JPH03186830A - Film take-up device for camera - Google Patents

Abstract

PURPOSE:To efficiently and surely wind a film to the outside circumference part of a spool by forming a press part, which presses the film to the outside circumference part of the spool, on one part of the outside circumference part of a press roller and simultaneously providing a regulation means which regulates that the press roller is moved to the spool side. CONSTITUTION:The press part 30a which presses the film 2 to the outside circumference part of the spool is formed to one part of a film width direction at the outside circumference part of the press roller 30 which is spliced so as to make the film 2 press-contact with the outside circumference part of the take-up spool 3. Besides, the regulation means 30b, which regulates that the roller 30 is moved to the spool 3 side so as to oppose the press part 30a to the outside circumference part of the spool with a prescribed gap when the leading edge of the film is fed between the spool 3 and the roller 30, is provided. Therefore, since the prescribed gap is previously provided between the spool 3 and the roller 30, the leading edge of the film can be properly and surely made to enter the gap between the spool 3 and the roller 30 by comparatively weak press-out force. Thus, the film 2 is surely wound to the outside circumference part of the spool.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides a method for transporting the leading edge of the film between a take-up spool and a presser roller attached to the outer periphery of the spool. The present invention relates to a film winding device for a camera that allows winding around the outer periphery of a take-up spool.

[Conventional technology]

For example, U.S. Pat. No. 4,832,275 and U.S. Pat. No. 4,834,308 disclose that a cylinder is equipped with a spool shaft for storing photographic film wound in a roll. A film cartridge structure is disclosed that includes a shaped part and a film feeding part that extends integrally in the tangential direction of the shaped part and stores the leading end of the film in a straight line. In these Pa) Rone films, when the Hatrone is not being loaded into a camera that is handled as a single unit, the leading edge of the film is housed in the feeding section so that it is not exposed to the outside, and when loaded into the camera. Sometimes, the cartridge spool is opened and moved by the drive system on the camera side, so that the leading edge of the film is sequentially delivered from the cartridge delivery port.

According to such a cartridge structure, when loading the film into the camera or winding the film to take it out after shooting, the leading edge of the film is retracted into the cartridge. The film can be fed out visually by rotating the spool with an electric motor, etc., making it extremely easy to load film into the camera, and also to easily handle the film in the operating groove. It becomes easier.

By the way, as a film feeding device for a camera loaded with a cartridge having such a structure, for example, one having a structure as shown in FIG. 1O is conceivable (not publicly known). To explain this simply, the reference numeral l in the figure is a film cartridge in which the film 2 is wound and stored in a cartridge spool la, and the cartridge 1 has a spool 1a that feeds the film as indicated by the solid line arrow a in the figure. By being rotationally driven in the direction, the film 2 is sent out sequentially from the feedout eye ib, and by being rotationally driven in the film rewinding direction indicated by the broken line arrow in the figure, the film 2 is wound onto the spool 1a and the leading edge is It is configured to be included in the Patrone, including the following. In addition, 2 in the figure
Perforations a are formed at a constant pitch along the upper edge of the film 2 in the width direction.

3 is inside the camera body (not shown), with cartridge L and the left side,
A film take-up spool is provided oppositely to the right, and a claw portion 3a that engages with the perforation 2a is provided on the outer periphery of the spool near the upper end, and a claw portion 3a that engages with the perforation 2a protrudes along the circumferential direction. is integrally provided with a winding spool drive gear 4 which receives rotational transmission in the frame feeding direction shown by the solid line arrow C in the figure during film winding.
The film is fed through a well-known film path called a tunnel, which is made up of inner and outer rails (not shown) and a film pressure plate, and along the way it passes through an aperture part that defines the photographic screen in the frame-by-frame direction. It is configured such that it is run and wound sequentially around the outer circumference of the spool 3.

Reference numeral 10 denotes a rotary drive from an electric motor 11 disposed within the take-up spool 3, etc., to drive the spool la of the cartridge 1 and the take-up spool 3 described above for film feeding, frame feeding, or rewinding. A film feeding device for transmitting force, reduction gears 15; 16 transmitting rotation from a pinion 12 on the morph shaft to a sun gear 14 forming a planetary gear mechanism 13 that switches the direction of rotation transmission.
It has a transmission gear train 17 consisting of a and 16b.

