JP3540657B2 - Method and apparatus for continuous welding processing of polymer film - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method and an apparatus for welding a polymer film, for example, a label storage bag made of a synthetic resin film, a binding hole peripheral edge reinforcing film (eyelet), and the like.
[0002]
[Prior art]
Generally, labels for document files, albums, books, etc. and labels for organizing can be inserted into and removed from a label storage bag made of a synthetic resin film such as vinyl attached to the file and used. Is being done. This label storage bag has a base film (also known as release paper) on the back side, which is polymerized so that it can be peeled off via the glue surface. Necessary portions are welded and cut so that a label accommodating portion is formed, and a label insertion opening is cut out in the cover film of the label accommodating portion. Is attached to a document file or the like.
[0003]
Conventionally, welding of the base film and the cover film of the label storage bag is performed by intermittent feeding using a high-frequency welder (heated mold).
Further, when spelling a document or paper, a ring-shaped vinyl eyelet is attached around a binding hole for passing a string or a binding tool, such as a document, a paper, or a paper shears, to reinforce. This vinyl eyelet is formed by laminating a transparent or translucent cover film on the surface of a base film on which a backing has been polymerized so that it can be peeled off via a glue surface. Are intermittently welded by a high-frequency welder, and then both films are cut into a ring shape so that they can be peeled off from the mount. When using the eyelets, the ring-shaped eyelets are peeled off from the backing paper, and the adhesive surface of the base film is adhered to the paper scissors or the binding holes of the documents.
[0004]
[Problems to be solved by the invention]
By the way, the conventional welding process of a polymer film is performed by intermittent feeding using a high-frequency welder, so that there is a problem that the efficiency is extremely low.
SUMMARY OF THE INVENTION The present invention has been made in view of the above situation, and an object of the present invention is to provide a method and an apparatus for continuously welding a polymer film, which can improve the processing efficiency by continuously feeding a workpiece. To be.
[0005]
[Means for Solving the Problems]
In the present invention, the following technical measures are taken to achieve the above object.
That is, the present invention supplies a base film on which a backing is polymerized so that the backing can be peeled off via a glue surface to a rotary printing machine to continuously print characters, designs, colors, etc. on the surface of the base film. A printing step, a cover film polymerization step of superimposing a transparent or translucent cover film on the surface of the base film after printing, and a base film on which the cover film is polymerized is used as a workpiece, and the workpiece is formed on the outer periphery. A continuously rotating rotary mold having a welded portion consisting of a projection or a ridge corresponding to a required welded portion of the workpiece on the surface, and a rotary mold corresponding to the mold and disposed parallel to the axis thereof and opposed to the mold. It is continuously fed between an ultrasonic transducer that is formed in the shape of a squirrel whose upper surface is an arc surface of an upwardly protruding ridge and that reciprocates only in the vertical direction by an ultrasonic transmitter. Ultrasonic welding process for welding required parts, film cutting process for continuously cutting the workpiece after welding into a required shape with a rotary cutter, and continuous removal of cutting chips via cutting roller. Cutting process to cut the backing paper with a rotary cutter, printing process on the base film → cover film polymerization process → ultrasonic welding process → film cutting process → cutting debris removing process → The feature is that the mount cutting process is performed continuously.
[0006]
According to the method of the present invention, the workpiece, for example, the base film and the cover film constituting the label accommodating bag, during continuous transfer, only the portion that comes into contact with the welded mold portion of the rotary mold surface is welded by frictional heating and is continuously welded And very efficiently welded. Therefore, the welding means can be easily incorporated into the preceding or subsequent continuous processing step, and the productivity can be improved.
Specifically, the base film and the cover film can be cut into a required shape (for example, a label storage bag, an eyelet, etc.) immediately after the material to be processed, for example, the base film and the cover film are welded. Further, before or after the cutting of the film, only a part of the cover film can be cut (for example, cut at the label insertion opening of the label storage bag).
[0007]
Further, the method of the present invention can be incorporated after the printing step of the base film and the step of polymerizing the cover film, and it is also possible to independently weld a film in which both films are polymerized. It should be noted that the base film can be made of synthetic resin and printed or of any color, and the cover film can be transparent or translucent and of any color.
