KR101472676B1 - Apparatus and method for winding film - Google Patents

Abstract

The winding device 10 of the film is provided with a winding mechanism 13 for winding up a predetermined amount of the film 11 at a different winding speed and a predetermined amount of the film 11 wound up by the winding mechanism 13, And an accumulation mechanism 30 for accumulating the film 11 delivered from the feeding mechanism 12 and then feeding the film 11 toward the winding mechanism 13. [ The accumulating mechanism 30 changes the accumulation amount of the film 11 in accordance with the change in the winding speed of the film 11 wound by the winding mechanism 13. The accumulating mechanism 30 includes a pair of fixing rollers 31 and 32 provided along the conveying path of the film 11 and a pair of fixing rollers 31 and 32, A movable roller 33 movable in a direction orthogonal to the conveying path of the movable roller 33, and a servo motor 34 moving the movable roller 33. [

Description

[0001] APPARATUS AND METHOD FOR WINDING FILM [0002]

TECHNICAL FIELD [0001] The present invention relates to a winding device and a winding method of a film that can be used in manufacturing a capacitor, a battery, or the like wound around a film for use in various electronic devices, electric devices, industrial devices, automobiles and the like.

In recent years, from the viewpoint of environmental protection, all electric devices are controlled by an inverter circuit, and energy saving and high efficiency are progressing. Among them, in the automobile industry, a hybrid car traveling by an electric motor and an engine is introduced to the market, and development of a technology that is friendly to the global environment, energy saving, and high efficiency is becoming active. Since the electric motor used in such a hybrid car has a high voltage range of several hundreds of volts, a metallized film capacitor having high withstand voltage and low loss electrical characteristics is noteworthy as a capacitor used in connection with such an electric motor . A metallized film capacitor of this kind is formed by winding a strip-shaped metallized film on which a metal deposition electrode is formed on a dielectric film made of resin such that a pair of metal deposition electrodes are wound so as to face each other with a dielectric film therebetween so as to form a capacitor element And forming extraction electrodes made of a metal ion by metal spraying on both end faces of the capacitor element.

BACKGROUND ART [0002] Conventionally, as an apparatus for manufacturing a capacitor element by winding such a film, it is known that a band-shaped metalized film is provided with a winding shaft for winding a bobbin or a reel to be wound (see, for example, Japanese Patent Application Laid-Open No. 2009-94188A Reference). In this apparatus, two winding axes are provided so that two sets of metallized films can be loaded, respectively, and a winding mechanism for overlapping and winding two sets of strip-shaped metallized films fed respectively from the two winding axes And a plurality of conveying rollers provided between the take-up shaft and the winding mechanism for conveying the metalized films, respectively. The plurality of conveying rollers include a guide roller for guiding the conveyance of the metallized film and a dancer roller for controlling the rotational speed of the take-up shaft by positional variation to apply a constant tension to the film. In this conventional film winding apparatus, a strip-shaped metallized film fed from two unwinding shafts whose rotational speeds are controlled is conveyed by a plurality of conveying rollers and wound around a winding mechanism to produce a stable capacitor element It is said that it can do.

However, in recent years, attempts have been made to increase the mounting rate of components by accommodating such capacitors in a predetermined gap of the vehicle, with the cross-sectional shape of the capacitor used as a capacitor used in connection with the electric motor used for the hybrid vehicle. In order to obtain such a capacitor having a non-circular cross section, a film is wound around a winding core having a non-circular cross section. In this case, when the winding core having a non-circular cross section is rotated at a constant speed, The speed of the film is changed. For example, when a winding core in which a film is wound has a rectangular cross-section and a long side of the rectangular cross-section is significantly longer than a short side of the rectangular cross-section, if the winding core rotates at a constant speed, The speed of the film wound on the winding core whose cross section is non-circular is remarkably changed, so that the comparatively fast speed and the remarkably slow speed are alternately repeated.

When the speed of the film to be wound is changed, even at the side from which the film is fed out, the film is fed at a relatively high speed so that the feeding speed of the film is equal to the speed at which the film is wound, It is necessary to alternately repeat the above operations. In this case, the speed at which the film is wound around the winding core substantially depends on the speed at which the film is fed out by varying the film speed.

However, in the case where the film to be fed is wound on a relatively large spool on the side from which the film is fed out, the spool has a relatively large inertia force, and therefore the acceleration and deceleration of the rotation of the spool is rapidly It becomes difficult to do. As a result, it is difficult to rapidly deliver the film, which makes it difficult to increase the winding speed of the film.

An object of the present invention is to provide a film winding device and a film winding method of a film which can wind the film at a relatively high speed even when the film is wound while changing the winding speed of the film.

A film winding apparatus according to the present invention is a film winding apparatus comprising a winding mechanism for winding a predetermined amount of film by changing the winding speed, a feeding mechanism for feeding the predetermined amount of the film wound by the winding mechanism at a predetermined amount, And an accumulation mechanism provided between the feeding mechanisms for feeding the film fed out from the feeding mechanism toward the winding mechanism after accumulating the film, wherein the accumulation mechanism comprises: And to change the accumulation amount of the film in accordance with the change in the winding speed.

