JPH04138231A - Advancing device for transfer film - Google Patents

Abstract

PURPOSE:To carry out simultaneously the positioning of a film in the longitudinal direction and in the width direction while adjusting the inclination of the film by disposing at least either of a film advancing device or a film take-up device to be able to rock to a mold around the given fulcrum. CONSTITUTION:A film longitudinal direction positioning sensor 24 for sensing a longitudinal direction positioning mark 5a and a take-up side film width direction positioning sensor 34 disposed on the film take-up side to the center of a mold 54 positioning mark 5b are installed. Further, a film take-up device 35 is disposed to be able to rock around the fulcrum 43 almost 10 parallel with a film advancing plane to the mold 54, and the film take-up device 35 is rocked around the fulcrum by a second driving device 39.

Description

[Detailed description of the invention]

Industrial Field of Application The present invention relates to the parting of the mold in simultaneous molding painting in which a pattern of a transfer film is transferred to the surface of the molded resin at the same time as molding by the heat and pressure of molten resin injected into the mold. The present invention relates to a transfer film feeding device for accurately positioning the transfer film relative to a surface while winding up the used film. 2. Prior Art Conventionally, this type of transfer film positioning device has been known to have various structures.

[)ru. For example, as shown in FIG. 4, the transfer film 5 has longitudinal positioning marks 5a formed along the longitudinal direction of the film at predetermined intervals, and marks 5a formed continuously in the longitudinal direction of the film at one end in the width direction of the film. The width direction positioning mark 5b is also grown. For such films, the following film feeding device is known (Japanese Unexamined Patent Publication No. 59-204522). The film is fed along the longitudinal direction, and the film is first positioned in the longitudinal direction with respect to the cavity of the mold. After that, in order to position the film in the width direction, the frame supporting the film is returned to its initial position, and then the frame starts moving from the initial position, and while the film is moved in the width direction, the width direction positioning sensor Detection of the film width direction positioning mark is started. Then, the film is positioned by stopping the movement of the film when detecting the amount of positional deviation of the mark on the frame from the initial position of the frame. Furthermore, there are positioning devices with other structures as described below (Japanese Patent Publication No. 1-59095). That is, by fixing the film feeding side unit and moving the film winding side unit in the film width direction, positioning of the film in the longitudinal direction is completed, and then only the film winding side unit is moved horizontally in the film width direction. The film is positioned in the width direction. Problem to be Solved by the Invention However, in the former structure described above, since the film feeding side unit and the film winding side unit are assembled in the same frame, it is difficult to connect the film winding side unit to the film feeding side unit. There is a problem in that the only way to adjust the tilt of the film is by moving it. In addition, even in the latter case, as shown in FIG. 9, since the film feed ω reunit 87 is fixed,
Positioning by moving the film winding side unit 88 has poor positioning accuracy and requires time and effort, and since the film winding side unit 88 moves horizontally in the film width direction, the mold and film feeding device If the parallelism with the film is out of order or if the film itself is tilted due to deformation, there is a problem in that wavy stains 90 occur on the pattern surface of the film to be transferred. Therefore, an object of the present invention is to solve the above-mentioned problems, and is capable of achieving high positioning accuracy, shortening the positioning work time, and preventing undulating stains on the transfer film that occur during film width direction positioning. An object of the present invention is to provide a transfer film feeding device that can prevent the above problems. Means for Solving the Problems In order to achieve the above object, the present invention provides at least one of a film feeding device and a film winding device arranged so as to be swingable around a predetermined fulcrum with respect to a mold, When feeding the film, one of the devices is swung around a fulcrum to adjust the inclination of the film and simultaneously position the film in the longitudinal direction and in the width direction. That is, the present invention has a longitudinal positioning mark arranged along the longitudinal direction of the film at predetermined intervals and a widthwise positioning mark continuously formed in the longitudinal direction of the film at one end of the film width direction. a film feeding device that feeds out a transfer film wound into a roll; a film longitudinal positioning sensor that detects the longitudinal positioning mark; a winding-side film width direction positioning sensor arranged to detect the width direction positioning mark; and a winding side film width direction positioning sensor arranged to be swingable about a fulcrum in a plane substantially parallel to the film feeding surface with respect to the mold; The film winding device is configured to include a film winding device that winds the film, and a second drive device that swings the film winding device about the fulcrum. In the above configuration, the feeding device is disposed in the mold so as to be movable in the film width direction, and is disposed on the film feeding side with respect to the center of the mold along the film feeding direction, and is positioned in the width