Apparatus And Method For Providing Marks On Extruded Films

Information

  • Patent Application
  • 20210031430
  • Publication Number
    20210031430
  • Date Filed
    October 12, 2020
    4 years ago
  • Date Published
    February 04, 2021
    3 years ago
  • CPC
  • International Classifications
    • B29C48/92
    • G01B5/06
    • B29C48/31
    • B29C48/88
    • B29C48/12
    • B29C48/08
Abstract
The invention relates to an apparatus for providing marks on extruded films, in particular on stretched films, which are exiting an extrusion lip of a film extruder and a respective method. The apparatus comprises at least one nozzle means for directing a gas stream, preferably an air stream to a surface of the film exiting the extrusion lip of the film extruder, wherein the nozzle means are configured and arranged in such a manner that the gas stream locally causes a cooling of the extruded film to create a local mark (FIG. 1).
Description

The present invention relates to an apparatus and a method for providing marks on extruded films, in particular on stretched films as well as to a system and method for automatically detecting marks on extruded films and a system and a method for automatically controlling a film extruder for manufacturing the extruded films.


U.S. Pat. No. 5,411,695 relates to a method for producing a thermoplastic resin film. It particularly deals with a bowing phenomenon which occurs in the process of transverse drawing of the thermoplastic resin film. According to this document the bowing phenomenon can be visualized by drawing straight lines on the surface of the film in the direction of transport. The bowing phenomenon can be reduced by not only considering manufacturing processes and apparatus but also by consideration of the characteristics of the film itself and by applying specific cooling in a cooling zone followed by heat setting of the film.


U.S. Pat. No. 3,904,725 relates to a process for quenching molten thermoplastic film in an apparatus which comprises a movable quenching surface, an extrusion dye positioned above the quenching surface to extrude a polymeric film from the dye onto the quenching surface and lateral point pinning means positioned above the quenching surface and over each lateral edge of the film. It is described that in the preparation of thermoplastic polymeric film using a flat extrusion process, a molten web is cast onto a cool quenching surface. Although the molten sheet may be substantially uniform in thickness as it issues from the parallel dye lips, tension on the free span between the dye and the quenching surface causes a contraction in the width of the film which results in a greatly increased thickness at the edges of the film. It is further stated that the contraction of the web continues through a cooling process. It is therefore suggested to use edge pinning means for stabilizing the film width. By providing a certain direction of additional pinning force at the portion of the lateral edge of the film the preparation of films that do not exhibit marked fluctuations in thickness adjacent the edge can be achieved. As pinning means electrostatic point probes or air jets are used.


U.S. Pat. No. 4,255,365 describes a process for promoting uniform thickness in cast webs of thermoplastic material comprising of variable air forces selectively directed toward a cast web with pinned edges along the line of initial proximity with a quenching surface. The air is provided to the web to provide rapid cooling to specific areas of the casted web. On each lateral side of the casted web one or more air jets can be provided.


The before-mentioned documents aim to avoid the bowing phenomenon and thickness variations of the casted film.


The present invention aims to provide an apparatus and a method for providing marks on extruded films, in particular on stretched films. It is a further object of the present invention to provide an apparatus and a method for automatically detecting marks on extruded films. It is a further object of the present invention to provide a system and a method for automatically controlling a film extruder in particular for automatically controlling the thickness of extruded films.


These objects are achieved with the features of the independent claims. The dependent claims relate to further aspects of the present invention.


The present invention is based on a general concept of using one or more nozzle means for directing a gas stream to a surface of the film exiting the extrusion lip of a film extruder. By using a gas stream the extruded film can be locally cooled to create a local mark.


The present invention is based on another general concept of using one or more nozzle means for directing a substance preferably a liquid or paste-like material more preferably an ink or a resin directed to a surface of the film exiting the extrusion lip of a film extruder. By directing the substance to the surface a local mark can be created which is visible or invisible (e.g. fluorescent ink) to the human eye.