The present invention also provides a film winding method for winding a film fed by a certain amount from a feeding mechanism with a winding mechanism changing a winding speed by a winding mechanism, the film being fed from the feeding mechanism is accumulated And then the accumulated amount of the film by the accumulation mechanism is changed in accordance with the change in the winding speed of the film wound by the winding mechanism.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a conceptual diagram showing a winding device of a film according to an embodiment of the present invention. Fig.
2 is a view showing the relationship between the angle of the winding core and the accumulation amount of the film by the accumulation mechanism;
3 is a view showing the relationship between the winding speed of the film and the accumulation amount of the film by the accumulation mechanism;
4 is a cross-sectional view taken along the line BB of Fig. 1 showing the configuration of the conveying roller.
5 is a cross-sectional view taken along line DD of Fig.
6 is a sectional view showing the configuration of the movable roller;
7 is a sectional view taken along line AA of Fig.
Fig. 8 is a sectional view corresponding to Fig. 4 showing the configuration of another conveying roller. Fig.
9 is a sectional view taken along line EE of Fig.
Fig. 10 is a conceptual view corresponding to Fig. 1 showing a winding device of another film of the present invention. Fig.
Fig. 11 is a conceptual view corresponding to Fig. 1 showing another winding device of a film of the present invention. Fig.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

Fig. 1 shows a film winding apparatus 10 according to an embodiment of the present invention. The winding device (10) has a feeding mechanism (12) for feeding a predetermined amount of a strip-shaped metallized film (11) in a predetermined amount. The feeding mechanism 12 in this embodiment includes a winding shaft 12a configured to be capable of loading a film roll 11a in which a metal film 11 is wound in a circular shape on a bobbin or a reel (not shown) And a feeding motor (not shown) for rotating the shaft 12a together with the film roll 11a. In this embodiment, a winding device 10 is shown in which two sets of the strip-shaped metallized films 11 are wound one over the other and wound in a pair. Thus, the winding shaft 12a constituting the feeding mechanism 12 and the feed shaft 12a (not shown) which constitute the feeding mechanism 12 are provided so as to be able to load the two film rolls 11a wound with the two sets of the strip- Respectively, that is, two sets.

A feeding motor (not shown) which rotates the two winding axes 12a respectively rotates the winding shaft 12a at a constant speed together with the circularly wound film roll 11a, So that a predetermined amount of the film 11 is constantly and constantly fed from the circular film roll 11a. As the metallization film 11, for example, one having a width of 80 mm and a thickness of 3 占 퐉, which is formed by forming a metal deposition electrode on one surface of a dielectric film made of polypropylene, is exemplified as a capacitor.

The winding device 10 of the film is provided with a winding mechanism 13 for winding the film 11 fed out from the feeding mechanism 12. This winding mechanism 13 is for winding a predetermined amount of the film 11 at a different winding speed. In this embodiment, the winding core 13a having a noncircular cross section for winding the film 11, And a winding motor (not shown) for rotating the core 13a at a constant speed. A winding motor (not shown) rotates the winding core 13a having a non-circular cross section at a constant speed and winds the film 11 around the winding core 13a rotating at a constant speed, (13) is configured to wind a predetermined amount of the film (11) at a different winding speed.

A plurality of conveying rollers 16 are provided on the conveying path of the film 11 between the winding shaft 12a constituting the feeding mechanism 12 and the winding core 13a constituting the winding mechanism 13. The same number of conveying rollers 16 from the respective unwinding shafts 12a to the winding cores 13a are provided in the winding device 10 of the present embodiment having the two unwinding shafts 12a . A plurality of conveying rollers 16 are fixedly provided on the conveying path of the metallized film 11 to guide the conveyance of the metallized film 11. The conveying rollers 16 convey the film 11, The film 11 is floated by the air blown from the outer periphery to be wound and the film 11 is transported. The plurality of conveying rollers 16 have the same structure and will be described by exemplifying one conveying roller 16 in Fig. 1. As shown in Figs. 4 and 5, The film 11 wound on the outer periphery of the film 11 is wound around the tube 23 so as to be floatable and the film 11 wound on the barrel 23 and wound on the barrel 23 on both sides of the barrel 23, (24, 25) for restricting the movement of the wall.

The conveying roller 16 shown in Figs. 4 and 5 is an example in which the tubular portion 23 and the wall members 24 and 25 are integrally formed by cutting a solid material made of metal or resin, 23 have a cylindrical shape with a through hole 23a formed along the central axis and wall members 24, 25 are provided so as to seal both end portions in the axial direction. 4, the wall members 24, 25 have an outer diameter larger than the outer diameter of the cylindrical portion 23 and are provided at both sides of the cylindrical portion 23 with a space slightly wider than the width of the film 11, (23). A male thread 24a coaxial with the cylindrical portion 23 is formed on the wall member 24 at one end side of the cylindrical portion 23 and the male thread 24a is mounted on the panel 10a of the retractor 10 Through hole 10b is formed. This conveying roller 16 is wound around the winding device 10 by inserting the male screw 24a into the insertion through hole 10b formed in the panel 10a and screwing the nut 26b through the washer 26a. Of the panel 10a.

A communicating hole 24b communicating with the through hole 23a is formed in the wall member 24 at one end side through the central axis and the one end side of the communicating hole 24b is provided with a first A first coupler 28 capable of fixing the air tube 27 is provided. A cover plate 29a for sealing the other end side of the through hole 23a in the tubular portion 23 is provided in the wall member 25 on the other end side of the tubular portion 23, Respectively. A plurality of air holes 23c communicating at one end with the through hole 23a are radially formed in the cylindrical portion 23 between the wall members 24 and 25 so as to open the other end thereof to the outer peripheral surface . The plurality of air holes 23c are formed in a portion where the film 11 is wound. That is, in Fig. 5, since the film 11 is wound so as to bend, a plurality of air holes 23c are formed in the semicircle which is a portion where the film 11 is wound. However, although not shown, in the conveying roller 16 for turning the wound film 11 by approximately 90 degrees, a plurality of air holes 23c (not shown) are formed in a range of about 90 degrees from the center, ) Are formed radially.