direction. It may be configured to further include a feed-out side film width direction positioning sensor 7 for detecting the film width direction positioning sensor 7, and a first drive device for moving the feed device in the film width direction. Further, the present invention includes longitudinal positioning marks arranged along the longitudinal direction of the film at predetermined intervals, and a widthwise positioning mark continuously formed in the longitudinal direction of the film at one end of the film width direction. In addition to feeding out the transfer film wound into a roll, a film feeding device is arranged to be able to swing around a fulcrum in a plane approximately parallel to the film feeding surface with respect to the mold, and the film feeding device is moved around the fulcrum. a first drive device that swings the film in the width direction; a film longitudinal positioning sensor that detects the longitudinal positioning mark; and a film longitudinal positioning sensor that detects the longitudinal positioning mark; The present invention is configured to include a feed-out side film width direction positioning sensor that detects a positioning mark, and a film winding device that winds up the film. In the above configuration, the film winding device is disposed to be movable in the film width direction, and is disposed on the film winding side with respect to the center of the mold along the film feeding direction, and for positioning in the width direction. It can also be configured to include a winding-side film width direction positioning sensor that detects marks, and a second drive device that moves the film winding device in the film width direction. Further, the present invention includes longitudinal positioning marks arranged along the longitudinal direction of the film at predetermined intervals, and a widthwise positioning mark continuously formed in the longitudinal direction of the film at one end of the film width direction. In addition to feeding out the transfer film wound into a roll, a film feeding device is arranged to be able to swing around a fulcrum in a plane approximately parallel to the film feeding surface with respect to the mold, and the film feeding device is moved around the fulcrum. a first drive device that swings the film in the width direction; a film longitudinal positioning sensor that detects the longitudinal positioning mark; and a film longitudinal positioning sensor that detects the longitudinal positioning mark; a feeding side film width direction positioning sensor that detects the positioning mark; and a winding side film arranged on the film winding side with respect to the center of the mold along the film feeding direction and detecting the width direction positioning mark. a width direction positioning sensor, and a sensor arranged to be able to swing around a fulcrum in a plane approximately parallel to the film feeding surface with respect to the mold;
The film winding device is configured to include a film winding device that winds the film, and a second drive device that swings the film winding device about the fulcrum. Each of the above configurations is configured to include a pair of first guide rollers that are arranged integrally with the film feeding device and guide the film to the mold side while sandwiching the film fed from the film feeding device. You can also do it. Each of the above configurations also includes a pair of second guide rollers that are disposed integrally with the film winding device and guide the film from the mold side to the film winding side while sandwiching the film. It can also be configured as Effects and Effects of the Invention According to the above configuration, at least one of the film feeding device and the film winding device is arranged to be swingable around a predetermined fulcrum with respect to the mold, and when feeding the film,
While adjusting the inclination of the film by swinging one of the pair of devices around the fulcrum, the film can be simultaneously positioned in the longitudinal direction and in the width direction. Therefore, positioning accuracy is high, positioning work time can be shortened, and it is possible to prevent the transfer film from becoming wavy and stained during positioning in the film width direction. Examples 1 to 8.1011 of the present invention are described below.
This will be explained in detail based on FIG. As shown in FIG. 1.2, the transfer film feeding device according to this embodiment is a film feeding device that feeds the roll-shaped transfer film 5 to the cavity 54a of the f2 movable mold 54, which is supported by the movable guide plate 14. The molten resin is sent out from l and positioned with respect to the cavity 54a, while after the molding is completed, that is, the mold 54 is closed and the molten resin is transferred to the mold 54.
The resin is injected into the cavity 54a to transfer the transfer pattern 5c of the transfer film 5 at the same time as molding, cool the resin, open the mold 54 and take out the molded product, and then feed the film 5 by a predetermined pitch and perform the next molding. It is designed to prepare for. Specifically, the film feeding device includes a film feeding device 1 that rewinds the transfer film 5 wound into a roll, and a first frame 7 on the feeding side supported by a mold 54 so as to be movable in the width direction of the film. a pair of first guide rollers 2.12 that sandwich and guide the film 5 fed out from the feed-out device 1 to the mold side; and the first frame 7 that supports the first guide rollers 2.12.
a first drive device 16 for moving the film in the film width direction; a film longitudinal positioning sensor 24 supported by the mold 54 and detecting a longitudinal positioning mark 5a described below; A first film width direction positioning sensor 2 on the feed side that is arranged closer to the film feed device than the center along the feed direction and detects a film width direction positioning mark 5b described below.
