube shape, a shape over which the freshly extruded tube is pulled to rapidly cool the tube so that it becomes solid, a chamber enclosing the opening of the annular orifice and at least part of the shape , on which the tube passes in the plastic state, a supply means intended to introduce a gaseous fluid under pressure inside the tube, a second supply means intended to introduce a gaseous fluid under pressure.

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 .ion in the chamber an outlet opening of the chamber, opening through which the tube can be withdrawn from the sound chamber, sibly without loss of gaseous fluid from the chamber,

   a pulling means for pulling the tube out of the form at a predetermined speed, without squeezing the wall of the tube to a fold and maintaining a passage through the tube, a heating means for heating the pulled tube form in an atmosphere having a pros- .ion less than the pressure prevailing inside the tube to allow the tube to expand to form a stretched tubular film, and a flattening means for flattening the skin - 'stretched tubular core and pulling the film at a predetermined speed past the heating means.



   The pulling means for pulling the tube out of the cooled form without kinking the tube and without completely closing the tube, so that the gaseous fluid admitted inside! of the tube can pass through the tube up to the stretching zone, can advantageously consist of a pair of short clamp cylinders, of a length substantially less than the width of the tube in the flat state. The clamp cylinders only pinch the central part of the tube and leave the free edges to bulge outwards, which prevents the formation of fold lines and forms passages for the gaseous fluid.



   The flattening means advantageously consists of a pair of clamp cylinders, of sufficient length to completely close the tubular film and to substantially block the escape of gaseous fluid from the tube. The flattening means also pulls the tubular film through the stirring area.



   The cooled form preferably has a cylinder form and is mounted on the face of the die, inside the annular orifice. However, it is even more preferable to taper the shape so that it tapers away from the die.

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   - to take account of the shrinkage of the tube during its solidification and to facilitate the removal of the solidified tube from the forma. The shape is advantageously hollow to allow the circulation of a cooling fluid which, for example) may consist of air, water or cooled brine.



   An important feature of the invention is that the freshly extruded tube is rapidly cooled below the solidification temperature of the thermoplastic material to promote the formation of small crystalline or partially crystalline regions, so that when stretched the tube in the stretching zone, it stretches evenly at all points. When the cooling is slow, as is the case when ordinary air cooling is used, the material tends to form large regions, such as ines or partially crystalline with the result that, when stretching, some areas tend to stretch more than other areas.



   A preferred temperature for the cooled form is that which is within the range of OOC to 20 C.



   The gaseous fluid under pressure, introduced into the tube, can advantageously be initially introduced by a pipe which passes through the central solid of the extrusion die and through the cooled form. To compensate for the gaseous fluid which escapes through the flattening means, it may be necessary from time to time to add additional gaseous fluid through this pipe.



   The gaseous fluid applied in the chamber formed around at least a portion of the form usually has the same loan- ment as the gaseous fluid introduced into the tube and may draw advantageously from a common source of pressurized fluid. limit the escape of the gaseous fluid from the chamber to the location of the outlet opening offered to the moving tube

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 a flexible seal can be adjusted to close the space between the edge of the opening and the wall of the tube.



   Since it is preferable to form a space between the face of the die and the die to minimize the transfer of heat from the hot die to the cooled form, the gaseous fluid under pressure is preferably introduced to the die as well. inside the tube as soon as it is extruded and the gold comes out !! * annular ticks, to prevent the molten tube from being pressed into space by the pressure of the gaseous fluid contained in the chamber.



   In the drawing zone) the tube can draw heated by the heat of irradiation such as that given by infrared heaters or by circulating hot air, which is heated by passing it over heating devices, by convection or by the effect of a fan.



   As the tube expands in the stretching area, the tube wall is stretched to a degree which depends on the degree of swelling of the tube. The stretching results in at least partial orientation of the molecular structure of the tube wall in the transverse direction and fortunately affects the physical properties of the tube film thus produced.



  In particular, the tensile strength of the film in the direction of stretching is increased and the clarity of the film is improved.