In the conveying roller 16 in which the plurality of air holes 23c are radially formed as described above, the first air tube 27 is provided with the first air tube 27 and the first coupler 28 in the through hole 23a The supplied compressed air flows from the plurality of air holes 23c to the outer surface of the cylindrical portion 23 of the conveying roller 16 after passing through the through hole 23a as indicated by the one- And the film 11 wound on the conveying roller 16 by the ejected air is floatable as shown in Fig. The wall members 24 and 25 provided on both sides of the barrel 23 are located on both sides in the width direction of the film 11 that is wound around the barrel 23 and floats and moves in the width direction of the film 11 And is configured to be transportable in a limited condition.

Referring back to Fig. 1, between the conveying roller 16 and the winding core 13a at the downstream end of the conveying path of the film 11, a plurality of Shaped metallized films 11 guided by the conveying rollers 16 of the conveying rollers 16 are provided in pairs so that the pair of pressing rollers 17 and 17 are sandwiched in pairs do. The pair of pressure rollers 17 and 17 are rollers for preventing air from being caught between the films 11 by squeezing the overlapped films 11 and being made of urethane rubber. However, these pressing rollers 17 and 17 are not limited to those made of urethane rubber. Here, in Fig. 1, a capacitor element made of a metallized film 11 wound around a winding core 13a constituting a winding mechanism 13 is indicated by reference numeral 14.

The winding device 10 of the film is provided between the winding mechanism 13 and the feeding mechanism 12 so that the film 11 fed out from the feeding mechanism 12 is accumulated and then fed toward the winding mechanism 13 And an accumulation mechanism (30) for performing an operation. The film winding apparatus 10 according to the present embodiment shows a case in which the accumulation mechanism 30 of the same structure is provided between each winding shaft 12a and the winding core 13a. The accumulation mechanism 30 includes a pair of fixing rollers 31 and 32 provided along the conveying path of the film 11, A movable roller 33 which is movable in a direction perpendicular to the conveying path of the film 11 through the middle of the pair of fixing rollers 31 and 32, And a servomechanism 34 for queuing.

In the present embodiment, the film 11 fed out from the film roll 11a is provided with a portion moving horizontally by the conveying roller 16, and a pair of fixing rollers 31, (11). The pair of fixing rollers 31 and 32 float the film 11 by the air blown from the outer periphery on which the film 11 is wound and turn the film 11 extending in the horizontal direction into the vertical direction . Concretely, the same structure as that of the above-described conveying roller 16 shown in Figs. 4 and 5 is used, and hence repeated description of the detailed structure of the pair of fixing rollers 31 and 32 is omitted. The pair of fixing rollers 31 and 32 having the same structure as the conveying roller 16 are directly mounted on the panel 10a of the winding device 10 (Fig. 4).

4) extending in the vertical direction is provided with a ball screw 36 extending in the vertical direction so as to pass through the centers of the pair of fixing rollers 31 and 32, The rotary shaft of the servo motor 34 for accumulation is connected to the ball screw 36 so that the rotary shaft 36 is rotatable. A movable base 37 is screwed to the ball screw 36 and a movable roller 33 is mounted on the movable base 37. A control signal from a controller (not shown) is output to the servo motor 34 for accumulation.

In the accumulating mechanism 30, means for preventing friction between the film 11 wound on the movable roller 33 and the movable roller 33 is provided. Specifically, the movable roller 33 of the accumulating mechanism 30 is configured to be supplied with compressed air from a compressed air supply pump controlled by a controller (not shown), and the compressed air is supplied to the movable roller 33 from the outer periphery of the movable roller 33. The film 11, That is, the movable roller 33 is configured to eject the compressed air supplied from the compressed air supply pump from the outer periphery thereof and to float the film 11 wound around the outer periphery thereof.

6 and 7 show the structure of the movable roller 33 in this embodiment. The movable roller 33 has substantially the same structure as that of the conveying roller 16 described above and includes a cylindrical portion 33a configured to allow the film 11 wound by the air ejected from the outer periphery to float, And wall members 33b and 33c provided on both sides of the cylindrical portion 33a for restricting the movement of the film 11 in the width direction wound on the cylindrical portion 33a. The movable roller 33 shown in the figure is an example in which the tubular portion 33a and the wall members 33b and 33c are integrally formed by cutting a solid material made of metal or resin, The wall members 33b and 33c are provided in the shape of a cylinder having a through hole 33d formed along the central axis and sealing both end portions in the axial direction.

The wall members 33b and 33c have an outer diameter larger than the outer diameter of the cylindrical portion 33a and are provided on both sides of the cylindrical portion 33a with a space slightly wider than the width of the film 11 so as to be coaxial with the cylindrical portion 33a . The wall member 33b at one end side of the cylindrical portion 33a is provided with a male screw 33e coaxial with the cylindrical portion 33a and the movable screw 37 is provided with a female screw 37a for mounting the male screw 33e. . The movable roller 33 is fixed to the movable table 37 by screwing the male screw 33e to the female screw 37a formed on the movable table 37. [

A communicating hole 33f communicating with the through hole 33d is formed on the wall member 33b at one end side so as to intersect with the central axis and one end side of the communicating hole 33f is provided with a second A second coupler 39 capable of fixing the air tube 38 is provided. A cover plate 33h for sealing the other end side of the through hole 33d in the cylindrical portion 33a is provided in the wall member 33c on the other end side of the cylindrical portion 33a, Respectively. A plurality of air holes 33k communicating one end with the through hole 33d are radially formed in the cylindrical portion 33a between the wall members 33b and 33c so as to open the other end thereof to the outer peripheral surface .