2, and a second film width direction positioning sensor 34 on the winding side, which is disposed on the film winding side from the center of the mold 54 in the film feeding direction and detects the width direction positioning mark 5b. , sandwiching the film 5 that is supported by the second frame 30 on the winding side that is swingable around the fulcrum 43 in a plane approximately parallel to the film feeding surface with respect to the mold 54 and discharged from the mold 54. a pair of second guide rollers 3637 that guide the film toward the film winding side; a second drive device 39 that moves the second frame 30 supporting the second guide rollers 36, 37 in the film width direction; It includes a film winding device 35 that winds up the film 5 guided via second guide rollers 36 and 37. As shown in FIG. 4, the film 5 has longitudinal positioning marks 5a printed along the longitudinal direction of the film corresponding to the patterns 5c to be transferred at predetermined intervals, and marks 5a for longitudinal positioning at one end in the width direction of the film. The film has width direction positioning marks 5b continuously printed and having a constant width dimension in the longitudinal direction of the film. The mold 54 is supported by the movable die plate 14, and above and below the cavity 54a of the mold 54 are bar-shaped pressing members 50 that extend in the film width direction and press the film 5 against the mold parting surface. 50. Each pressing member 50 is connected via a rod 51 to a drive plate 53 which is biased by a spring 52 in a direction to press the film 5 against the parting surface. Therefore, while the film 5 is normally pressed against the parting surface of the mold 54 by the pressing member 50.50 by the spring 52.52, the drive plate 53 is moved toward the capitivity side against the biasing force of the spring 52.52. That is, when the film 5 is moved to the right in FIG. 2, the holding of the film 5 by the holding member 50 is released, and the film 5 can be moved freely. On the other hand, the film feeding unit disposed above the mold 54 of the film feeding device has the following configuration. An adapter plate 13 is fixed to the upper part of the mold 54, and the first frame 7 is attached to the adapter plate 13 so as to be swingable about a fulcrum 15. Therefore, by swinging the first frame 7 around this fulcrum 15 by a drive device (not shown) or manually, the inclination of the film 5 on the feeding side can be adjusted. This first frame 7 has a dovetail groove 7a formed in its upper part so as to extend in a direction perpendicular to the film feeding direction, that is, in a direction penetrating the plane of the paper in FIG. A trapezoidal support base 6 is movably fitted into this dovetail groove a. A rack 10 is formed on the lower surface of the support base 6, and a rotating shaft I9 to which a pinion 26 that meshes with the rack 10 is fixed is disposed so as to pass through the first frame 7. A handle 20 is disposed at the outer end of the rotating shaft 19. Therefore, when replacing the mold 54 or placing it for the first time, the binion 26 is rotated by the rotating operation of the handle 20, and the first frame 7 is moved perpendicularly to the film feeding direction with respect to the support base 6 via the rack 1o. The position can be adjusted in the direction of A casing 32 is arranged above the support stand 6. This casing 32 includes, as shown in FIG.
A feed-out roller 1 as the feed-out device has its rotating shaft 1a rotatably supported, and a brake roller 2 is similarly rotatably supported, and guide rollers 11 and 12 are provided on both sides of the brake roller 2. supported so as to be in contact with each other and to freely rotate, further 1;
A guide roller 3 is rotatably supported at one end of the casing 32. The surface of the brake roller 2 is provided with rubber. The above brake roller 2 and guide roller I
2 constitute the first guide roller. Therefore,
The film 5 fed out from the feeding roller 1 is sandwiched between the brake roller 2 and the guide roller 11 and between the brake roller 2 and the inner roller 12, and then directed downward toward the mold side by the guide roller 3. You will be guided as follows. A coupling 28 is attached to the rotating shaft of the brake roller 2.