Further, the continuous welding apparatus for a polymer film according to the present invention is a rotary printing machine that prints characters, designs, colors, etc. on the surface of the base film on which the backing is polymerized so that the backing can be peeled off via the adhesive surface, A film feeding means for taking out the base film after printing, superimposing a transparent or translucent cover film on the surface thereof and sending out the work material, and a work material sent out by the film feeding means, a work material on an outer peripheral surface. A continuously rotating rotary mold provided with a welding mold portion consisting of a projection or a ridge corresponding to the required welding portion, and a surface opposed to the mold, which is disposed parallel to the axis of the mold and faces the mold, faces upward. It is continuously fed between an ultrasonic vibrator, which is formed in the shape of a circular arc of a ridge and is reciprocally oscillated only in the vertical direction by an ultrasonic transmitter. Ultrasonic welding means for performing welding of a minute, a film cutting means for continuously cutting a workpiece after welding into a required shape by a rotary cutter, and a cutting waste removing roller for cutting the cutting waste of the film cut by the film cutting means. Cutting debris removing means for continuously removing through, a mount cutting means for continuously cutting the mount of the workpiece cut by the film cutting means with a rotary cutter, the film cutting means and the mount cutting means, And a workpiece transfer means arranged to continuously transfer the workpiece therebetween.
[0008]
In this case, the workpiece to be continuously fed generates frictional heat due to the vibration of the ultrasonic vibrator at a portion in contact with the projection or ridge portion of the rotary mold that is continuously rotating, that is, the welding portion, and the polymer film is formed. Weld together. Therefore, the workpiece is continuously and efficiently welded at the contact point with the welding mold portion of the rotary mold. The ultrasonic transducer has a mold facing surface on a mold facing side.
Further, on the upper side of the ultrasonic welding means, a film feeding means having a function of superimposing the synthetic resin film can be provided, and the polymerization of the film and the feeding of the workpiece can be performed. It can be performed simultaneously and efficiently.
[0009]
On the lower side of the ultrasonic welding means, a film cutting means for cutting the surface side film of the workpiece into a required shape is provided, and the cutting debris of the film generated by the cutting means is removed. It is possible to adopt a configuration in which cutting waste removing means is provided. With this configuration, it is possible to continuously process a large number of workpieces such as label storage bags and eyelets, and simultaneously process cutting waste generated by cutting. .
Further, on the lower side of the film cutting means, a mount cutting means capable of cutting the mount on which the work material processed by the film cutting means is formed is provided, and between the film cutting means and the mount cutting means, with high accuracy. It is preferable that a work material transfer means is provided so that the work material can be supplied from the film cutting means to the backing sheet cutting means, whereby the cover film or the base film is cut into a required shape or the backing sheet is cut. Can be performed with high accuracy, and quality can be improved.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 3 show an embodiment of an apparatus 1 for carrying out a method for welding a polymer film according to the present invention. The polymer film made of a synthetic resin (for example, made of vinyl) as the workpiece 2 is used to process the label storage bag 3 illustrated in FIGS. 4 to 7, and the backing paper 4 is peeled off via the glue surface 5 on the back surface. It consists of a base film 2A that has been polymerized as much as possible and a transparent or translucent cover film 2B superimposed on the surface of the base film 2A.
[0011]
As shown in FIGS. 4 to 7, the label storage bag 3 is rectangular and has welds 6 on four sides (indicated by solid lines in FIG. 4), and the label 7 is stored in a substantially central portion in the width direction. A welding portion 9 (shown by a dotted line in FIG. 4) extending in the longitudinal direction forming the label accommodating portion 8 is provided, and the label accommodating portion 8 has a label insertion opening 10 formed in the cover film 2B. When using the storage bag 3, the backing paper 4 is peeled off, the glue surface 5 is attached to the shoulder of the file, etc., desired items are written on the label 7, and the label 7 is inserted into the storage bag 8 with the label insertion slot. Open 10 and insert. The base film 2A can be color-printed in any color, and can be a film on which any line, character, pattern, or the like is printed.
[0012]
In front of the welding apparatus 1 shown in FIG. 1, a rotary printing machine 11 is disposed on the upper side, and a cover film superposing / feeding unit 12 is disposed on the lower side. The welding apparatus 1 includes an ultrasonic welding unit 13 for welding a required portion of the cover film 2B and the base film 2A on which the backing paper 4 is superimposed via the glue surface 5 on the back surface, and welding by the welding unit 13. Film cutting means 14 for cutting the work material 2 composed of the base film 2A and the cover film 2B, and processing the cutting waste of the cover film 2B and the base film 2A generated by the cutting processing by the cutting means 14. Cutting waste removing means 15, work material transfer means 16 for accurately supplying the superimposed mount 4 together with the work material 2 processed by the film cutting means 14 to the subsequent process, and transfer from the transfer means 16 It is mainly composed of mount cutting means 17 for cutting the mount 4 on which the processed workpiece 2 is superimposed into a predetermined length.