7, the plurality of air holes 33k are formed in a portion where the film 11 is wound, and the compressed air supplied from the compressed air supply pump (not shown) through the second air tube 38 Is configured to be supplied to the inside of the through hole 33d through the second coupler 39 and the communication hole 33f shown in Fig. The air then passes through the through hole 33d as indicated by the one-dot chain line arrow and then flows from the air holes 33k to the outside of the cylinder 33a of the movable roller 33 As shown in FIG. As shown in Fig. 7, the film 11 wound on the movable roller 33 is lifted by the air thus blown so as not to cause friction between the film 11 and the movable roller 33 . The wall members 33b and 33c provided on both sides of the cylindrical portion 33a are located on both sides in the width direction of the film 11 wound on the cylindrical portion 33a and floated, It acts as conveying in a restricted state.

1, the film 11 which is turned by the conveying roller 16 and directed in the horizontal direction extends over the pair of fixing rollers 31 and 32 so that the pair of fixing rollers 31 and 32 The film 11 is wound on the movable roller 33 located below the film 11 from below. The accumulation mechanism 30 thus includes a pair of fixing rollers 31 and 32 provided along the conveying path of the film 11 and a pair of fixing rollers 31 and 32, The film 11 is accumulated by winding the film 11 on the movable roller 33 provided in a direction orthogonal to the conveying path of the film 11.

On the other hand, when the servo motor 34 for accumulation is driven to rotate the ball screw 36 on the basis of a command from a controller (not shown), the movable table 37, which is screwed to the ball screw 36, And moves together in the vertical direction. As a result, when the servo motor 34 for accumulation is driven to lower the movable roller 33, the vertical distance between the pair of fixed rollers 31 and 32 and the movable roller 33 is enlarged, The film 11 having a length twice the vertical distance between the movable rollers 31 and 32 and the movable rollers 33 is accumulated between the pair of fixed rollers 31 and 32. [ Conversely, when the servo motor 34 for accumulation is driven so that the movable roller 33 is lifted, the vertical distance between the pair of fixed rollers 31, 32 and the movable roller 33 is reduced, . The change of the accumulation amount of the film 11 can be prevented by moving the movable roller 33 to the pair of fixing rollers 31 and 32 by the servomotor 34 or by moving the pair of fixing rollers 31 , 32, respectively.

When the film 11 is wound around the outer periphery of the winding core 13a having a noncircular section, even if the winding core 13a rotates at a constant speed, the winding mechanism 13 having the winding core 13a , And a predetermined amount of the film 11 is wound by changing the winding speed. As shown in Fig. 2, for example, when the winding core 13a having a long circular cross section is used, the winding core 13a rotates and the film 11 wound on the winding core 13a in the longitudinal direction C thereof is wound (Fig. 2 (a) and Fig. 2 (g)) is significantly slowed down. On the other hand, in the case where the winding core 13a rotates and its longitudinal direction C becomes substantially perpendicular to the film 11 wound on the winding core 13a (Figs. 2 (c) and 2 (d) Significantly faster. Corresponding to the change in the winding speed of the film 11 wound by the winding mechanism 13, the accumulating mechanism 30 moves the movable roller 33 up and down by a command from an unillustrated controller , And to change the accumulation amount of the film (11).

Concretely, a winding motor (not shown) is controlled by a controller, and the rotational position of the winding core 13a, which is non-circular in cross section, rotated by the motor is configured to be grasped by the controller. In the winding device 10, the amount of winding of the film 11 wound by varying the winding speed by one revolution of the winding core 13a and the amount of winding of the film 11 fed out from the feeding mechanism 12 during one revolution of the winding core 13a The amount of the film 11 becomes equal. When the winding speed of the winding mechanism 13 is slow, the excess film 11 fed out of the feeding mechanism 12 is accumulated by the accumulation mechanism 30, and on the contrary, When the speed is high, the excessive film 11 accumulated by the accumulating mechanism 30 is directed toward the winding mechanism 13. [

The winding device 10 of this film is provided with a tension imparting device 40 for applying tension to the film 11 fed from the feeding mechanism 12 and conveyed to the winding mechanism 13. The tension imparting device 40 includes a pair of guide rollers 41 and 42 provided along the film 11 from the accumulating mechanism 30 toward the winding core 13a and a pair of guide rollers 41 and 42 and has a dancer roller 44 which is separated by the lever 43 from the pair of guide rollers 41 and 42 so as to be movable toward or away from the pair of guide rollers 41 and 42. The dancer roller 44 A spring 46 is provided which urges the guide roller 41 in the direction away from the pair of guide rollers 41, 42. The tension applying device 40 applies a pressing force of the dancer roller 44 applied by the spring 46 to the film 11 fed from the feed mechanism 12 and accumulated by the accumulating mechanism 30. [ So as to apply a predetermined tension to the sheet.