A powder brake 27 is connected via. Although not specifically shown in the drawings, it is preferable to attach three disks to the rotation shaft of the feed roller l in order to stop the inertial force in the rotation after rotating to feed the film 5. It is preferable to install a stage which prevents the rotation caused by the inertial force by applying a brake to this disc by frictional force. Therefore, the upper feed-out roller l is configured to stop rotating when the film 5 is fed at a predetermined pitch. That is, a pair of straight rails 99 are fixed to the upper surface of the support base 6, and a rail 8.8 that movably fits the rails 9.9 is fixed to the lower surface of the casing 32. Then, the opening 32a of the casing 32 is opened from the support stand 6.
A nut is built into the protruding portion 6a that protrudes through the body, and a trapezoidal screw shaft 18 screwed into the nut is connected to the stepping motor 16 via a coupling 17. This stepping motor] 6 is fixed to the casing 32. Therefore, when the screw shaft 18 is rotated by the driving of the stepping motor 16, the stepping motor 16 moves in the film width direction relative to the fixed casing 32 or the support base 6. On the other hand, below the support stand 6, a first width direction positioning sensor 22 made of a phototube is arranged on the right end side in the width direction of the film 5 from the support stand 6 through a lot 23 in a position adjustable manner. On the other hand, in FIG. 3, a longitudinal positioning sensor 24 made of a phototube is arranged on the left end side of the film 5 in the width direction from the support base 6 via a lot 25 so as to be adjustable in position. The first width direction positioning sensor 22 detects the position of the width direction positioning mark 5b of the film 5 on the feeding side above the mold 54, and drives the stepping motor 16 when the mark 5b starts to come off from the sensor 22. The position of the film feed unit is adjusted. For this reason, the stepping motor 16 is constantly driven to rotate during the film feeding operation, and the longitudinal positioning sensor 24 is
The position of the longitudinal positioning marks 5a of the film 5 formed at predetermined intervals on the delivery side above the mold 54 is detected. Further, the film winding unit disposed below the mold 54 of the film feeding device has the following configuration. As shown in FIG. 6.7, an adapter plate 31 is fixed to the lower part of the mold 54.
The second frame 30 is swingably attached to one fulcrum 43. Therefore, when the second frame 30 is swung around this fulcrum 43 by the drive device described below, the film 5
It is possible to adjust the inclination on the winding side. A stepping motor 39 is fixed to the second frame 30, and a trapezoidal screw shaft 4 is connected to the rotation shaft of the second frame 30 via a coupling 40.
1 is connected, and a screw shaft 41 is screwed into a nut 42. This nut 42 is rotatably supported by a protrusion 31a that protrudes from the adapter plate 31 and passes through the opening 30a of the second frame 30 about the axis of the protrusion 3]11. Therefore, the stepping motor 39
When the screw shaft 41 is rotated by the drive of Rotate around the screw shaft 4 to avoid overloading it. The second frame 30 further includes a guide roller 4 disposed below the guide roller 3 of the delivery side unit, and a casing 29. The casing 29 rotatably supports a guide roller 38, a pressure roller 36 and a drive roller 37 constituting a second guide roller, and a take-up roller 35 as a take-up device. The pressure roller 36 has rubber on its surface. The drive roller 37 has a coupling 4 on its rotating shaft.
A stepping motor 44 is connected via 5. This stepping motor 44 is fixed to the casing 29, and the stepping motor 44 drives the driving roller 37 to send the film 5 sandwiched between it and the pressing roller 36 downward, that is, toward the winding side. The pair of second guide rollers 36.37 feed the film 5 to the take-up side, while the first guide roller 122 applies a brake to the film 5. , 37 so that the film 5 is always supported with an arbitrarily set tension. Further, the rotation shaft of the take-up roller 35 is connected to a take-up motor 46 via a coupling 47 . This motor 46
is fixed to the casing 29, and the motor 46 is constantly driven to wind up the used film 5 onto the winding roller 35. In addition, a rod 3 is attached to the upper part of the adapter plate 3I.
A second width direction positioning sensor 3 consisting of a phototube via 3
4 are arranged so that their positions can be adjusted. This sensor 34 detects the position of the width direction positioning mark 5b of the film 5 on the winding side below the mold 54, and when the mark 5b is about to come off from the sensor 34, it drives the stepping motor 39 to remove the film. The position of the take-up unit is adjusted. Therefore, the stepping motor 39 is constantly driven to rotate during the film feeding operation. According to the above configuration, the positioning and feeding operations of the film 5 are performed as follows. First, when attaching the mold 54 to the movable die plate 14, the handle 20 is rotated to adjust the position of the film feeding unit in the film thickness direction with respect to the parting surface of the mold 54. Thereafter, the film 5 is wound around the take-up roller 35 from the feed roller I via the guide roller and the like, and the film 5 is fed at predetermined pitches. That is, the stepping motor 44 is driven to send the film 5 to the take-up side by the rotation of the drive roller 37. At this time, the longitudinal positioning sensor 24 detects the position of the film 5 in FIG.