When combining the gas nozzle means and the substance nozzle means a local mark by cooling and/or a local mark by a substance can be created. This might be done through a combined nozzle means configured to selectively apply gas and/or a substance to the film surface or by two separate nozzle means located next to each other one for applying gas and the other one for applying a substance.


The local mark can be detected at a position downstream of the extrusion lip and can then be used for a specific control of the extrusion lip of the film extruder.


Previously marking of a film was made by using for example a wax pen to draw a line on the film. However, for marking the film with a wax pen the pen had to be brought into contact with the surface of the film. This way of marking is quite difficult because on the one hand the film should not be damaged by the contact with the wax pen and on the other hand for drawing a line on the film a certain contact pressure is needed.


Another alternative to mark the film is to intentionally change the thickness at a certain position of the extruded film by changing the width at a certain position of the extrusion lip of the film extruder. However, this type of marking has a high response time and is therefore not convenient.


The present invention has the advantage that by marking the film using one or several gas streams and/or using a substance a high response time can be achieved and no contact is necessary for providing the mark. By providing a mark of a substance, preferably a liquid or paste-like material, more preferably an ink or a resin which is directed to the surface of the film to create a local mark which is visible or invisible (e.g. fluorescent ink) to the human eye has the advantage of not creating a thickness variation in the film. By using a mark of invisible ink the part of the film where the mark is applied to can still be used, whereas a visible mark or a thickness variation mark has to be cut away after processing of the film.


According to the present invention at least one nozzle means is provided adjacent to the extrusion lip of the film extruder. Preferably, the nozzle means is configured to be movable in a scanning manner in parallel to the extrusion lip of the film extruder along the width of the extruded film or web. Preferably the position of each nozzle means has a specific known relationship with one or several adjusting means for example with one or several bolts with which the extrusion lip of the film extruder can be specifically controlled at respective positions along the width of the extrusion lip.


According to an aspect of the present invention an array of a plurality of nozzle means is used, wherein the array is preferably a linear array which is oriented in parallel to the extrusion lip of the film extruder. According to another aspect of the invention the individual nozzle means are arranged at predetermined distances from each other and more preferably at equal distances from each other, preferably equivalent to the width of adjusting means like bolts of a film extruder or a multiple of the bolts.


According to a further aspect of the present invention the nozzle means are configured to blow a gas stream (also referred to as gas jet) and/or a substance to the surface of the film wherein the gas stream and/or the substance has a predetermined cross section. The gas stream and/or substance is suitable to provide a local cooling and/or a local mark at a part of the film material. As a result the part of the film being cooled by the gas stream and/or being marked by the substance represents a local mark having a predetermined dimension, preferably a predetermined diameter or a predetermined width and length.


According to still another aspect of the invention the nozzle means are configured to be arranged in relation to the extrusion lip of the film extruder such that the gas stream and/or the substance can be directed to the local position within at least one border region of the extruded film, i.e. on one or both lateral sides of the extruded film.


According to an aspect of the present invention the apparatus comprises a frame which is adapted to support at least one nozzle means, wherein the nozzle means is configured to be movable in a scanning manner in parallel to the extrusion lip of the film extruder along the width of the extruded film or web and/or to support a linear array of nozzle means at one or both ends of the extrusion lip of the film extruder. In that case a plurality of gas streams and/or substance can be directed to either one or both border regions of the extruded film. The one or both linear arrays of nozzles are arranged substantially along a line parallel to the extrusion lip of the film extruder.


According to a further aspect of the invention a plurality of nozzle means are arranged in a linear array wherein a number n of nozzle means is preferably in the range 1 to 30, preferably of 2 to 20, more preferably 5 to 10.


According to a further aspect of the invention the nozzle means are arranged in a 1 to m correspondence with respect to individual adjusting means for adjusting the local width of the film extruder for example the bolts present in the film extruder for adjusting the local width. In that case m can preferably be in the range of 1 to 20, more preferably 1 to 5. Thus, in a 1 to m correspondence there is one nozzle means for every m-th individual adjusting means. For example, in case of a 1 to 1 correspondence there is one nozzle means for each individual adjusting means. Alternatively, any arbitrary combination can be used, wherein one nozzle means is arranged at one arbitrarily selected individual adjusting means.