The pair of guide rollers 41 and 42 lifts the film 11 by air blown from the outer periphery around which the film 11 is wound and stretches the film 11 extending in the horizontal direction in the vertical direction As shown in FIG. Concretely, the same structure as that of the above-described conveying roller 16 shown in Figs. 4 and 5 is used, and hence repeated description of the detailed structure of the pair of guide rollers 41 and 42 is omitted. A pair of guide rollers 41 and 42 having the same structure as the conveying roller 16 are directly mounted on the panel 10a of the winding device 10 (Fig. 4).

In the dancer roller 44, the film 11 is floated by the air ejected from the outer periphery on which the film 11 is wound, so that the film 11 is turned into a U-shape. Specifically, since the movable roller 33 having the same structure as that of the movable roller 33 shown in Figs. 6 and 7 is used, repeated description of the detailed structure of the dancer roller 44 is omitted.

The other end of the lever 43 at which the dancer roller 44 is pivotally supported at one end, that is, the pivot fulcrum 43a of the panel 10a (FIG. 4) of the lever 43, A position detection angle sensor 47 for detecting the position of the dancer roller 44 from the swing angle of the rotation sensor 43 is provided and the detection signal of the angle sensor 47 is outputted to a controller not shown. Since the film roll 11a in the feeding mechanism 12 feeds the film 11 by its rotation, when the film 11 is fed out, the outer diameter of the film roll 11a gradually decreases, When the velocities are the same, the amount of the film 11 fed out in a unit time gradually decreases. The dancer roller 44 that applies the tension to the film 11 is moved close to the pair of guide rollers 41 and 42 against the urging force of the spring 46 do. The movement of the dancer roller 44 is detected by the position detection angle sensor 47. Based on the detection signal, a controller (not shown) controls a feed motor (not shown) The rotation speed of the film roll 11a is changed in accordance with the change so that the amount of the film 11 fed out in a unit time is always made constant.

Next, a winding method of the film using the winding device 10 of the film configured as described above will be described.

The film winding method according to the present embodiment is such that the film 11 fed by a certain amount from the feeding mechanism 12 is wound by the winding mechanism 13 with the winding speed varied. 1, a predetermined amount of the film 11 is fed by the feed mechanism 12 by feeding the film roll 11a wound on the bobbin or reel in the form of a roll to the feed shaft 12a, And the film roll 11a is rotated together with the feeding shaft 12a at a constant speed based on a command from a controller (not shown) of a feeding motor (not shown). As the unwinding shaft 12a rotates, the strip-shaped metallized film 11 is fed out from the bobbin or the reel and conveyed to the winding core 13a which is the winding mechanism 13 via the conveying roller 16. [

The metallized films 11 and 11 respectively fed from the two unwinding shafts 12a are superimposed on the pair of pressure rollers 17 and 17 and are wound on the film 11 Is carried out by winding the film 11 on a winding core 13a having a non-circular cross section. That is, two metallized films 11, 11 in the overlapped state are wound around the winding core 13a of the winding mechanism 13 as a pair. The winding core 13a is wound by rotating the respective metalized films 11 and 11 so that the pair of metal deposition electrodes face each other with the dielectric film 11 interposed therebetween.

In the winding method of the film according to the present embodiment, the winding amount of the film 11 wound by varying the winding speed by one revolution of the winding core 13a having a noncircular section in the winding mechanism 13, The amount of the film 11 fed out from the feeding mechanism 12 during one rotation of the winding core 13a becomes equal. The film 11 delivered from the feeding mechanism 12 is accumulated by the accumulating mechanism 30 and then fed toward the winding mechanism 13. The film 11 wound by the winding mechanism 13 is wound around the film 11, The accumulation amount of the film 11 by the accumulating mechanism 30 is changed corresponding to the change in the winding speed of the film 11. 3, the accumulation amount of the film 11 in the accumulating mechanism 30 is changed in a phase opposite to the winding speed change of the film 11 wound by the winding mechanism 13 . More specifically, when the winding speed of the winding mechanism 13 is slow, the excess film 11 fed out of the feeding mechanism 12 is accumulated by the accumulating mechanism 30, and conversely, (11) accumulated by the accumulating mechanism (30) toward the winding mechanism (13) when the winding speed of the accumulating mechanism (30) is high.

2, the accumulation of the film 11 in the accumulating mechanism 30 is carried out from a pair of fixing rollers 31 and 32 provided along the conveying path of the film 11 to the film 11 By winding the film 11 on a movable roller 33 provided in a direction orthogonal to the conveying path of the recording medium. That is, the film 11 turned by the conveying roller 16 and directed in the horizontal direction is stretched over the pair of fixing rollers 31 and 32, and the film 11 between the pair of fixing rollers 31 and 32 Is wound on the movable roller 33, which is located below the movable roller 33, from below. In this way, the film 11 having a length twice as much as the vertical distance between the pair of fixing rollers 31, 32 and the movable rollers 33 is accumulated in the accumulating mechanism 30. [

On the other hand, in order to change the accumulation amount of the film 11 accumulated in the accumulating mechanism 30, the film 11 in the middle of the pair of fixing rollers 31 and 32 is wound and the film 11 The movable roller 33 is moved up and down by the servomotor 34 so that the movable roller 33 is moved toward or away from the pair of fixed rollers 31 and 32, And is spaced from the pair of fixing rollers 31 and 32. For example, when the movable roller 33 is lowered, the vertical distance between the pair of fixing rollers 31 and 32 and the movable roller 33 is enlarged and the pair of fixing rollers 31 and 32 and the movable roller 33 The film 11 having a length twice the vertical distance of the film 11 is accumulated between the pair of fixing rollers 31 and 32. Conversely, when the movable roller 33 is lifted, the vertical distance between the pair of fixing rollers 31, 32 and the movable roller 33 is reduced, and the accumulation amount of the film 11 is reduced.