   The degree of stretch imparted to the tubs upon inflation depends on the thermoplastic material used and the physical properties required for the tubular film. For example, when the organic thermoplastic material is polyvinyl chloride, a preferred ratio of the diameter of the expanded tubular film to the diameter of the tube is in the range of 1 1/2:
1 to 3: 1. However, when the organic thermoplastic material is polypropylene, the ratio of the tube diameter may be this -

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 taken between 1 1/2 :: 1 and 10: 1 and even be greater than the latter limit.

   However. a more preferred interval is that which ranges from 2: 1 to 8 t 1.



   The tube can also be stretched longitudinally while in the stretching area by pulling the film with the flattening means out of the stretching area at a rate greater than that. at which the tube is pulled from the cooled form.

   Longitudinal stretching combined with transverse stretching results in a biaxially oriented tubular film, that is, the molecular structure of the particle is at least partially oriented in where two say were, the longitudinal direction and transverse direction
For many purposes, it is desirable that the tubular film be balanced, that is, it should be stretched equally in the longitudinal and transverse directions, so that the physical properties of the film, such as that the tensile strength, are substantially equal in these two directions.

   Such a film can be obtained by proceeding so that the ratio of the speed of pulling the tubular film out of the stretching zone to the speed of pulling the tube out of the form is substantially the same as ratio of the diameter of the expanded tubular film to the diameter of the tube before expansion
If desired, alternatively, the degree of stretching in the transverse direction or in the longitudinal direction may be greater than the degree of stretching in the other direction if the film is required. has a greater resistance in one of the two directions, for example for the photographic film or the sound recording tapes.



   The process according to the present invention can be used in the production of the tubular film from any thermoplastic material suitable for extrusion into the form of.

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 tuba, and it is particularly useful for the production of films from polypropylene, for example isotactic polypropylene, polyethylene, polyesters such as polyethylene terephthalate, polyvinyl chloride and polystyrene.



   After stretching has taken place, the tubular film can, if desired, be heat-set by heating it to a temperature which is within 10 ° C of the temperature at which the stretching has taken place, but less than the transition point.



   A specific apparatus and a single method of carrying out the invention will now be described with reference to the drawings appended to the present description.



   Figure 1 is a front elevation of the apparatus, in partial section.



   Figure 2 is a section of Figure 1 taken through line 2-2.



   Reference is now made to Figure 1; a thermoplastic material in the molten state is forced by an extrusion device (not shown) through an annular orifice 1 of a die 2 to form a tube 3 which is pulled over a cooled form 4 by a pair of short pinch cylinders 5 to rapidly cool the tube 3 and bring it to the solid state.

   The solidified tube 3 is then pulled through a stretching zone, indicated generically at 6 by a pair of gripper rollers 7, the tube 3 being stretched in said stretching zone by means described below. to form a tubular film 8. The clamp cylinders 7 flatten the tube 8 and give it a flat shape in which it is spooled on a storage spool (not shown).



   The cooled form 4 is mounted on the face of the die 2 by a rod 9 to minimize heat transmission from the hot die 2 to the cooled form 4; cold water

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 is put into circulation inside the forât 4 by pipes 10,11 which pass through the center of the die 2 and by the rod 9. The shape 4 is circular in cross section and this cones so as to s' trim away from the die 2 to facilitate pulling off the solidified tube 3.

   The face of the die 2 and the major part of the body of the form 4 are enclosed in an annular chamber 12 which has a vertically movable cover 13, mounted on rods 14 to which the cover 13 can be fixed, as it is. is required, by pan head screws 15. The cover 13 is sealed, when in position on top of the chamber 12, to the wall of the chamber 12 by a circular gasket 16. In Furthermore, the cover 13 has a circular opening 17 through which the end of the cooled form 4 protrudes and in the edge of the opening 17 is housed a flexible annular seal 18 which presses lightly against the tube 3 which is and ie to be pulled over the shape 4.

   The pressurized air is filled in the chamber 12 by an inlet pipe 19 and the seals 16,18 substantially prevent it from leaking.