The film 5 is fed at high speed for a predetermined number of pulses from the roughly square longitudinal positioning mark 5a, and after the predetermined number of pulses has been counted by the pulse counting means, the CPU
The control means further performs low-speed constant speed running for a predetermined number of pulses, and when the predetermined number of pulses is reached, the driving of the stepping motor 44 is stopped. As a result, the film 5 is stopped at the position where the sensor 24 detects the next longitudinal positioning mark 5. While the film 5 is being fed, the first width direction positioning sensor 22 continues to detect the outer edge of the width direction positioning mark 5b of the film 5, and when the mark 5b begins to shift from the sensor 22, the stepping motor 16 moves it to the support base 6. On the other hand, the position is adjusted by moving the casing 32 in the film width direction. That is, for example, when the outer edge of the width direction positioning mark 5b of the film 5 begins to shift to the right in FIG. and adjust the position so that the mark 5b does not deviate from the detection position of the sensor 22. At this time, while the film 5 is being fed, the stepping motor 16 is continuously driven in forward and reverse rotation within a minute range to perform the position adjustment, so that the position adjustment can be performed more smoothly. While the film 5 is being fed, the second width direction positioning sensor 34 continues to detect the outer edge of the width direction positioning mark 5b of the film 5, and when the mark 5b begins to shift from the sensor 34, the stepping motor 39 moves the adapter plate. 31, that is, the position of the second frame 30 is adjusted by swinging it around the fulcrum 43 with respect to the mold 54. That is, for example, when the outer edge of the width direction positioning mark 5b of the film 5 begins to shift to the right side in FIG. The position of the mark 5b is adjusted so that the mark 5b does not deviate from the detection position of the sensor 34 by swinging it to the left. At this time, while the film 5 is being fed, the stepping motor 39 is continuously driven in forward and reverse rotation within a minute range to perform the position adjustment, so that the position adjustment can be performed more smoothly. When the longitudinal feeding operation of the film 5 is completed, the driving of the stepping motors 16 and 39 is stopped. As a result, when the longitudinal positioning of the film 5 is completed, the widthwise positioning is also completed. With the film 5 positioned at a predetermined position relative to the mold 54, the film 5 is held by the member 50.50.
Press it against the parting surface of the mold 54. and,
The movable die plate 14 is connected to four tie bars 21. ...,
The movable mold 54 is moved to the fixed mold side (not shown) according to the guide 21, the fixed mold and the movable mold 54 are closed, molten resin is injected into the cavity between both molds, and the pattern 5 of the film 5 is molded at the same time as the resin molding.
Transfer c. After the mold is cooled, the movable mold 54 is separated from the fixed mold by moving the movable gouly plate 14 and the molded product is taken out, and the transferred film 5 is moved by a predetermined pitch while performing the above-described film positioning operation. The transferred film 5 is transferred to the take-up roller 3
5 is sequentially wound. According to the above embodiment, when the film 5 is fed along the longitudinal direction, the number of pulses of the stepping motor 44 is counted to perform longitudinal positioning operation, and as shown in FIG. In addition to adjusting the movement of the unit in the film width direction, the stepping motor 39 swings the film winding side unit around the fulcrum 43 to adjust the inclination of the film 5, thereby making it possible to perform an operation that does not determine the position in the width direction. Therefore, when the longitudinal positioning operation of the film 5 ends, the widthwise positioning operation also ends at the same time, so the positioning accuracy is high.