[0013]
The rotary printing machine 11 prints characters, designs, colors, and the like on the front surface of a base film 2A having a backing material on which a backing 4 is superimposed, and may employ a printing device conventionally used for label printing or the like. The base film 2A sent out from the printing press 11 is guided by the guide roller group 24, is guided again by the guide roller group 24 via the meandering correction device 23, and is guided to the cover film superimposing / feeding means 12.
The film superimposing / feeding unit 12 includes a pair of upper and lower pinch rollers including a rubber roller 25 and a metal roller 26, and a cover film guide roller 27. The cover film 2B wound on a payout reel 28 is used as a film. The film is fed by a feeder 29, is superposed on the surface of the base film 2A fed between the pinch rollers, and is fed to the welding means 13.
[0014]
As shown in FIGS. 2 and 3, the ultrasonic welding means 13 includes a rotary mold 19 which is continuously rotated, and an ultra-low-pressure tool provided in parallel with the mold axis below the mold 19 in correspondence with the mold 19. It comprises a sound wave oscillator 20 and an ultrasonic wave transmitter 21. The rotary mold 19 is provided with a required welding portion, that is, a welding mold portion 22 formed of small projections or ridges for forming the welding portions 6 and 9 on the outer peripheral surface.
The ultrasonic transducer 20 has a surface facing the rotary mold 19 as an upwardly protruding arc-shaped surface, and is formed in a concave shape. The ultrasonic oscillator 21 reciprocates vertically (60 μm). The stroke vibrates 20,000 times per second).
[0015]
The film cutting means 14 is disposed on the lower side of the ultrasonic welding means 13 and includes a lower roller 30 and a half-cut rotary cutter 31 provided in parallel above the lower roller 30. The cutter 31 is a half-cut blade (not shown) for cutting the base film 2A and the cover film 2B outside the welded portion 6 to form the rectangular label storage bag 3, and only the cover film 2B has a one-character label. A half-cutting blade (not shown) for cutting and opening the insertion opening 10.
The cutting waste removing means 15 is composed of a cutting waste take-up reel 32 and a winder 33 disposed on the upper right side of the film cutting means 14, and the cutting waste removal disposed on the lower side of the film cutting means 14. By the use rollers 34, the scrap portion of the cover film 2 </ b> B and the base form 2 </ b> A generated by the film cutting unit 14, that is, the scrap 35, is peeled off from the backing paper 4 and wound on the take-up reel 32.
[0016]
The workpiece transfer means 16 is provided on the lower side of the cutting waste removing roller 34 and includes a lower metal roller 36 and an upper rubber roller 37.
The mount cutting means 17 is provided on the lower side of the workpiece transfer means 16 and includes a lower roller 38 and a full-cut rotary cutting cutter 39 provided in parallel with the lower roller 38. The cutter 39 has a full cutting blade (not shown) that can cut the mount 4 into a predetermined length.
An unloading means 41 for transferring the product 40 cut by the cutting means 17 to the downstream side is provided below the mount cutting means 17.
[0017]
Next, a case where the method for welding a polymer film according to the present invention using the apparatus 1 of the above embodiment will be described with reference to FIG.
First, on the front surface of the base film 2A on which the backing 4 is superimposed and corona-treated, the printing machine 11 prints necessary items, colors, and the like. 12 is introduced such that the base film 2A is on the upper side. At the same time, the cover film 2B is fed by the film feeder 29 and fed between the upper and lower rollers 25 and 26 of the cover film superposing / feeding means 12 so as to overlap the surface of the base film 2A, as shown in FIG. The polymer film, that is, the workpiece 2, is sent out by the upper and lower rollers 25 and 26 and guided to the ultrasonic welding means 13.
[0018]
The workpiece 2 continuously fed between the rotating rotary mold 19 of the ultrasonic welding means 13 and the ultrasonic vibrator 20 comes into contact with the welding mold portion 22 of the mold, The vibration of the ultrasonic vibrator 20 generates frictional heat, and the base film 2A and the cover film 2B are sequentially welded to each other at that position, so that the welded portions 6 and 9 shown in FIGS. 4 to 8B are continuously formed. At the same time, the label storage bags 3 each having the label storage section 8 are formed in two rows.