Fig. 2 shows a change in the accumulation amount of the film 11 in the accumulation mechanism 30 when the winding core 13a having a long circular section has a half revolution. 2 (a), the longitudinal direction C of the winding core 13a is parallel to the film 11 wound on the winding core 13a, and the film 11 The winding speed is remarkably slow. In this case, the accumulation mechanism 30 accumulates the surplus film 11 to be fed out from the feeding mechanism 12.

The accumulation of the film 11 in the accumulating mechanism 30 is carried out by a pair of fixing rollers 31 and 32 provided along the conveying path of the film 11 and a pair of fixing rollers 31 and 32 The movable rollers 33 capable of moving in the direction orthogonal to the conveying path of the film 11 are wound on the film 11 in the middle of the film 11 as shown by the solid arrows in Figure 2 32 from the fixing rollers 31, 32, respectively. The vertical distance between the pair of fixing rollers 31 and 32 and the movable roller 33 is enlarged to be twice the vertical distance between the pair of fixing rollers 31 and 32 and the movable roller 33, A surplus film 11 to be fed out from the feeding mechanism 12 is accumulated between the pair of fixing rollers 31 and 32.

The amount of the film 11 wound on the winding core 13a increases in the state of Figure 2B where the winding core 13a rotates therefrom and the amount of the film 11 wound on the winding core 13a increases, And the lowering of the movable roller 33 is stopped in a state in which the amount of the film 11 wound up by the winding core 13a is the same. 2 (c), the winding speed of the film 11 wound on the winding core 13a is increased and the winding core 13a is wound on the winding core 13a The amount of the film 11 exceeds the amount of the film 11 fed out by the feeding mechanism 12. As a result, in the accumulating mechanism 30, the movable roller 33 is lifted and the pair of fixing rollers 31 and 32 is lifted up, as indicated by solid arrows in FIGS. 2C and 2D, Lt; / RTI > The vertical distance between the pair of fixing rollers 31 and 32 and the movable roller 33 is reduced and the film 11 accumulated between the pair of fixing rollers 31 and 32 is led out to the winding core 13a, Respectively.

The amount of the film 11 wound on the winding core 13a gradually decreases in the state of Fig. 2E as the winding core 13a further rotates, and the amount of the film 11 wound on the winding core 13a gradually decreases, The rising of the movable roller 33 is stopped and the amount of the film 11 fed out from the feeding mechanism 12 (Fig. 1) is increased in the state in which the amount of the film 11 wound by the winding core 13a is the same The feeding of the film 11 exceeding the amount from the accumulation mechanism 30 is stopped. 2 (f) and 2 (g), the amount of the film 11 wound on the winding core 13a is remarkably reduced, As shown by a solid line arrow, from the pair of fixing rollers 31 and 32 so as to accumulate an excess film 11 that is not wound on the winding core 13a even if it is fed out from the feeding mechanism 12. [ And accumulates in the mechanism (30). By repeating the operations shown in Figs. 2A to 2G, a predetermined amount of the film 11 fed out of the feeding mechanism 12 by a predetermined amount is changed by the winding mechanism 13 by the winding mechanism 13 It becomes possible to take up winding.

That is, since the accumulation amount of the film 11 by the accumulating mechanism 30 is changed corresponding to the change in the winding speed of the film 11 wound by the winding mechanism 13, the winding speed of the winding mechanism 13 is slow The accumulating mechanism 30 accumulates the surplus film 11 fed out from the feeding mechanism 12 and conversely when the winding speed of the winding mechanism 13 is high, The accumulated film 11 is fed toward the winding mechanism 13 so that the film 11 is fed by the winding mechanism 13 even though the film 11 is fed from the feeding mechanism 12 by a predetermined amount The winding speed can be changed and the winding can be performed. Then, it is not necessary to change the rotation speed of the relatively large film roll 11a formed by winding the film 11. As a result, even if the film roll 11a has a relatively large inertial force, the film 11 can be wound quickly as long as a certain amount of the film 11 can be fed. Therefore, according to the present embodiment, even when the film 11 is wound while changing the winding speed of the film 11, the film 11 can be wound at a relatively high speed.

In the present embodiment, the movable rollers 33 are separated from or approach the pair of fixing rollers 31 and 32 of the accumulating mechanism 30 to accumulate and discharge the film 11 The weight of the movable roller 33 is light compared to the winding core 13a in the film roll 11a and the winding mechanism 13 in the feeding mechanism 12 and the inertial force exerted thereon is Is small compared with the case of rapidly accelerating or decelerating the rotation of the film rolls 11a and 11a. In addition, even in the case of the actually fed film 11, since the inertia force generated in the film 11 is small, the movable rollers 33 can be relatively moved at high speed. Therefore, the accumulation and feeding of the film 11 in the accumulation mechanism 30 can be performed quickly.

Further, in the feeding mechanism 12, since the film 11 is always fed from the film roll 11a by a constant amount, in the present embodiment, unless the rotation of the film rolls 11a and 11a is rapidly accelerated, none. Therefore, in a feeding motor (not shown) for rotating the film rolls 11a and 11a, a motor having an output enough to rotate the film roll 11a at a constant speed is sufficient. Therefore, a motor having a large output is not required, as is the case conventionally, in which the rotation of the film rolls 11a, 11a is accelerated and decelerated. As a result, the size of the winding device 10 can be prevented from being increased, and a relatively inexpensive winding device 10 can be obtained.

