DE2934631C2 - Process for the production and monoaxial stretching of a group of foil strips and device for carrying out the process - Google Patents

Description

The invention relates to a method for producing and monoaxially stretching a group of film strips according to the preamble of claim I and a device for implementation this method according to the preamble of claim 5.

It is known, film strips made of thermoplastic, high-polymer plastics for various applications with the specific product properties required for this. Such use cases are for example woven tapes for carpet backing fabrics or for packaging fabrics. Foil tapes for the production of cords. Ropes or ropes as well as foil strips as Auspingsmaterial for the Manufacture of splicing threads and similar products.

In the known manufacturing processes, the plastics are plasticized in a continuous process and in a liquid state through a Pressing tool. preferably a slot nozzle, as Fol'enH; him; Hisg!. * PreH; Πΐ '.- s? will be roniperier-

th cooling bath cooled below the softening temperature of the plastic. After trimming the At the edges of the film web, the flat film is divided into a group of narrow, flat film strips, which between roller or godet arrangements, which are preferably designed as wrap-around draw frames and between which hot air ovens are arranged, stretched monoaxially in the long stretching gap, if necessary heat-stabilized and then wound up.

In this process, a. Out of flat foil; Yes it is Also state of the art, starting from an extrusion blown film that, after being laid flat, laterally Slitting and separating the overlapping webs into foil sheets of the desired width is divided.

The known systems for the continuous production of foil strips are still in need of improvement, on the one hand in terms of usability and on the other hand in terms of the productivity that can be achieved, the specific space requirements of the system and the energy requirements. So when fulfilling the usual Quality requirements for the products today d'e winding speed of the film strips at the end known production plants - despite long-term efforts by the industry - a maximum of 300 to 350 m / min. This speed is at a withdrawal speed of the film web from the extrusion die on the order of less than 50 m / min.

The further increase in the production speed is particularly difficult towards the drafting systems and hot air ovens. The reasons for these difficulties are less in the mechanical part of the machinery aJs to look in the related technology. Because it succeeded So far only inadequate, the amount of heat required for stretching on the available standing length of the system so timely and dosed into the crowd to be stretched Bring in foil strips with the proviso that individual foil strips are used when the stretching speed is increased do not tear off, which leads to significant operational disruptions and production losses. So became found that the film strips generally increase when the production speed is increased low stretching temperatures are stretched, from which a low operational reliability with the result of Tears and impermissible loss of quality as well as, in particular, unfavorable shrinkage properties result. As a result, the products were unusable for various areas of application.

From DE-OS 16 79 983 is a method according to the preamble of claim 1 for the production of packaging tapes became known. The ones specified there In the case of packaging tapes stretched in this way, temperature conditions and process conditions should ensure the high tendency to splice while maintaining the Eliminate the advantage of high tensile strength. This is achieved by using either the Ken or the outer zone of the bands has a temperature above the softening temperature of the polymer, which is at a thermoelastic stretching of the remaining Bandcjuschnittes is plastically warped and one Has cross-section of high toughness.

The disadvantage here is. that those above the softening temperature pleatedly distorted band cross-section c are not covered and therefore practically not

contribute to the strength of the belts, which means that the polymer material is poorly utilized.

In the case of the prior art described, the task now arises, the generic method according to the preamble of claim 1 so that the described barriers for a Increase in production speed can be overcome. The invention is directed in particular ensure that it adapts to the extrusion stage continuously subsequent stretching process with the aim of higher production speeds and a substantial To improve the reduction of the required energy consumption.

The solution to this problem results from the characterizing features of claim 1.

It should be mentioned that single-band extrusion for flat threads is known per se (cf. Textilindustrie 70, 11/1968, pages 774 to 776). It has the advantage that all the film strips of the group have identical properties with regard to their geometry and stretching conditions. This also eliminates the difficult and time-consuming adjustment of the exit gap of the slot die tool, trimming the film web at the edges and dividing the film web into individual film strips. In the drawing step resulting in stretching individually extrudie ^r * he tapes additional advantages in terms of more uniform drawing conditions, ie for example a substantially identical linear density and the same pre-treatment in the extrusion step, wherein the same flow conditions, the same residence times, and temperature stresses, etc. present in the extrusion die. The single-band extrusion is also necessary according to the invention because the cutting of a band of bands from a film web while observing the other features of claim 1 with the usual tools, such as cutter bars or the like., Can not be performed reliably.