In this way, the workpiece 2 to which the required portion has been welded is fed to the film cutting means 14 together with the backing paper 4 and is rotated by the rotary cutter 31 at the end of each label accommodating portion 8 of the cover film 2B as shown in FIG. As shown in FIG. 8 (d), the label insertion opening 10 is cut open, and as shown in FIG. 8 (d), the outside of the welded portion 6 defining the label containing bag 3 (in FIG. The base film 2A and the cover film 2B at the position ()) are cut. Then, the cutting waste 35 of the base film 2A and the cover film 2B cut by the cutting waste removal roller 34 is removed from the backing paper 4, and only the label accommodating bag 3 is superimposed on the backing paper 4 via the glue surface 5. The label storage bag 3 is easily peeled off from the backing paper 4.
[0019]
The backing paper 4 on which the label storage bag 3 is superimposed is sent to the backing paper cutting means 17 via the workpiece transfer means 16, and the backing paper 4 is cut into a predetermined length to form two vertically arranged labels. The product 40 in which the storage bags 3 are arranged in a predetermined row (for example, one row in FIG. 8E) is manufactured, and is discharged by the unloading means 40 to the subsequent continuation.
On the other hand, the cutting waste 35 of the base film 2 </ b> A and the cover film 2 </ b> B outside the rectangular label storage bag 3 peeled from the backing paper 4 by the cutting waste removal roller 34 is taken up by the take-up roll 32.
[0020]
In this manner, the welding process of the workpiece 2 is continuously and efficiently performed together with the printing of the base film 2A and the polymerization of the cover film 2B.
Further, the cutting of the workpiece 2 and the processing of the cutting waste 35 generated by the cutting can be continuously and efficiently performed, and the productivity can be improved.
In the above-described embodiment, the slitter 42 that continuously cuts the middle in the width direction of the films 2A, 2B and the backing sheet 4 along the longitudinal direction is provided between the cutting waste removal roller 34 and the transfer means 16 to be processed. It may be arranged between the film cutting means 14 and the cutting waste removing roller 34 shown by a dotted line in FIG. In this way, two strips of the backing sheet 4 in which the label storage bags 3 are formed in one row are obtained, and the backing sheet 4 is supplied to the backing sheet cutting means 17 to be cut and processed. The products 40 arranged in the same manner can be manufactured.
[0021]
Alternatively, the backing sheet cutting means 17 may be removed, and the backing sheet 4 having the label storage bags 3 formed in two rows or one row may be directly wound around a winding roll (not shown).
A case in which the polymer film 46 having the synthetic resin film eyelets 45 shown in FIG. 9D is welded by partially changing the apparatus 1 will be described.
As shown in FIG. 9D, the eyelet 45 has a ring shape having a circular hole 55 at the center, and a colorless or arbitrary color base film 46A and a transparent or translucent cover film 46B have an outer periphery. And a welded portion 49 welded on the outer periphery of the hole 55.
[0022]
The polymerized film 46 is formed by polymerizing a large number of eyelets 45 on a backing sheet 47 via a glue surface on the back surface of the base film 46A.
The difference between the apparatus for producing the polymerized film 46 having the eyelets 45 formed thereon and the apparatus 1 of the above embodiment is that the rotary mold 19 constituting the ultrasonic welding means 13 and the one-side rotation which constitutes the film cutting means 14. The other configuration is the same as that of the device 1 of the above embodiment.
The rotary mold 19 is provided with a large number of welded mold portions 22 formed of large and small concentric ridges on the outer peripheral surface in order to form welded portions 48 and 49 of the eyelets 45.
[0023]
The half-cut rotary cutter 31 has a half-cut blade (not shown) for cutting the base film 46A and the cover film 46B around the outer periphery of the trapezoidal welding portion 48 (two-dot chain line 50 shown in FIG. 9C) and small-diameter welding. It is provided with a base film 46A, a cover film 46B, and a full cutting blade (not shown) for cutting the portion of the inner periphery of the part 49 (two-dot chain line 51 shown in FIG.
Next, a method for welding a polymer film 46 having a synthetic resin film eyelet 45 formed thereon using the above-described apparatus will be described with reference to FIG.