The positioning work time can be shortened, and the transfer film can be prevented from becoming wavy and dirty during positioning in the film width direction. In particular, the winding side of the film 5, that is, the transferred portion is tilted because it is thermally deformed by the heat of the molten resin. By swinging, the position of the film 5 can be adjusted so as to absorb such a tilt of the film 5, and the accuracy of position adjustment of the film 5 can be further improved. Note that the present invention is not limited to the above embodiments, but
It can be implemented in various other ways. For example, in the above embodiment, during the film feeding operation, as shown in FIG. 8, the film feeding side unit moves and adjusts in the film width direction, while the film winding side unit swings around the fulcrum 43. Or, conversely, while the film feeding side unit is swung around the fulcrum 15, the film winding side unit may be moved and adjusted in the film width direction. Further, during the film feeding operation, both the film feeding side unit and the film winding side unit may be swung about the supporting points 15 and 43, respectively, with respect to the mold 54. In addition, the first guide rollers 2 and 12 and the second guide roller 3
6 and 37, instead, a brake device is incorporated in the film feed roller 1 as shown in FIGS. 10 and 11, so that the film 5 is held at a constant tension between the film winding roller 35 You may also do so. That is, as shown in FIG. 1θ, a pulley 121 is provided at one end of the rotating shaft 1a of the film feed roller l so as to rotate together with the pulley 121.
is connected to another pulley 123 via a belt 122. This pulley 123 is an electromagnetic brake device +24
It is installed on the rotating shaft of the The brake device 124 uses electromagnetic powder, and can control the braking force by controlling the amount of electricity applied. Further, the film feed roller l has a potentiometer 125 (roll diameter detector) as shown in FIGS. 1+ and 12. The potentiometer 125 is attached to a bracket 126 attached to the casing 32 so that rotational displacement of the lever 127 can be detected. The lever 127 has a roller 150 at its tip, and a spring 152 is provided so that the roller 150 is always in contact with the outer periphery of the film roll 101. Therefore,
Potentiometer 125 can constantly detect the radius of film roll 101. Therefore, the brake device 124 is configured to generate a braking force proportional to the diameter of the film roll 101 based on a signal from the roll diameter detector 125 that detects the diameter of the film roll 101. According to the above configuration, the film 5 is driven by the drive roller 37 and wound onto the take-up roller 35, but the tension of the film 5 at this time is maintained in a constant state by the action of the brake device +24. That is, the brake device 12
4 generates a braking force that gradually decreases as the outer diameter of the film roll 101 decreases, so that a constant tension is always applied to the film 5. As the films 5 are used one after the other and the outer diameter of the film roll I 01 +7) decreases, the decrease in the outer diameter is detected by the potentiometer +25. The braking force of the brake device 124 is controlled to decrease in proportion to the decrease in the outer diameter of the film roll 101. Therefore, the brake device, 124
The braking force divided by the radius of the film roll 201 (
That is, the tension) is always maintained constant. In this way, since a constant tension is always applied to the film 5, the elongation of the film 5 is always constant, and the positioning accuracy of the film 5 can be improved.

[Brief explanation of drawings]

Figures 1 and 2 are front and side views of a film feeding device according to an embodiment of the present invention, Figure 3 is an enlarged front view of the main part of the film feeding side unit of the above device, and Figure 4 is a front view of a film feeding device according to an embodiment of the present invention. , FIG. 5 is a side view of the main part of the film feeding side unit, FIG. 6 is a side view of the main part of the film winding side unit of the above device, and FIG. 7 is a main part of the film winding side unit. FIG. 8 is a conceptual diagram of film position adjustment in the above embodiment, FIG. 9 is a conceptual diagram of conventional film position adjustment, and FIG. 10 is a diagram of a take-up roller according to another embodiment of the present invention. Partial cross-sectional front view showing the brake device, 1st
1.12 is a front view and a side view of essential parts showing a potentiometer in the above other embodiment. !・Feeding roller, 2・Brake roller, 34.
11.12.38・Guide roller, 5 film, 5a・
Longitudinal positioning mark, 5b Width positioning mark, 5c...Picture, 6. Support stand, 7-first frame, 8.