The sun gear 14 is rotatably supported around a fixed sun shaft 14a, and is provided with a friction spring (a friction spring) that provides a frictional behavior between the sun gear 14 and a lever arm 18 that is coaxially supported.
(not shown) is interposed, and this lever arm 18 is connected to the sun gear 1.
It is configured to swing in the direction of rotation shown in FIG. 1
Reference numeral 9 denotes a planetary gear that is pivotally supported at the tip of the lever arm 18 in a state in which it meshes with the sun gear 14.
When the motor 1 side rotates in the direction of arrow d in the figure, the sun gear 14 rotates in the direction of arrow f in the figure, causing the lever arm 18 to rotate.
As shown in the figure, the rotation transmission system 20 to the take-up spool 3 side and the delivery rotation transmission system to the spool 1a side of the cartridge l It is configured to simultaneously mesh with the transmission gears 20a and 21a at 21. Note that one transmission gear 20a
meshes with the drive gear 4 of the spool 3-hi via the gears 20b and 20c, and transmits rotation to the take-up spool 3. Further, the other transmission gear 21a meshes with the gear 22 and is connected to the gear 24 via the one-way clutch 23,
The rotation of this gear 24 is transmitted via a gear 25 to a film driving gear 26 connected to the patronage spool 1a. This film drive gear 2
6, a fork portion (not shown) at the lower end of the shaft portion 26a engages with a key (not shown) on the spool 1a side to transmit rotation.

On the other hand, when the sun gear 14 rotates in the direction of the broken line arrow g in the figure due to the rotation of the motor 11 in the direction of the broken line arrow e in the figure, the idler gear 19 rotates in the direction of the broken line arrow g in the figure as the lever arm 18 swings. It moves clockwise (in the direction of the dashed arrow in the figure) and meshes with a transmission gear 27 that transmits rotation in the film rewinding direction to the cartridge 1 side. This transmission gear 2
7, the gear 24 on the lower side of the one-way clutch 23,
The signal is transmitted via gear 25 to film drive gear 26 .

Here, as shown in FIG.
It is a cam roller type clutch consisting of 3a, =+o23b, and an outer cylinder 23c, and the cam 23a is integrated with the lower side 4124, and the outer cylinder 23c is integrated with the gear 22 on the 1- side. When the lower gear 24 is about to rotate counterclockwise relative to the upper gear 22, the two are separated, and the lower gear 24 is rotated relative to the upper gear 22. When attempting to rotate in the clockwise direction, both are integrally connected and configured to rotate together.

Reference numeral 30 denotes a presser roller that is attached to press the film 2 against the outer periphery of the take-up spool 3 and constitutes a film winding device.
A coil spring 33 is wound around a support shaft 32 which is rotatably supported between the upper and lower parts of the support bracket 31 and which rotatably supports the support bracket 31. A biasing force is applied to push it toward.

According to the film feeding device having such a configuration, first, by loading the cartridge l into the camera, the spool la and the film drive gear 26 are connected. When the motor 11 is rotated in the direction of arrow d in the figure by closing the camera back (not shown) or pressing the release button halfway, the sun gear 14 rotates in the direction of arrow f, causing the lever arm 18 to rotate. The planetary gear 19 meshes with both transmission gears 20a and 21a via the transmission gears 20a and 21a. Then, the rotation of the gear 20a rotates the take-up spool 3 in the direction of the arrow C in the figure, and the rotation of the gear 21a rotates the gear 22 in the direction of the arrow, the one-way clutch 23 is connected, and the gears 24, 25 The drive gear 26 is rotated in the direction of arrow a through the film 2.
is operated so as to sequentially send out from patrone l.

The film 2 fed out in this manner passes through a film passage having an aperture (not shown), and its leading end 2b reaches the joint between the take-up spool 3 and the presser roller 30, and enters the gap between them. The outer circumferential portion of the spool 3 is sequentially pierced with the claw portion 3a and the perforation 2a engaged with each other.