[0024]
The base film 46A with the backing 47 superposed and corona-treated is introduced into the cover film superimposing / feeding unit 12 via the meandering correcting device 23 so that the base film 46A is on the upper side. At the same time, the cover film 46B is fed by the film feeder 29 and fed between the upper and lower rollers 25, 26 of the cover film superposing / feeding means 12 so as to overlap the surface of the base film 46A, as shown in FIG. The polymer film, that is, the material to be processed 46 is sent out by the upper and lower rollers 25 and 26 and guided to the ultrasonic welding means 13.
[0025]
The workpiece 46 continuously fed between the rotating rotary mold 19 of the ultrasonic welding means 13 and the ultrasonic vibrator 20 comes into contact with the welding mold portion 22 of the mold, The vibration of the ultrasonic vibrator 20 generates frictional heat, and the base film 46A and the cover film 46B are sequentially welded to each other at that position. As shown in FIG. 9B, the welded portions 48 and 49 on large and small concentric circles are continuously formed. At the same time, eight rows of eyelets 45 are formed.
In this way, the workpiece 46 to which the required portion has been welded is sent to the film cutting means 14 together with the backing sheet 47, and is rotated by the rotary cutter 31 on the outer peripheral side of the large-diameter welded portion 48 (two points shown in FIG. 9C). The base film 46A and the cover film 46B of the small-diameter welded portion 49 (two-dot chain line 51 shown in FIG. 9C) are cut off while cutting the base film 46A and the cover film 46B of the chain line 50). Cut. Then, the cutting chips 35 of the base film 46A and the cover film 46B cut by the cutting chip removing roller 34 are removed from the backing sheet 47, and the ring-shaped eyelets 45 having the holes 55 are superimposed on the backing sheet 47 via the glue surface. The eyelets 45 are easily detached from the mount 47.
[0026]
The mount 47 on which the eyelets 45 are superimposed is sent to the mount cutting means 17 via the workpiece transfer means 16 and cuts the mount 47 to a predetermined length, so that eight vertically aligned eyelets 45 are formed. Products 56 arranged in a predetermined row (for example, two rows in FIG. 9D) can be manufactured.
On the other hand, the cutting waste 52 of the base film 46A and the cover film 46B around the eyelet 45 peeled off from the backing sheet 47 by the cutting waste removal roller 34 is taken up by the take-up roll 32.
[0027]
The eyelets 45 thus processed are peeled off from the backing sheet 47, and the glue surface on the back side of the base film 46A is attached to the outer periphery of a punch hole for a document, a file, or the like to reinforce the periphery of the punch hole. it can.
In addition, all the cutting blades for cutting the base film 46A, the cover film 46B, and the mount 47 on the inner periphery of the small-diameter welded portion 49 (two-dot chain line 51 shown in FIG. 9C) may be provided in the mount cutting means. .
In the above embodiment, the design can be changed as appropriate. For example, the label accommodating bag 3, the workpieces 2, 46 of the eyelets 45 are superposed and the mounts 4, 47 are in a state of being peelably adhered, It can be supplied to the ultrasonic welding means 13 and welded. Further, the welded portion 9 of the label storage bag 3 can be formed in a solid line (continuous line) like the welded portion 6 without being formed in a dotted line, and the welded portion 6 and the eyelet of the storage bag 3 can be formed. The welding portions 48 and 49 of the 45 can be formed in a dotted line like the welding portion 9.
[0028]
4 and FIG. 8, a portion indicated by a broken line (discontinuous shape) 53 is a welded portion. The label containing bag 3 is provided so as to be easily folded by the welded portion 53. Depending on the shape and size of No. 3, it may not be necessary, and can be appropriately selected.
In the above embodiment, the case where the bonding process is performed while the mount is superimposed on the polymerized film is extended. However, in the present invention, a plurality of films in which the mount is not superimposed, for example, two or three films are polymerized and welded. The present invention is applicable not only to the label storage bag 3 and the eyelets 45 but also to the welding process of various polymer films.
[0029]
【The invention's effect】
According to the method for welding a polymerized film according to the present invention, as described above, the workpiece is continuously fed between the rotary mold that continuously rotates and the ultrasonic vibrator arranged corresponding to the mold. Since a required portion of the workpiece is fed and welded, welding can be continuously and efficiently performed, and productivity can be improved.
Further, the apparatus for welding a polymerized film according to the present invention includes a rotary mold provided with a projection or a ridge corresponding to a required welding amount on an outer peripheral surface, and a super mold arranged in parallel with an axis thereof corresponding to the mold. Since it is constituted by an ultrasonic welding means comprising an ultrasonic oscillator and an ultrasonic transmitter, and a means for continuously feeding a workpiece between the rotary mold and the ultrasonic oscillator, polymerization is performed. The required welding portion of the film can be welded continuously and reliably and efficiently, and the apparatus can be made relatively simple.