According to a further aspect of the invention the apparatus comprises control means for controlling the delivery of gas and/or substance to each one of the nozzle means. More specifically the control means can control the delivery of gas and/or substance to one, two, three or more individual nozzle means independently or to certain specific groups of nozzle means. For example gas and/or substance can be delivered at the same time to all nozzle means. Alternatively, gas and/or substance can be delivered to only one of the nozzle means at a time. By intermittently providing gas and/or substance to the nozzle means dot like marks can be created. By continuously providing gas and/or substance for a predetermined time to the nozzle means a linear mark can be created. Depending on whether one, two, three or more or all nozzle means are provided with gas and/or substance intermittently or continuously an array of dot like marks or an array of linear marks can be created. It is also possible to create after each dot like mark one linear mark or after two or more dot like marks one or more linear marks. The specific pattern of dot like marks and linear marks can be used to distinguish between certain time points of providing marks on the extruded films.


According to another aspect of the present invention the temperature of the gas stream is lower than the temperature of the film which exits from the film extruder. Thus, the gas stream provides a cooling of the film material which results in a detectable mark in the form of a local change of the characteristics of the film, in particular the physical characteristics of the film, preferably a detectable local thickness variation in comparison to other parts of the film which are not cooled by the gas stream. Preferably, due to cooling of a film material the thickness of the film is greater than the thickness of adjacent parts in the neighbour region.


According to another aspect of the present invention an apparatus is provided for automatically detecting a mark on extruded films in particular on stretched films which comprises a detector for detecting said marks, preferably a detector for detecting thickness variations of the film and/or marks in the form of a substance on the films surface. The detector can comprise a gauging instrument for measuring the thickness of the film and/or optical means for detecting said substance on the films surface. The system further comprises means for determining the lateral position of the detected marks in relation to a reference position for example the edge on one or both lateral sides of the film.


In case the film changes the width after being cast from the extruder the lateral position of the detected marks can be brought into a relation to the lateral position where the mark is created. More specifically if there is only one nozzle means the position where the mark is created on the film can be detected by the detector by detecting for example a thickness variation of the film which results from the gas stream from said nozzle means and/or by detecting optically the local mark which results from the substance from said spray nozzle. The detected position can be brought into a specific relationship to the position of the nozzle means or the position where the mark is created.


According to a still further aspect of the invention a system is provided for automatically controlling a film extruder in particular for automatically controlling the thickness of extruded films, in particular of stretched films which are produced with the film extruder. The system comprises an apparatus for creating marks as described before and a system for detecting marks and for providing information of the lateral position of the marks as described before. It further comprises a gauging instrument for measuring the thickness of the film preferably the thickness of the film over its whole width. The system additionally comprises control means for controlling individual adjusting means for adjusting the local width of the film extruder. The control is performed on the basis of measurement results of the gauging instrument and the information of the lateral position of the marks.


The present invention further provides a method for providing marks on extruded films, in particular on stretched films, which are exiting an extrusion lip of a film extruder. This method comprises the step of directing at least one gas stream, preferably an air stream to a surface of the film exiting the extrusion lip of the film extruder in such a manner that the gas stream locally causes a cooling of the extruded film to create a local mark. The present method preferably uses an apparatus for providing marks on extruded films as described above. Thus, for directing a gas stream to the surface of the film a respective nozzle means is used.


Furthermore, the present invention provides for a method based on another general concept for providing marks on extruded films, in particular on stretched films, which are exiting an extrusion lip of a film extruder. This method comprises the step of directing at least one substance, preferably a liquid or a paste-like material, more preferably an ink or resin and more preferably fluorescent ink to a surface of the film exiting the extrusion lip of the film extruder using at least one nozzle means, in such a manner that the substance creates a local mark on the extruded film.