In the method according to the invention, the pressed sheet of foil strips is only cooled to the extent that that the jacket zone of the individual film strips is solidified as they exit the cooling bath, while the a core zone having 50% to 60% of the total cross section of each foil strip is still plastic is present and has such a heat content that you have to stretch the entire foil strip cross-section required amount of heat can still be withdrawn by after leaving the cooling bath a temperature equalization between the core and jacket zone of the foil strips with solidification of theirs Total cross-section takes place. In this case, there is essentially one over the entire cross-section of the film homogeneous temperature distribution before and at the beginning of the stretching zone becomes the optimum stretching temperature Achieve, in which the previously plastic core zone of the foil tape is sufficiently solidified, to extend them as well. Through this procedure there are significant advantages in terms of the specific energy and space requirements, since the The amount of heat brought along by the belts from the extrusion stage is used and not in the Cooling bath is discharged in order to have to supply it again later in the stretching stage. After all, even can the conventional hot air ovens can be completely saved, since the stretching after the other Feature of the invention is carried out without additional heat input from the outside into the film strips. This shortens the plant length and the

specific space requirements significantly reduced.

In the context of this invention, stretching of the film strips without additional heat input from an external energy source or the term "cold stretching" should be understood to mean that no "> external energy source is used to heat the film strips to the stretching temperature "or" external power source "also versiehen so that here under, for example, dielectric, capacitive or microwave heaters fall * by the be '■', the foil strips heated by external action of energy inside. in other words, to a plant for carrying out the method according to the invention Area of the stretching zone do not have a component that is heated by an external energy source to a temperature above the film strip temperature, in particular the optimal stretching temperature of the plastic film strips or above - "Foil tape towards - as a prerequisite for heat flow into the foil tape - is thus excluded. On the other hand, however, in a "cold stretching unit", for example, the delivery unit can be tempered within the scope of the invention in such a way that when the group of foil strips is passed over, heat is avoided and thus the foil strips are prevented from cooling down or cooling down.

According to a further, preferred embodiment of the invention according to claim 2 there is a considerable Jo higher productivity than with the known manufacturing processes, because the dwell times previously required for introducing the heat in the stretching stage are not more are necessary. Rather, it is particularly advantageous to use the system at high take-off, stretch and Ji Operate winding speeds. This is advantageous because there is only little heat loss here H

The method according to the invention differs from the known in particular in the high withdrawal speeds from the nozzle openings of the extrusion tool between 100 m / min to 200 m / min and the high winding speed of preferably more than 600 m / min, which increases the output On the other hand, it is also possible to reduce the number of film strips with this high throughput. This can shorten the godets of the drafting units, reduce the investment costs for the system and make ^v> den more usable high speeds can be improved.

In experiments mn polymer mixtures has been found that this method of the invention is also applicable and in that by the features stated in claims 3 and 4 Mischungsverhältnis- ~ »se of polypropylene with a linear polyester one hand, and with a polyamide on the other hand excellent good properties of the film strips with regard to strength and elongation can be achieved.

The device for carrying out the method ^M) according to the invention according to claim 5 is based on the preamble of a state of the art, as it is in textile industry 11/1968. Pages 774 to 776 is described. The apparatus is characterized in that the melt inlet opening of the extrusion 'tool ^{n is} an Schmelzeveneiiüngseinrichtung with a plurality of individual melt channels of equal length is connected. which open into individual nozzle openings, the Schmel / ckaniile lying in one or more parallel planes in nozzle bodies which are arranged interchangeably in the extrusion die. In combination with this, the device is also characterized in that a height-adjustable deflection device for the group of foil strips is arranged below the liquid level in the cooling bath.

It should be mentioned that the first-mentioned feature in the characterizing part of claim I for single-band extrusion is necessary and the individual measures mentioned in this context by the DE-AS 12 62 012 and US-PS 16 03 813 for others Production processes are known per se.