[Brief description of the drawings]
FIG. 1 is an overall schematic side view showing one embodiment of a polymer film welding apparatus according to the present invention.
FIG. 2 is an enlarged side view showing a schematic configuration of an ultrasonic welding unit in the embodiment.
FIG. 3 is an enlarged sectional view taken along line AA of FIG. 2;
FIG. 4 is a plan view of a label storage bag which is an example of a polymer film.
FIG. 5 is a side view of the label storage bag.
FIG. 6 is an enlarged sectional view taken along line BB of FIG. 4;
FIG. 7 is an enlarged cross-sectional view taken along the line CC of FIG. 4;
FIGS. 8A to 8E are explanatory views of a welding process of a label storage bag which is an example of a polymer film.
FIGS. 9A to 9D are explanatory views of a welding process of eyelets, which is an example of a polymer film.
[Explanation of symbols]
1 Welding and processing equipment for polymer film 2 Work material (polymer film)
2A Base film 2B Cover film 3 Label storage bag 4 Backing paper 5 Adhesive surface 6 Welding part 9 Welding part 10 Label insertion opening (cut part)
12 Film superposition / feeding means 13 Ultrasonic welding means 14 Film cutting means 15 Cutting debris removing means 16 Workpiece transfer means 17 Mount cutting means 19 Rotary mold 20 Ultrasonic vibrator 21 Ultrasonic transmitter 22 Welding mold part 45 Eyelet (polymerized film)
46 Work material 46A Base film 46B Cover film 47 Backing sheet 48 Welding part 49 Welding part 52 Cutting chips

Claims (3)

A printing step of supplying a rotary printing machine with a base film on which a backing paper is peelably polymerized through a glue surface, and continuously printing characters, patterns, colors, etc. on the surface of the base film; A cover film polymerization step of superimposing a transparent or translucent cover film on the surface of the base film, and using the base film on which the cover film is polymerized as a workpiece, and applying the workpiece to the outer peripheral surface of the workpiece. A continuously rotating rotary mold provided with a welding portion consisting of a projection or a ridge corresponding to a required welding portion, and a surface facing the mold is disposed in parallel with an axis of the rotary mold corresponding to the mold and has an upward ridge. It is continuously fed between an ultrasonic vibrator, which is formed in a circular shape with a circular arc surface and is reciprocated only in the vertical direction by an ultrasonic transmitter, and melts a required portion of the workpiece. Ultrasonic cutting step, a film cutting step of continuously cutting the workpiece after welding into a required shape with a rotary cutter, and a cutting chip removing step of continuously removing cutting chips via a cutting chip removing roller. And a mounting sheet cutting step of continuously cutting the mounting sheet with a rotary cutter.The printing step on the base film → the cover film polymerization step → the ultrasonic welding step → the film cutting step → the cutting debris removing step → the mounting sheet cutting step continuous fusion bonding method of polymerization film, characterized in that to perform continuously. The method according to claim 1, wherein only a part of the cover film is continuously cut before or after cutting the base film and the cover film . A rotary printing machine that prints characters, designs, colors, etc. on the surface of the base film on which the backing has been polymerized so that it can be peeled off via the glue surface, and the base film after printing is taken off and the surface is transparent or translucent. A film feeding means for superimposing the cover film and sending it as a material to be processed, and a material to be processed which is fed by the film feeding means, a welding die comprising a projection or a ridge corresponding to a required welding portion of the material to be processed on the outer peripheral surface. A rotary mold having a continuously rotating portion having a portion and a kamaboko mold corresponding to the mold and arranged in parallel with the axis thereof and having a surface facing the mold as an arc surface of an upwardly projecting ridge, An ultrasonic welding means for continuously feeding a required portion of the workpiece by being continuously fed to an ultrasonic vibrator which is reciprocally oscillated only in the vertical direction by an ultrasonic wave transmitter; Processing materials Film cutting means for continuously cutting into a required shape with a rotary cutter, cutting waste removing means for continuously removing the cutting waste of the film cut by the film cutting means via a cutting waste removing roller, and the film cutting means. Mount cutting means for continuously cutting the cut material of the work with a rotary cutter, and a work arranged between the film cutting means and the mount cutting means for continuously transferring the work. An apparatus for continuously welding a polymerized film, comprising: a processing material transfer means.

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