   The pressurized air is also introduced into a space 20 between the face of the die 2 and the form 4 by a pipe 21 to balance the pressure applied in the chamber 12 and to prevent the tube 3 which is in the state. melted, to be pressed into space 20.



   The interior of the tube 3 is kept under pressure by the air introduced by a pipe 22 which passes through the die% and the form 4 and the pressure of the air maintained in the chamber 12 is adjusted so that it balances the pressure maintained in the tube 3 and prevents the tube 3 from expanding while it is in the plastic molten state. When the process is under way and the conditions are stable, the pressures of the air applied in the chamber 12, inside the tube 3 and in the space 20 are advantageously equal *

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The gripper cylinders 5, which serve to pull the tube 3 of the form 4 are much shorter than the width of the tube 3 in its flattened state.

   The cylinders 5 clamp the central part of the tube 3 so that the edges 23 of the tube 3 bulge outwards (fig. 2), forming passages 24 for the air introduced into the tube ', which avoids the formation of folds at the edges 23.



   In the mono drawing 6, the tube 3 enters an enclosure 25 where there is a pressure which is substantially atmospheric pressure, in which the heat is directed to all the peripheral points of the tube 3 by infrared heaters 26 The intensity of the heat applied to the tube 3 is regulated so that the temperature of the wall of the tube rises to a value which does not exceed 2 ° C below the transition point of the thermoplastic material, at which temperature. the tube expands under the influence of internal pressure.



   When expanding tube 3, the wall of tube 3 is stretched transversely and the molecular structure of the tube wall is oriented or partially oriented in the transverse direction.



   As the tube 3 passes through the stretching zone, it can also be stretched longitudinally by rotating the gripper rolls 7 at a speed greater than that at which the tube 3 is pulled from the form 4 by the clamp cylinders 5.



  This stretching fully or partially orients the molecular structure of the tube wall in the longitudinal direction.



   The stretched tube 3 which has now become the tubular film 8, is withdrawn from the enclosure 25, cooled by passage through the atmosphere to room temperature and is flattened between clamp rolls 7 which also serve to prevent the escapes. air from inside tube 3 and film 8.



   If desired, the tubular film 8 can be clamped

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 heat-treated before passing through the cylinders 7, by the application of heat from, for example, infrared heaters (not shown) * The film 8 is hot-frozen by heating it to a temperature which if ** kills within 1000 of the temperature at which the stretching took place, but below the transition point of the thermoplastic.



   The degree of stretching of the tube 3 depends on the pressure applied inside the tube 3, the degree of heat applied in the enclosure 25 and the difference in speeds between the clamp cylinders 7 and the cylinders. 5. These conditions are chosen for the thermoplastic material used and for the desired or required thickness of the film.



   Although the apparatus shown in the drawing produces a tube which moves upward, the apparatus can be reversed, so that the tube is extruded and moves downward.



   In an example of making stretched tubular film of polypropylene by the process described above, the polypropylene was extruded from a die orifice at 190 C. The orifice was 3 inches in diameter and had a 0.019 inch slot. .



  An air pressure of 9 1/2 inches at the water pressure gauge was maintained in tube 3, in chamber 12 and in space 20. Form 4 was maintained at 14 C by circulating water to ensure rapid cooling of tube 3 below the solidification point of the polypropylene. Tube 3 had, leaving form 4, a diameter of 2. 3/8 inches and was pulled out by pull cylinders at 5 to 6 feet per minute.



   Upon entering enclosure 25, tube 3 was heated to 145 C by heaters 26., and it was expanded to a diameter of 10.7 inches. Tubular film 8 had a wall thickness of 0.0004 inch on a coil and was wound at a speed of 30 feet per minute.