Only the combination of the Vorrichiungsmerkmale of claim 5 but leads to success, since one for the Exercise of the process essential measure for the targeted control of the heat balance in the Foil tapes are also proposed.

Advantageous measures for influencing and controlling the film strip temperature between the cooling bath and the delivery system of the drafting system are specified in claims 6 to 8. The measures according to claims 6 and 7 serve, inter alia, the purpose of making the strip temperatures uniform among one another and over their length. The suggestion according to claim 6 is regarded as a preferred measure, since the cooling liquid that adheres to the belts and is dragged along is removed with little effort and without the energy requirement of a suction system. As a result, on the one hand, only little heat is withdrawn from the foil strips to evaporate adhering liquid and, on the other hand - in contrast to vacuum suction - no air flow is generated in which there are increased heat transfer values with increased cooling of the foil strips.

According to claim 8 is the temperature of the cooling bath

Ι * »- • · Ά ~ 1 ···> ηΙ« · «\ / a ^ k, n / i, inn with Λι ** · UnUanoAP 5tcÜCrL» 5.r. wOuUttii ill HI i / 'iiuuttg ιιιιτ xn »t ι luiibiiTvi adjustability of the deflection device in the cooling bath allows easier temperature control.

It has been found that the achievable by the measure according to claim 6 success still from the exit angle of the band of ribbons from the cooling bath is dependent. A preferred exit angle is after Claim 10 in the range from 30 ° to 50 °; an optimal value became for an exit angle of about 30 ° determined.

The control of the heat balance of the film strips according to the invention leads to that according to Claim 9, the godets of the delivery system for the drafting system are designed so that they are only up to one Temperature below the softening temperature of the film strips can be heated. Because through the godets the film strips do not have to be heated to the stretching temperature; rather, only need heat losses compared to the environment and a heat extraction by the godets of the delivery plant are reduced.

In the following the invention will be explained with reference to the drawing showing a preferred embodiment and explained in more detail by test results:

In the film strip system shown schematically in the drawing is a melting extruder with the Reference numeral 1 denotes a special extrusion die 2 is arranged at its discharge end, the instead of a single exit gap of a wide slot tool in one or more parallel ones Levels not shown in more detail, has offset to one another present nozzle openings, which one below the other

which have identically the same cross-sections and are arranged interchangeably in the extrusion die 2 in nozzle bodies (not shown in detail). The extruder 2 is arranged on the extruder 1 in such a way that the film strips individually extruded from the nozzle openings enter a cooling bath 3 arranged below, either vertically or at a slightly different angle, where they are solidified on their surface. The film strip group 4 is deflected in the cooling bath 3 by a height-adjustable deflection device 5, for example a rod or a roller. The individual film strips are also tilted about their longitudinal axis between the deflection device 5 and a guide device 6 arranged above the liquid level of the cooling bath 3, which consists, for example, of rollers rotatably mounted on a rod, and guided over the guide device 6, preferably turned by 180 ° or 360 ° . Immediately behind the cooling bath 3, a delivery mechanism 7 of a drafting system is arranged, which consists of the delivery mechanism 7 and a take-off mechanism 8 that is driven more rapidly. The delivery mechanism 7 and the take-off mechanism 8 are both designed as three-roller wrap-around stretching mechanisms (trio), over the godets of which the group of foil strips is guided around with the greatest possible wrap angle. On each of the last roller there is a pivotably mounted pressure roller 9, the normal force of which presses the film strips against the godet and, in connection with the wrap, the holding and stretching forces are determined. Ar of the last roller of the delivery mechanism 7 and the withdrawal system 8 is also connected a suction device 10 from which the film strips during the commissioning of the plant, ie, first aspirated during the application of the individual foil strips. In this way, the foil strips torn off during operation are also sucked off so that no curls can form on the gaietten. At the end of the system there is a winding device 11 in which the film strips are wound in a known manner by means of tension-regulated and speed-controlled winding heads.

The decisive factor for the system according to the invention for performing the method is the design of the Extrusion tool 2 in connection with the cooling bath 3 and the height-adjustable deflection device 5 as well as the stretching device 7, 8, between their units no hot air oven or other devices are arranged for the supply of heating energy.