The accumulation mechanism 30 accumulates the surplus film 11 fed out from the feeding mechanism 12 when the winding speed of the winding mechanism 13 is low and conversely, Since the surplus film 11 accumulated when the speed is high is directed toward the winding mechanism 13, the tension of the film 11 wound on the winding core 13a is not affected. Even if an error occurs between these quantities, the error can be absorbed by the pressing force of the springs 46 or by moving against the pressing force of the dancer rollers 44 in the tension applying device 40 do. Therefore, in the present embodiment, a predetermined amount of the film 11 can be rapidly wound at a predetermined time without affecting the tension of the film 11. [

On the other hand, when the metallization film 11 is wound around the winding core 13a to manufacture the capacitor element 14, its outer diameter gradually increases, and the amount of the film 11 to be wound increases. Since the film roll 11a in the feeding mechanism 12 is to feed the film 11 by its rotation, the outer diameter of the film 11 is gradually reduced when the film 11 is fed out, The amount of the film 11 fed out in a unit time gradually decreases. The total length of the film 11 between the feeding mechanism 12 and the winding mechanism 13 is set to be smaller than the total length of the film 11 when the amount of the film 11 to be fed is decreased while the amount of the film 11 to be wound is increased The dancer roller 44 of the tension imparting device 40 that gradually reduces the tension of the film 11 moves to the upper side of Fig. 1 and approaches the pair of guide rollers 41 and 42. [ Then, the movement of the dancer roller 44 is detected by the position detecting angle sensor 47. Based on the detection result, a controller (not shown) controls a feeding motor (not shown) The rotational speed of the film roll 11a is changed in accordance with the change of the outer diameter so that the amount of the film 11 fed out per unit time is always made constant. Whereby the amount of film 11 to be fed and the amount of the film 11 to be wound are always kept constant regardless of the change in the outer diameter of the capacitor element 14 made of the film roll 11a and the film 11 wound on the winding core It can be done in a certain amount.

The conveying roller 16 and the rollers 31 to 33 in the accumulating mechanism 30 and the tension applying device (not shown) in the conveying path between the unwinding shaft 12a and the winding core 13a In the guide rollers 41 and 42 and the dancer roller 44 in the film forming apparatus 40, the film 11 is floated by the air ejected from the outer periphery on which the strip- Is conveyed from the feeding mechanism (12) to the winding mechanism (13), the conveying resistance of the film (11) can be remarkably lowered.

According to the embodiment described above, the following effects are exhibited.

In the film winding device and the film winding method according to the present embodiment, the accumulation amount of the film 11 by the accumulation mechanism 30 is changed in accordance with the change in the winding speed of the film wound by the winding mechanism 13 The surplus film 11 fed out from the feeding mechanism 12 is accumulated in the accumulation mechanism 30 when the winding speed of the winding mechanism 13 is slow and the winding speed of the winding mechanism 13 Even if the amount of the film 11 fed out of the feeding mechanism 12 is constant and a constant amount by feeding the excess film 11 accumulated by the accumulating mechanism 30 toward the winding mechanism 13 when the film 11 is fast, The film 11 can be wound by the winding mechanism 13 while changing the winding speed. Then, even in the winding mechanism 12 in which the winding speed of the winding mechanism 13 is changed by using a relatively large spool in which the film 11 is wound, the rotational speed of the spool is remarkably changed It does not need to be done. As a result, even if the spool has a relatively large inertia force, the film 11 can be quickly wound by the winding mechanism 13 as long as a certain amount of the film 11 can be fed. Therefore, according to the present embodiment, even when the film 11 is wound while changing the winding speed of the film 11, the winding speed of the film 11 by the winding mechanism 13 can be increased . In this embodiment, the production efficiency of the capacitor element 14 with stable performance can be remarkably improved as compared with the conventional one.

The conveying roller 16 for lifting the film 11 to transport the film 11 from the feeding mechanism 12 to the winding mechanism 13 and the feeding roller 16 for feeding the film 11 to the accumulating mechanism 30 The guide rollers 41 and 42 and the dancer roller 44 in the rollers 31 to 33 and the tension imparting device 40 in the first embodiment have a plurality of air The conveying rollers 16, 31 to 33, 41, 42, and 44, in which the holes 23c and 33k are formed in the cylindrical portions 23 and 33a, are illustrated. However, it is not necessary to form the air holes 23c and 33k in the cylindrical portions 23 and 33a as long as the film 11 wound by the air ejected from the outer periphery can be lifted.

8 and 9, the cylindrical portion 23 is formed from a porous material through which air can pass from the through hole 23a to the outer peripheral surface thereof, The wall members 24 and 25 may be bonded to both sides of the cylindrical portion 23. [ In this case, the wall members 24 and 25 are formed by metal or resin that can not pass air, and the outer peripheral portion of the tubular portion 23 where the film 11 is not wound is sealed by the shield member 50 I think. Even in such a conveying roller 16, the compressed air supplied to the through-hole 23a is discharged from the through-hole 23a to the cylinder portion 23 which is not sealed by the shielding member 50, The film 11 is blown out from the outer periphery of the film 11 as indicated by an arrow and the film 11 wound on the tube portion 23 can be floated. The wall members 24 and 25 can limit the movement of the film 11 in the width direction by being wound around the cylindrical portion 23 and floating.