It is further possible to combine the two methods described above in that a method comprising the step of directing a gas stream and/or directing a substance to the surface of the film exiting the extrusion lip of the film extruder can be employed. This might be done through a combined nozzle means configured to selectively apply gas and/or a substance to the film surface or by two separate nozzle means located next to each other one for applying gas and the other one for applying a substance.


According to an aspect of the present invention two or more gas streams and/or substance are directed to the surface of the film. The gas streams and/or substance can be switched on and off in such a way that either 1, 2 or more gas streams and/or substance are active simultaneously or at a different time period. When using an array of plurality of nozzle means, preferably a linear array which is arranged in parallel to the extrusion lip of the film extruder several marks can be created which are placed at predetermined distances from each other. Preferably the marks are at equal distance from each other.


According to a further aspect each gas stream is created by blowing a gas jet to the surface of the film. The gas jet has a predetermined cross-section and preferably the gas jet is suitable to provide a local cooling at a part of the film material, more preferably within a well defined area of the surface of the film material. Preferably, the local cooling is effective through the film material such that the whole material under the well defined area is cooled. As a result the cooled part of the film has a predetermined dimension when seen on the surface of the film, preferably a predetermined diameter or a predetermined width and length. For example, one or several continuous linear marks which are spaced from each other in the lateral direction can be provided on the film. Alternatively, the spray nozzle for creating at least one mark comprises at least one nozzle means for directing a substance, preferably a liquid or a paste-like material, more preferably an ink or resin and more preferably fluorescent ink to a surface of the film exiting the extrusion lip of the film extruder, wherein the nozzle means are configured and arranged in such a manner that the substance creates a local mark having a predetermined cross-section and preferably the gas jet is suitable to provide a local mark at a part of the film material, more preferably within a well defined area on the surface of the film material.


According to a further aspect the gas stream and/or substance is directed to a local position within one or both border regions of the film. Alternatively, a plurality of gas streams and/or substance can be directed to one or both border regions of the film. In such a way, several marks can be created on both lateral sides of the film which are arranged along a line parallel to the extrusion lip of the film extruder.


According to another aspect of the invention a plurality of nozzle means, i.e. a number n of nozzle means are arranged in a linear array. Such a linear array can be provided on both border regions of the film. The arrangement of the nozzle means is preferably in a 1 to m correspondence with respect to individual adjusting means of the film extruder. Such adjusting means are configured to adjust the local width of the film extruder so that the thickness of the film extruded from the film extruder can be adjusted. Preferably the number of nozzle means is the same as the number of adjusting means. Thus, there is a 1 to 1 correspondence. Alternatively, one nozzle means is provided for every m-th adjusting means with m being in the range of 1 to 20, more preferably 1 to 5. Any arbitrary combination of each one nozzle means with an arbitrary selected individual adjusting means can also be used.


According to a further aspect the delivery of gas and/or substance is controlled to each one of the nozzle means independently. The gas and/or substance can be provided intermittently to one or more of the plurality of nozzle means or even to all nozzle means at the same time. In this way, an array of dot like marks can be created by quickly switching on and off the gas stream and/or substance stream. In addition or alternatively, the gas and/or the substance can be continuously provided for a predetermined time to one or more or all nozzle means. In that case an array of linear marks can be created. The length of the linear marks depends on the ON-time on the gas supply and/or substance supply and the speed with which the film is moving from the film extruder to a chilling roll downstream of the film extruder.


According to a further aspect the temperature of the gas is controlled to be lower than the temperature of the film exiting the film extruder. The temperature difference is selected in such a manner that the cooling of the film material results in a detectable mark in the form of a local change of the characteristics of the film, preferably a detectable local thickness variation in comparison to other parts of the film not being cooled by the gas stream. More specifically, the local thickness variation can be a greater thickness in parts of the film which are cooled by the gas stream. When exiting the extrusion lip the film has a certain temperature and when being transported to a first chill roll thermal contraction of the film occurs resulting in a neck-in portion. The gas stream causes a local cooling of the film that comes out of the extrusion lip which results in a specific thickness at this part of the film.