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   The tubular film 8 had high clarity and a strength greatly exceeding the strength of unstretched polypropylene of the same thickness.
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  RE¯8M 1. The present invention relates to a process for the production of tubular films. A stretched organic film forming thermoplastic material comprising the steps of extruding an organic thermoplastic film forming material, heated so as to acquire a molten plastic state, through an annular orifice to form a tube, rapidly cooling the tube so that it becomes solid by stretching the tube over a cooled form, applying a gaseous fluid under pressure inside the tube and applying a equilibrium pressure of a mangy fluid & the outside of the tube,

   in the region where the tube is plastic, to prevent: * expansion of the tube, to pull the tube out of the form at a high speed
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 predetermined, without squeezing & crease the wall of the tube it dm keeping a passage through the tube, 1 heat the tube to a test "'perature which does not exceed 200 and -dos of the transitive point 44 defined above, in a stretching zone, zone in which the pressure is lower than the pressure prevailing in the tube to allow the tube to expand under the influence of the inter-
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 ne to form a smooth stretched tubular film, pull the tube away from the stretching area at a speed, Jg & le or lup4r1eu ... re z the speed at which the tube had been pulled from the drill ..

   cooled, and & flatten the tubular film.



  2.The present invention also relates to a method


    

Claims (1)

EMI13.4 lon claim 1, wherein the features Mi1vantt. are taken alone or in combination when possible t (a) The tube is heated in the drawing chamber to a temperature in the range from 2 C below <Desc / Clms Page number 14> at 60 C below the transition point. (b) The organic thermoplastic material has a distinct crystalline melting point and the tube is heated, in the drawing process, to a temperature in the range of 5 ° C below to 40 ° C below the point. of transition. (c) The organic thermoplastic material is polyvinyl chloride. (d) The organic thermoplastic material is polyvinyl chloride and the ratio of the diameter of the expanded tubular film to the diameter of the tube is in the range of 1 1/2 1 to 3: 1. (e) The organic thermoplastic material is polypropylene. (f) The organic thermoplastic material is polypropylene and the ratio of the diameter of the expanded tubular film to the diameter of the tube is in the range of 2 1 to 8: 1. (g) The ratio of the rate of pulling the tubular film out of the stretching zone to the rate of processing of the tube out of the form is roughly the same as the ratio of the diameter of the tube. tubular film expanded to the diameter of the tube before expansion. (h) The cooled form is maintained at a temperature in the range of 0 C to 20 C. (i) The tubular film is heated, after elis has left the stretch, to a temperature which is within 1000 of the temperature at which the stretching takes place, but below the transition point. . 3. The present invention also relates to an apparatus for producing a stretched tubular film of an organic thermoplastic film-sealing material, comprising an extrusion die having an annular orifice through which a material is formed. <Desc / Clms Page number 15> An organic thermoplastic film forming material may be extruded in the form of a tube, a form over which the freshly extruded tube is pulled to rapidly cool the tube so that it becomes solid, a chamber enclosing the tube. the opening of the annular orifice and at least the part of the form, on which the tube passes in the plastic state, a supply means intended to introduce a gaseous fluid under pressure inside the tube, a second supply means intended to introduce a gaseous fluid under pressure into the chamber, an outlet opening of the chamber, opening through which the tube can be withdrawn from the chamber substantially without loss of gaseous fluid from the chamber, a pulling means for pulling the tube out of the form at a predetermined speed, without kink-pressing the tube wall and maintaining a passing through the tube, heating means for heating the tube pulled from the form in an atmosphere having a pressure less than 1 release prevailing inside the tube to allow the tube to expand to form a film stretched tubular, and flattening means for flattening the stretched tubular film and drawing the film at a predetermined speed past the heating means. 4. the present invention also relates to an apparatus according to claim 3, having the following features, which are taken singly or in combination where possible (a) The stretching means comprises a pair of clamp cylinders of which the length is substantially less than the width of the tube when laid flat, serving to clamp the tube centrally. (b) The shape is a cylinder cone so as to undermine away from the die. (c) The outlet opening of the chamber circulates and comprises a flexible annular seal intended to close off <Desc / Clms Page number 16> the space between the edge of the opening and the wall of the tube. (d) The heating means comprises infrared ray heaters, spaced outwardly all around the tube.