In the above-described embodiment, in the rollers 31 to 33 and the tension imparting device 40 of the conveying roller 16, the accumulating mechanism 30, and the pressurizing roller 17, The film 11 is transported from the feeding mechanism 12 to the winding mechanism 13 by the guide rollers 41 and 42 and the dancer roller 44 , And as the pressure roller 17, a roller for lifting the film 11 may be used. The guide rollers 41 and 42 and the dancer roller 44 in the conveying roller 16 and the rollers 31 to 33 and the tension applying device 40 in the accumulating mechanism 30 Any one or more of them may be transported by rotating the film 11 in contact with the outer periphery thereof so long as the film 11 is not deviated from the transport path.

In the above-described embodiment, an example in which a metal film 11 having a width of 80 mm and a thickness of 3 m, which is formed by forming a metal deposition electrode on one surface of a dielectric film 11 made of polypropylene, was used . However, the present embodiment is not limited to this. The metal film 11 and the separator film 11, each having the metal evaporation electrode formed on both surfaces of the dielectric film 11, Alternatively, it is possible to use a metallized film 11 having a different width or thickness, and a similar effect can be obtained even in a strip-shaped film 11 having no metal evaporation electrode.

In the above-described embodiment, the winding core 13a having a circular cross section is used as the winding core 13a in the winding mechanism 13. However, the winding core may have a long circular cross section But may have other shapes as well. For example, the winding core may have an elliptical cross section or other polygons as long as the film 11 can be wound by changing the winding speed.

Although the accumulation mechanism 30 is provided between the two take-up shafts 12a and the tension imparting devices 40 in the above-described embodiment, the take-up mechanism 13 and the feed mechanism The accumulation mechanism 30 is provided between the two tension applying devices 40 and the pair of pressure rollers 17 and 17 as shown in Fig. A single accumulation mechanism 30 may be provided between the pair of pressure rollers 17 and 17 and the winding mechanism 13 as shown in Fig.

As long as the accumulation mechanism 30 is provided between the winding mechanism 13 and the feeding mechanism 12 even if the position at which the accumulation mechanism 30 is installed is changed, The surplus film 11 fed out from the feeding mechanism 12 is accumulated by the accumulation mechanism 30 when the winding speed is slow and the accumulation time is increased when the winding speed of the winding mechanism 13 is high. Even if the amount of the film 11 fed out of the feeding mechanism 12 is constant and a constant amount by feeding the excess film 11 accumulated by the mechanism 30 toward the winding mechanism 13, Can be wound by the winding mechanism (13) while changing the winding speed. As shown in Fig. 11, when the accumulating mechanism 30 is provided between the pair of pressure rollers 17 and 17 and the winding mechanism 13, the accumulating mechanism 30 is single, It can also be avoided.

Although the embodiments of the present invention have been described above, the above embodiments are only a part of the application examples of the present invention, and the technical scope of the present invention is not limited to the specific configurations of the above embodiments.

Claims (6)

A winding mechanism 13 for winding a predetermined amount of the film 11 by changing the winding speed,
A feeding mechanism (12) for feeding the predetermined amount of the film (11) wound up by the winding mechanism (13)
An accumulation mechanism provided between the winding mechanism 13 and the feeding mechanism 12 for feeding the film 11 fed out from the feeding mechanism 12 toward the winding mechanism 13 after accumulating the film 11 30,
The winding mechanism 13 is configured to wind the film 11 by winding the film 11 on a winding core 13a having a non-circular cross section,
The accumulating mechanism (30) is configured to change the accumulation amount of the film (11) in response to a change in the winding speed of the film (11) wound by the winding mechanism (13). 2. The apparatus according to claim 1, wherein the accumulation mechanism (30)
A pair of fixing rollers 31 and 32 provided along the conveying path of the film 11,
A movable roller 33 which is movable in the direction orthogonal to the conveying path of the film 11 through the middle of the pair of fixing rollers 31 and 32,
And a servo motor (34) for moving the movable roller (33). The film feeding device according to claim 1 or 2, wherein the feeding mechanism (12) is configured to feed a predetermined amount of the film (11) by rotating the film roll (11a) , The winding device of the film. In the winding method of the film in which the winding speed by the winding mechanism 13 is changed by winding the film 11 fed out from the feeding mechanism 12 by a predetermined amount on the winding core 13a having a non-
The film 12 fed out from the feeding mechanism 12 is accumulated by the accumulating mechanism 30 and then fed toward the winding mechanism 13,
Wherein the accumulation amount of the film (11) by the accumulation mechanism (30) is changed corresponding to a change in the winding speed of the film (11) wound by the winding mechanism (13). The film according to claim 4, wherein the accumulation of the film (11) in the accumulating mechanism (30) is performed by a pair of fixing rollers (31, 32) provided along the conveying path of the film (11) Is carried out by winding the film (11) on a movable roller (33) provided in a direction orthogonal to the conveying path of the film (11) from the pair of fixing rollers (31, 32)
The change of the accumulation amount of the film 11 is controlled by the servomotor 34 so that the movable roller 33 approaches the pair of fixing rollers 31 and 32 or the pair of fixing rollers 31 , 32). ≪ / RTI > The film feeding apparatus according to claim 4 or 5, wherein a predetermined amount of the film (11) is fed by the feeding mechanism (12) by rotating the film roll (11a) A method of winding a film.

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