According to another aspect of the present invention these marks on the extruded films are automatically detected by using a detector preferably a gauging instrument for measuring the thickness of the film and/or optical means for detecting said substance on the films surface. For example, a measurement sensor head detects thickness peaks at predetermined positions that are associated to respective positions where the gas stream cools the film. The lateral position of the detected marks is in a specific relation to a reference position for example to one or both edges of the film. Furthermore, the optical means for detecting the lateral position of the mark at the neck-in portion according to one aspect of the present invention comprises a sensor, preferably an optical camera, configured to detect the substance at the neck-in portion.


According to another aspect of the present invention a method for automatically controlling a film extruder in particular for automatically controlling the thickness of extruded films, in particular of stretched films uses the before-described method for marking and the before-described method for detecting marks on a film. It further comprises the step of measuring the thickness of the film over the whole width using a gauging instrument and of controlling individual adjusting means of a film extruder on the basis of the measurement results of the gauging instrument and the information of the lateral position of the marks by using further control means.


Air blow marking can be performed in cycles which are started either manually by an operator or which can be started automatically in case of events which are significant in the manufacturing process. In particular, if events are significant on the neck-in effect for example a change of production, a change of the width of the film, a change of the distance between the dye and the chill roll or a change of vacuum box conditions a cycle of air blow marking according to the present invention can be performed.


The method and apparatus as claimed and described herein can be used in combination with an apparatus and a method for automatically analyzing extruded films, i.e. auto-mapping of the neck-in portion, as described in a co-pending patent application of the same applicant filed on the same day as the present patent application. Therefore, the content of this co-pending patent application with the title apparatus and method for automatically analyzing extruded films is fully incorporated herein by reference.





BRIEF DESCRIPTION OF FIGURES

The present invention will now be explained with reference to preferred embodiments and the drawings, in which:



FIG. 1 shows a schematic perspective view of a system for manufacturing films comprising an apparatus for providing marks on films, according to an embodiment of the present invention.



FIG. 2 shows a schematic side view of a system as shown in FIG. 1,



FIG. 3 shows a schematic diagram as a top view on the extruded film in the system of FIG. 1



FIG. 4 shows a schematic diagram of the measurement result representing the thickness variation resulting from marks created on an extruded film,



FIG. 5 a) and b) show a schematic perspective view of a system for manufacturing films according to another embodiment of the present invention and



FIG. 6 shows a schematic diagram as a top view on the extruded film in the system of FIGS. 5a and b.





DETAILED DESCRIPTION OF THE INVENTION


FIG. 1 shows a schematic view of a system according to an embodiment of the present invention which comprises an apparatus for creating marks according to an embodiment of the present invention. FIG. 1 shows a film extruder 1 comprising an elongated extrusion lip 3 and a plurality of adjusting means 5 being arranged adjacent to each other along the width of the extrusion lip. The adjusting means 5 can comprise respective bolts, and the adjusting means can be used for changing the width of the extrusion lip 3 and more specifically wherein individual adjustments can be made to adjust the thickness individually at specific parts of the extrusion lip. FIG. 1 further schematically shows an extruded film 7 which exits the extrusion lip 3 and which is rolled on a chill roll 9. As further schematically shown in FIG. 1 the extruded film has a wider width at the exit of the film extruder which substantially corresponds to the width of the extrusion lip 3. Due to a thermal contraction the width of the extruded film is smaller when reaching the chill roll 9. More specifically, due to this thermal contraction the extruded film comprises on the left lateral side a neck-in portion 7a and on the right lateral side a neck-in portion 7b.



FIG. 1 further schematically shows the apparatus 10 for providing marks on the extruded film. The apparatus 10 comprises a plurality of nozzles 11 which are arranged close to the extrusion lip and directed to the top surface of the film. FIG. 1 schematically shows three nozzles 11 on both lateral sides of the extruded film. In this example, each nozzle 11 is connected via a respective line 13 to a manifold 15. The manifold 15 for distributing gas to the several lines 13 is connected at one end via an electro valve 17 to a compressed air supply 19. The compressed air supply 19 can be connected to a compressor (not shown) for supplying the compressed air. The apparatus 10 comprising the nozzle 11 can be supported by a first frame which is arranged above the extrusion lip 3.