9...Rail, lO...Rack, 133I adapter plate, 14 Movable die plate, 15. Fulcrum,
16 39.44...Stepping motor, +7,
28,40,45.47・Coupling, +8.41
... Screw shaft, 19 ... Rotating shaft, 20 ... Handle,
21... Tie bar, 22... First width direction positioning sensor, 23. 25. 33... Lot, 24 Film longitudinal direction positioning unit, 26 - Pinion, 27... Powder brake, 29. 32 - Casing , 30... Second frame, 34 - Second width direction positioning sensor, 35 Take-up roller, 36 - Press roller, 37... Drive roller,
42 nut, 43 fulcrum, 46/winding motor, 5o/
Holding member, 01 lot, 52 spring, 53/drive plate, 54 movable mold. Patent Applicant: Nissha Printing Co., Ltd. Agent Patent Attorney: 2 people: 1 Figure 2 Figure 3 Figure 6 Figure 7 Figure 8 Figure 9 Figure 10

Claims (7)

[Claims] (1) Longitudinal positioning marks (5a) arranged along the longitudinal direction of the film at predetermined intervals and widthwise positioning marks (5b) continuously formed in the film longitudinal direction at one end of the film width direction. a film feeding device (1) that feeds out the transfer film (5) wound into a roll; a film longitudinal positioning sensor (24) that detects the longitudinal positioning mark (5a); is arranged on the film winding side with respect to the center of the mold (54) and the width direction positioning mark
5b); a winding side film width direction positioning sensor (34) for detecting the film width direction; and,
Film winding device (35) that winds the film (5)
and a second drive device (39) that swings the film winding device (35) around the fulcrum. (2) The feeding device (1) is disposed in the mold (54) so as to be movable in the film width direction, and is positioned on the film feeding side with respect to the center of the mold (54) along the film feeding direction. a feeding side film width direction positioning sensor (22) arranged to detect the width direction positioning mark (5b); and a first drive device (16) for moving the feeding device (1) in the film width direction. The transfer film feeding device according to claim 1, further comprising: a transfer film feeding device according to claim 1; (3) Longitudinal positioning marks (5a) arranged along the film longitudinal direction at predetermined intervals and width direction positioning marks (5b) continuously formed in the film longitudinal direction at one end of the film width direction. At the same time, the transfer film (5) that has been wrapped into a roll is sent out, and the mold (54) is sent out.
) in a plane approximately parallel to the film feeding surface.
5) a film feeding device (1) arranged to be able to swing around the film feeding device (1), a first drive device (16) that swings the film feeding device (1) about the supporting point, and a longitudinal positioning mark ( 5a), and a film longitudinal positioning sensor (24) for detecting the film longitudinal direction positioning sensor (24) for detecting
a feed-out side film width direction positioning sensor (22) that is arranged on the film feed side with respect to the center of the screen and detects the width direction positioning mark (5b);
Film winding device (35) that winds the film (5)
A transfer film feeding device comprising: and. (4) The film winding device (35) is disposed so as to be movable in the film width direction, and is disposed on the film winding side with respect to the center of the mold (54) along the film feeding direction. A winding side film width direction positioning sensor (34) that detects the width direction positioning mark (5b), and a second drive device (39) that moves the film winding device (35) in the film width direction. The transfer film feeding device according to claim 3, wherein the transfer film feeding device is configured as follows. (5) Longitudinal positioning marks (5a) arranged along the film longitudinal direction at predetermined intervals and width direction positioning marks (5b) continuously formed in the film longitudinal direction at one end of the film width direction. At the same time, the transfer film (5) that has been wrapped into a roll is sent out, and the mold (54) is sent out.
) in a plane approximately parallel to the film feeding surface.
5) a film feeding device (1) arranged to be able to swing around the film feeding device (1), a first drive device (16) that swings the film feeding device (1) about the supporting point, and a longitudinal positioning mark ( 5a), and a film longitudinal positioning sensor (24) for detecting the film longitudinal direction positioning sensor (24) for detecting
a feed-out side film width direction positioning sensor (22) that is arranged on the film feed side with respect to the center of the screen and detects the width direction positioning mark (5b);
a winding side film width direction positioning sensor (34) arranged on the film winding side with respect to the center of the mold (54) along the film feeding direction and detecting the width direction positioning mark (5b); is arranged to be swingable about a fulcrum (43) in a plane approximately parallel to the film feeding surface with respect to the mold (54), and
Film winding device (35) that winds the film (5)
and a second drive device (39) that swings the film winding device (35) around the fulcrum. (6) A pair of first guide rollers that are arranged integrally with the film feeding device (1) and guide the film (5) fed out from the film feeding device (1) to the mold side without sandwiching it. The transfer film feeding device according to any one of claims 1 to 5, comprising: (2, 12). (7) A pair of second guides that are arranged integrally with the film winding device (35) and guide the film (5) from the mold side to the film winding side while sandwiching the film (5). Claims 1 to 3 comprising rollers (36, 37).
6. The transfer film feeding device according to any one of 6.