In contrast, the guide device 6 can be replaced by a vacuum suction device. Also is that Training of the delivery mechanism 7 and the trigger mechanism 8 is not bound to the illustrated embodiment. So For example, in an alternative embodiment of the drafting system, the delivery system can also be used as a Galette duo formed with two S-shaped looped godets arranged at a distance from one another be, the flock of foil strips 4 in this case obliquely from the lower godet of the duo up to the first godet of the take-off mechanism 8 runs. The suction device 10 is with its corresponding In this case the suction nozzle is connected under the godets of the duo. Such a facility has the Operational advantage that when a foil strip breaks, the one that springs back with a high spring force Foil tape does not strike into the crowd of other tapes and lead to curling and Breaks in sympathy

The invention is explained below with the aid of an exemplary embodiment and the here set Parameters explained. The example relates to a method for the production of woven tapes for sack or Packaging fabric.

Commercially available polypropylene of the type PPR 1070 F from Hoechst AG with a melt index of 17 g / 10 min was used as the raw material. The granules were melted in an extruder 1 and extruded through the extrusion die 2 in the form of several individually extruded ribbon, wherein the nozzle tool was heated to a temperature of 300 ⁰ C. The cooling bath 3, filled with water, into which the film strips 4 were extruded for solidification, was kept at a temperature of 25.degree. The starting strips, 16 of which are extruded at the same time, had dimensions of about 5.5 mm in width and 110 μm in thickness. The shortest distance between the spray nozzle and the water bath was 180 mm iinH the immersion depth in the water bath was 44 mm, the deflection taking place on a deflection roller with a diameter of 22 mm. The shortest distance between the spray nozzle and the center deflection roller was 125 mm, and that from the center deflection roller to the exit from the cooling liquid was 80 mm.

The take-off speed was set at the godets of the delivery mechanism 7 for the undrawn strips 194.5 m / min and at the take-off unit 8 for the drawn strips 1170 m / min.

The yield stress was 185OcN; the stretching ratio was calculated from the set speeds as 1: 6. The first godet of the delivery mechanism 7 for the stretching device was unheated; the following two galettes had to maintain a temperature of 90 ⁰ C to the cooling of the bands low. The temperature of the godets of the withdrawal system 8, which determined the subsequent thermal stabilization was set to 160 ⁰ C. After the stretching and heat stabilization, the tapes were wound up by speed-controlled individual winding heads at a speed of 1021 m / min. A tape tension of 70 cN was set on the dancer arms, which was kept constant during the entire winding cycle. A calculated stretching ratio of 1: 5.25 resulted between winding and entry into the drafting system. The allowable shrinkage on heat stabilization was 12.7%.

The data measured and calculated on the film strips resulted in a width of 23 mm and a thickness of 48 μΐη for the single band a titer of 990dtex; the breaking strength was 4.4 cN / dtex and the elongation at break was 30%. The bands were well suited for the intended purpose in the further processing stage

In a second series of tests, the following changes were made with essentially the same settings made: distance spray nozzle - water bath 125 mm; the shortest distance of the immersion depth was 17 mm, so that the pulley with a diameter of 22 mm is a total of 5 mm above the water level stood out. The shortest distance between the spray nozzle and the center pulley and the center pulley for the The exit of the film strips from the cooling liquid was 50 mm in each case.

With the same dimensions of the output belts and with the same temperature settings on the godets of the stretching device 7, 8, the speed of the godets of the delivery mechanism 7 was 120 m / min, that of the

üaletlen of the take-off mechanism 8 801 m / min and the Winding speed b87 m / min. The yield stress was determined with lb50cN, while the tape tension on the dancer arms of the winding heads with 7OcN was set. The stretching ratio between the delivery mechanism 7 and the haul-off mechanism 8 is calculated as follows I: 6.675, while the effective draw at a Heat shrinkage of 14.23% between the trigger mechanism 8 and the head of the Aufi ^ iileiniichcing 11 a value of Reached 1: 5.725.