As shown in the side view of FIG. 2 one air regulator 14 can be provided for each line 13 connecting one nozzle 11 with the manifold 15. As schematically shown in FIGS. 1 and 2 the nozzles are arranged along a line parallel to the extrusion lip 3. The tip end of the nozzle 11 is arranged adjacent to a respective adjusting means 5 of the film extruder 1. In the example of FIG. 1 three nozzles 11 are arranged on both lateral sides of the film, i.e. in a border region of the film. More specifically, as schematically shown the outer most nozzle 11 is arranged on the left side at a specific distance from the left end of the extrusion lip, i.e. it is placed close to the fourth adjusting means from the left side of the extrusion lip. The second and third neighbour nozzle is arranged at equal distances such that the second nozzle 11 is arranged adjacent to the sixth adjusting means 5 and the third nozzle 11 is arranged close to the eighth adjusting means 5. The other three nozzles are similarly arranged on the right lateral side of the extrusion lip. Thus, there is a 1 to 2 correspondence between the number of nozzles on both lateral sides and the respective number of adjusting means in these border regions. This is just an example. Any arbitrary combination can be used, for example, a first nozzle is arranged at the second adjusting means, a second nozzle is arranged at the fifth adjusting means, a third nozzle is arranged at the tenth adjusting means and the fourth nozzle is arranged at the twentieth adjusting means. The arrangement on the other lateral side can be mirror-symmetric but also non-symmetric.



FIG. 3 schematically shows a top view of an extruded film coming out from the extrusion lip 3 wherein between the extrusion line Y and a measurement line X a neck-in portion 7a is formed on the left side and a neck-in portion 7b is formed on the right side of the schematic drawing of FIG. 3. FIG. 3 illustrates that the contraction of the film specifically occurs along the border region of a film on both lateral sides. FIG. 3 further shows schematically a number N of adjusting means 5 designated with numbers 1, 2, 3 to 11 and N-10, N-9 to N. In the middle region between the adjusting means 10 to N-9 substantially no thermal contraction occurs. This is again an example. The numbers depend for example on the width of the neck-in area or production and line conditions like viscosity of the material or mechanical dimensions of the production line. The total number of adjusting means N may be in the range of 30 to 350. Therefore, in FIG. 3 both lateral sides are shown in an enlarged manner. As can be seen the width of the film along the extrusion line is wider than the width along the measurement line. As can be further seen there is a specific relation of the position of the part of the film exiting for example the adjustment means 1, i.e. the position along the axis Y and the respective position of this part of the film along the measurement line which corresponds to a position along the axis X. In other words, there is a specific function y=f(x). Those parts which exit the extrusion lip 3 at a particular individual adjusting means 5 can be marked with the present system by blowing air to the surface of the film. By using an array of air blows located above the adjusting means, i.e. the bolts on both lateral sides of the film extruder local film cooling can be caused. The air flow can be simultaneously or individually be directed to the surface of the film such that the film coming out of the extrusion lip 3 is cooled and as a consequence a mark is created on the film having a specific thickness.


By using a measurement sensor head 21 along the measurement line X the thickness can be measured and the marks can be detected. This measurement sensor head can move back and forth along the measurement line X to measure the thickness of the film over its whole width. For example, a second frame (not shown) may be arranged above the measurement line X along which the measurement sensor head traverses.


As schematically shown in FIG. 4 the film thickness profile comprises three peaks on both sides wherein one peak corresponds to a respective mark detected by the measurement sensor head 21. The thickness peaks schematically shown in FIG. 4 correspond to linear marks created on respective parts of the film when exiting the extrusion lip. More specifically these marks correspond to respective adjusting means 5 where a nozzle 11 directs a gas stream on the surface of the extruded film.