By the way, when this film is fed out, the motor
Take-up spool 3 and spool 1 on the cartridge L side
Both a and a are rotationally driven in the same direction, but in this case, the winding speed of the film 2 on the take-up spool 3 side is faster than the speed of feeding the film 2 from the cartridge 1 side. The gear ratios in both rotation transmission systems are set as follows. When the film 2 is hooked onto the hook 3a of the perforation 2a on the spool 3 side and is wound onto the spool 3 side, the cartridge 1 The spool 1a is rotated faster than the rotation transmitted from the motor 11. In such a state, the drive gear 26 and gears 25 and 24 are rotated at the same time faster than the rotation from the motor 11 side, so the gear 24 is rotated counterclockwise relative to the gear 22. As a result, the one-way clutch 23 is in a disengaged state, and the gears 22 and 24 rotate at different speeds. Then, an encoder (not shown) that detects the amount of film feeding generates a signal corresponding to a predetermined amount of film movement, and at that point the motor 11 is stopped, thereby completing the initial winding. Thereafter, each time the film 2 is exposed during a photographing operation, the motor ti is rotated again in the film feeding direction (direction of arrow d in the figure), and the film 2 is fed one frame at a time. The motor 11 is repeatedly stopped by a signal from an encoder that detects the amount of movement.

Further, when all the frames have been photographed, the motor 11 is rotated in the direction of the broken line arrow e in FIG. 10, contrary to what was described above.
As a result, the planetary gear 19 swings and the other transmission gear 27
The rotation of the drive gear 26 through the gears 24 and 25 causes the drive gear 26 to rotate in the direction indicated by the arrow, resulting in the filtrate 2 being rewound laterally into the cartridge 1. In addition,
During this rewinding, the gears 22 and 24 are connected by the one-way clutch 23, and the gears 22 and 21a are rotated idly, but there is no problem in operation -L. On the other hand, the take-up spool 3 also rotates idly as the film 2 is rewound into the Hatron I. When all the films 2 are rewound, the encoder no longer outputs a signal, and the motor 11 is stopped by the detection signal generated by the encoder.

[Problem to be solved by the invention]

By the way, - in the film feeding device 10 mentioned above,
The film tip that is fed from the cartridge L side during initial winding! FIG. 12 schematically shows the state in which the take-up spool 3 is inserted between the take-up spool 3 and the press roller 301 which is tangentially connected to the take-up spool 3 by a spring 33. In this state, as the spool la is rotated on the cartridge 1 side, the film 2 is pushed by a force S from the cartridge 1 side, and the film 2 is pushed by the force S from the cartridge 1 side.
faces the wedge-shaped space between the take-up spool 3 and the presser roller 30, and while moving the presser roller 30 in a direction away from the outer circumference of the spool 3 against the biasing force W of the spring 33, Accordingly, it attempts to operate so as to enter between the outer circumferential portion of the spool 3 and the outer circumferential portion of the roller 30. However, at this time, the film tip 2
Due to the magnitude relationship of the force S pressing b and the biasing force W of the spring 33 biasing the roller 30, the leading edge 2b of the film cannot enter between the spool 3 and the roller 30, and the film 2 buckles. There was a risk that the tape would be bent and deformed in a wave-like manner, making it impossible to wind it up correctly around the outer circumference of the spool 3.

In order to solve this problem, the leading end 2b of the film 2 is formed into a tapered shape 2 in the thickness direction, and due to the wedge effect, the leading end 2b of the film 2 can be moved between the spool 3 and the roller 30 with a smaller force S. However, it is practically difficult to perform such processing on a thin film 2, and a more cylindrical structure would prevent the above-mentioned deformation due to buckling of the film 2. It is desirable to take some kind of measure to prevent this and to ensure that the leading end 2b of the film enters between the spool 3 and the roller 30 smoothly and reliably.

Further, the problem that occurs when feeding the film leading end 2b between the take-up spool 3 and the presser roller 30 that is pressed against it is that the 35 mm
A similar phenomenon occurs in a camera using a 135-inch cartridge containing roll film, for example, in a type of winding device that uses a sprocket to feed the film between a winding spool and a presser roller. It is necessary to resolve the problems.