The finished tapes had a tiler of 1000 dtex and with approximately the same final dimensions an elongation at break of 31% a breaking strength of 4.35 cN / dtex. They were as a ribbon for them

IO

Production of packaging fabrics well suited. Reference symbol extension

1 Aufschmel / .cxtriidcr

2 extrusion die

3 cooling bath

4 set of foil tapes

5 deflection device

6 guidance system

7 Supplier

8 trigger mechanism

9 pressure roller

10 suction device

11 Aiifspuleinrichtiing

1 sheet of drawings

Claims (10)

Patent claims: 1. A process for the production and monoaxial stretching of a group of film strips made of thermoplastic, high-polymer plastics ϊ and plastic mixtures, in which the plastics are plasticized in a continuous process and pressed in a molten state by a pressing tool to form film strips and then passed through a cooling bath, where they are are cooled in such a way that the jacket zone of the film strips is cooled to below the softening temperature of the plastic, while the core zone of the film strips is still plastic, whereupon the film strips are monoaxially stretched, if necessary, heat-stabilized and wound up, characterized in that
that the film strips of a film strip pack pressed out of individual individual ^{nozzles are drawn off the nozzle openings at a take-off speed of more than 20} 50 m / miti yen and passed through the cooling bath with such dwell times, that the foil strips produced when exiting the cooling bath, the individual film strips having a core area of 50% to 60% of the total cross-section ^ in a plastic state,
that after leaving the cooling bath, the temperature between the core and jacket zones of the film strips is equalized for homogeneous temperature distribution and consolidation of the entire film strip cross-section and that the stretching is carried out into the film strips without additional heat being added from the outside. 2. The method according to claim 1. in which the " Plastic is a polyolefin, in particular polypropylene, characterized in that that the withdrawal speed of the film strips from the nozzle openings - at the usual melt temperature - is between 100 m / min to 200 m / min ^Jr> and is preferably 160 m / min to 200 m / min, that the group of film strips without external heat supply drove with a stretching ratio of more than 1: 5 and stretched at a speed of more than ⁴ > than 400 m / min, preferably more than 600 m / min after a heat stabilization treatment. 3. The method of claim I. wherein the plastic is a polymer blend, characterized in ^~>r> in that the polymer mixture of a linear polyester, especially polyethylene terephthalate having a mixing ratio of at least 70 wt% polypropylene, preferably 75 to 85% by weight Polypropylene. "'"' 4. The method according to claim I, wherein the plastic is a polymer mixture, characterized in that the polymer mixture is a polyamide, in particular poly-e-caprolactam, with a mixture ^proportion of at least 80 weight ⁿ .ii. is preferably 84 to 86 weight percent polypropylene. 5. Device for performing the method according to claims 1 to 4. with a melting extruder, an extrusion die, which has a " Melt inlet opening and a multitude of individual ones Aufweisi nozzle openings with identical cross-sections. a Kiih! b: «cl. a balance ·: '- bar behind the cooling bath arranged delivery mechanism of a drafting device and a looping drafting device and a plurality of winding devices, characterized in that to the Melt inlet opening of the extrusion die (2) is connected to a melt distribution device is, with a plurality of individual melt channels of equal length in individual Open out nozzle openings, the melt channels in one or more parallel planes in Nozzle bodies lieger. Which are arranged interchangeably in the extrusion die (2), and that in the Kühjbad (3) a height-adjustable deflection device (5) for the group of foil strips (4) is arranged. 6. Apparatus according to claim 5, characterized in that at the outlet of the cooling bath (3) Guide devices (6) for rotating the film strips (4) are arranged about their longitudinal axis. 7. Apparatus according to claim 5 and 6, characterized in that that the delivery mechanism (7) of the stretching device (7, 8) as a pair of godets with two spaced apart arranged, S-shaped looped godets is formed, and that the suction nozzle of a suction device (10) is connected at a distance below the godets is. 8. Apparatus according to claim 5, characterized in that that the temperature of the cooling bath is controllable. 9. Device according to claims 5 to 8, characterized in that the godets of the Delivery plant (7) only up to a temperature below the softening temperature of the film strips are heatable. 10. The device according to one or more of claims 5 to 9, characterized in that the Foil strips (4) the Kühibad (3) in the running direction at an angle of JO "to 5ύ ° with respect to the Leave the liquid level and turn it through the guide devices (6) by about 180 ° or 360 °! so that they leave the cooling bath (3) essentially upright.