These data can be processed to adjust the function y=f(x) in a way that gives more accuracy in the characterization of the real film contraction. The air blow marking cycle can be initiated manually or automatically. The air blow marking can be used continuously or in the case of events which are significant on the manufacturing of the extruded film in particular significant on the neck-in effect. For example, in case of a change of production, a change of the width of the film, a change of the distance between the dye and the chill roll and a change of vacuum box conditions the air blow marking cycle can be initiated.


Instead of, or optionally in addition, to marking by a gas nozzle as described above it is possible to create a mark using a spray nozzle situated above and/or below the film at the extrusion lip. In this embodiment, a substance preferably a liquid or paste-like material more preferably an ink or a resin is directed to the surface of the film to create a mark which is visible or invisible to the human eye. The mark is positioned in a defined relationship with respect to a specific part of the extrusion lip. In the following, ink is used from the list of substances as to describe the embodiment by example. The ink can be of any material and/or color to create a mark on the extruded film which can be detected by an appropriate sensor, e.g. an optical camera or other non-contact type sensors like beta ray, x-ray, infrared sensors or interference type sensors. Preferably, the ink can be a fluorescent ink that is invisible for the human eye on the extruded film. Fluorescent inks particularly suitable might either be UV curable or thermally dried. This has the advantage that the marked part of the extruded film can stay on the extruded film, i.e. it does not have to be cut away in post-processing. The use of an ink spray nozzle is advantageous as there is no contact between the nozzle and the extruded film. Furthermore, the thickness of the film is not changed apart from the thin layer of ink deposited on the film.


Next, the marking by an ink spray nozzle will be described referring to FIGS. 5a and b and FIG. 6. The description of features which have been described above already will not be repeated. Rather, full reference is made to the above description and the new features of this specific embodiment will be described in detail. According to FIGS. 5a and b the ink with or without fluorescent characteristics will be put into a pressure vessel connected to an air pressure system with a pressure regulating valve in between. An electric valve in the front of the spray nozzle 6 is provided to control the application of ink to the extruded film. The ink spray nozzle 6 is situated in scanning traversing position on a beam that has a mechanical lay out and assembly compatible with the lay out and the assembly of the machinery (extrusion die plus chill roll) where it is mounted on. The ink spray nozzle 6 is supported by a vertical translation to support the installation in narrow spaces. Furthermore, the ink spray nozzle 6 can have different spray angles and different spray volumes and can mark the film with correspondence to any specific part of the extrusion lip or the respective bolt, preferably one of the bolts at the extrusion lip in the border region. FIG. 6 is an illustration showing the marking of the bolt 3 of the extrusion lip (indicated by the thick black line). As can be seen, the mark on the film follows the specific form of the neck-in portion.


Even though the above described marking apparatus according to FIGS. 5a and b has been described by employing one spray nozzle, multiple spray nozzles in one array corresponding to the respective bolts can be employed. Furthermore, it is possible to provide one or two opposite transversal scanning spray nozzles, which, depending on the peculiarity of the products may spray a gas that leaves a mark preferably as a change of thickness that is detected by the thickness measurement system, and/or spraying a substance, for example an ink, that leaves a visible or invisible mark detected by an optical system built-in with the sensor heads of the thickness measurement system.


The detection system according to this embodiment is outlined next. The ink is detected by a sensor, preferably by an optical camera. Preferably, the optical camera is mounted onto the first measurement sensor head 21 as shown in FIG. 3. The optical camera can be used to detect visible ink. In case fluorescent ink is used to mark the extruded film, an additional light source might be used to make the mark, i.e. the fluorescent ink, visible for detection by an optical camera. Preferably, the light source is mounted onto a second measurement sensor head. The second sensor head might be movable back and forth in the same direction as the first sensor head but independently from each other. The source of light can be selected according to the choice of ink used for the specific application and/or the camera system can be selected accordingly. As described above the sensor can be selected to be any suitable sensor to detect the mark on the extruded film and the additional light source is selected according to the sensor used or can be omitted completely.


Again, the track left by the ink spray nozzle 6 on the film allows determining a univocal correlation between the bolt at the extrusion lip and the correspondent material stripe running below the gauge. Using both the information of the location of the mark and the information from the two edge detectors the functional relationship like the function f(x) can be adjusted in a perfect manner, preferably to respond to changes of surrounding conditions as described above.


The present invention has now been described with reference to embodiments. The foregoing detailed description and example have been given for clarity of understanding only. No unnecessary limitations are to be understood therefrom. It will be apparent to those skilled in the art that many changes can be made in the embodiments described without departing from the scope of the present invention. In particular, although features and elements of the present invention are described with reference to the aspects in particular combinations, each feature or element can be used alone without the other features and elements of the aspects or in various combinations with or without other features and elements of the invention. Therefore, the scope of the present invention should not be limited to the apparatus, system and methods described herein, but only by the language of the claims and the equivalence of those apparatus, systems and methods.

Claims
  • 1. Method for automatically analyzing extruded films, in particular stretched films, wherein a neck-in portion is formed at each of both edges of the film at a specific distance from an extrusion lip of a film extruder along the longitudinal transport direction of the film, comprising the following steps: detecting continuously the lateral position of one respective edge of the neck-in portion of the film, using two edge detectors being arranged along a first line substantially transversal to the longitudinal direction and being spaced from each other by a specific distance; anddetermining the spatial relation between at least one lateral position at the extrusion lip and a respective lateral position at the neck-in portion on the basis of the two lateral positions of the edges of the neck-in portion of the film using a calculation means.
  • 2. Method according to claim 1, further comprising: determining the width of the film along the first line on the basis of the two lateral positions of the edges of the neck-in portion of the film; anddetermining the spatial relation between the at least one lateral position at the extrusion lip and the respective lateral position at the neck-in portion on the basis of the width of the film along the first line taking into account a width of an opening of the extrusion lip.
  • 3. Method according to claim 1, further comprising the steps of: storing at least one an equation defining a relationship between at least one lateral position at the extrusion lip and a respective lateral position at the neck-in portion for a reference film having a specific width and thickness at the extrusion lip, wherein the equation is defined for a specific material of the extruded film; andcorrecting the functional relationship on the basis of the two lateral positions of the edges of the neck-in portion of the film or on the basis of the width of the film and determining the spatial relation between at least one lateral position at the extrusion lip and a respective lateral position at the neck-in portion using the corrected functional relationship.
  • 4. Method according to claim 1, further comprising the steps of: creating at least one mark on the extruded film at least one lateral position at the extrusion lip in the border region of the first and/or second lateral side of the film; anddetecting the lateral position of the mark at the neck-in portion.
  • 5. Method according claim 1, further comprising the steps of: adjusting the width of respective portions of the extrusion lip of the extruder;receiving thickness information of the film along a second line substantially parallel to the first line, wherein the second line is at the same position as the first line or at a position spaced apart from the first line downstream in the longitudinal transport direction; andgenerating control signals for controlling respective adjusting means of the extruder on the basis of the thickness information and the two lateral positions of the edges of the neck-in portion of the film or the width of the neck-in portion of the film.
  • 6. A method for automatically controlling a film extruder in particular for automatically controlling the thickness of extruded films, in particular of stretched films, comprising the steps of: automatically analyzing extruded films; andcontrolling individual adjusting means for adjusting the local width of respective portions of the extrusion lip of the film extruder on the basis of the analysis of the extruded film.
Priority Claims (1)
Number Date Country Kind
13180391.8 Aug 2013 EP regional
REFERENCE TO RELATED APPLICATION

This application is Divisional of U.S. Non-Provisional application Ser. No. 14/911,817, filed Feb. 12, 2016 which is a U.S. National Phase filing of International Application No. PCT/EP2014/067361, filed Aug. 13, 2014, which claims priority to U.S. Provisional Application No. 61/865,695, filed Aug. 14, 2013, and claims priority to European Application No. 13180391.8, filed Aug. 14, 2013, the entirety of each of which are hereby incorporated by reference in their entirety.

Provisional Applications (1)
Number Date Country
61865695 Aug 2013 US
Divisions (1)
Number Date Country
Parent 14911817 Feb 2016 US
Child 17067856 US