[Means to solve the problem]

In order to meet such demands, the film winding device for a camera according to the present invention includes a film winding device for a camera in which at least a portion of the film in the width direction is attached to the outer peripheral portion of the presser roller attached so as to press the film against the outer peripheral portion of the take-up spool. A holding part is formed to press the film against the spool outer periphery, and the holding part is opposed to the spool outer periphery with a predetermined gap when the leading edge of the film is fed between the spool and the roller. , a regulating means for regulating the movement of this roller toward the spool side is provided.

[Effect]

According to the present invention, when feeding the leading edge of the film between the take-up spool and the presser roller, a predetermined gap is provided between the two members in consideration of the thickness of the film, the shape of the leading edge of the film, etc. The tip can be properly and reliably inserted between the spool and the roller by a relatively weak extrusion force, and the henofilm can be reliably wound around the spool outer circumference.

4 [Example] Hereinafter, the present invention will be described in detail using an example shown in the drawings.

Figures 1 and 2 show an embodiment of the film winding device for a camera according to the present invention, and in these figures, the same or corresponding parts as in Figures 10 and 12 described above are given the same numbers. A detailed explanation will be omitted.

Now, according to the present invention, in a film winding device comprising a take-up spool 3 for winding the film 2 and a presser roller 30 attached to this spool 3 and press-contacting the film 2 to the outer circumference of the spool 3, these spools 3. Roller 30
By feeding the film leading end 2b between them, the film 2 can be wound around the outer peripheral part of the spool 3 by feeding the film leading end 2b in between.
A holding part 30a is formed in at least a part of the width direction of the film 2 to press the film 2 against the outer peripheral part of the spool 3, and
The roller 30 is moved toward the spool 3 so that when the leading edge 2b of the film is fed between the spool 3 and the roller 30, the presser portion 530a faces the outer circumference of the spool 3 with a predetermined gap. For example, the roller 30 is characterized in that a large diameter portion 30b is provided in a part of the roller 30 as a regulating means. In addition, in FIGS. 1 and 2, 30c is a small diameter portion formed in a corresponding portion of the roller 30 in order to escape the claw portion 3a corresponding to the perforation 2a protruding from the outer peripheral portion of the spool 3. Furthermore, in this example,
1-The large diameter portions 30b, 30b are placed at both ends of the roller 30 at a distance lower than the width of the film 2 so as to be shifted downward from both edges of the film 2 in the width direction. is forming. Also, -) double roller 3
0 is pivotally supported by the support bracket 31 and the like as illustrated in FIG. 1O described above, but detailed illustration thereof will be omitted.

According to such a configuration, before the film leading end 2b is fed, as is clear from FIG. A gap 34 for feeding the film 2 is formed. The gap t of this gap 34 is
Greater than the thickness T of film 2.

17 This film thickness T and spool 3" second claw part 3
It is set to be smaller than the sum of a and the protrusion height X. That is, there is a relationship of T<t<"r+x.

According to such a configuration, the leading edge 2b of the film is fed between the spool 3 and the roller 30! +, since a predetermined gap t is provided between both members 3 and 30 in consideration of the thickness T of the film 2, etc., the film tip 2
b can be appropriately and reliably inserted between the spool 3 and the roller 30 with a relatively weak extrusion force,
The coil 2 can be reliably wound around the outer periphery of the spool 3. That is, when the film is fed, its leading end 2b is smoothly and reliably pushed into the gap 34 formed between the spool 3 and the holding part 30a of the roller 30 by the relatively weak extrusion force on the film 2 side. The roller 30 is moved by the spring 33 as explained in FIG.
There is no need to move the film 2 against the urging force, and the buckling phenomenon of the film 2 can be reliably prevented. Also, the claw portion 3 on the spool 3 side is attached to the perforation 2a of the film 2.
There is no problem that the film 2 escapes in the gap t of the gap 34 and becomes disengaged when the spool 3 and the roller 30 are engaged. It is possible to reliably prevent problems such as the leading edge 2a of the film not being able to enter between the edges of the spool 3 and winding the film correctly around the outer periphery of the spool 3. You can definitely do it.

Here, in the embodiment described above, the gap t of the gap 34 formed between the presser part 30a and the outer circumference of the spool 3 by attaching the large diameter part 30b to the outer circumference of the spool 3
Although the case where the gap t is set to satisfy the relationship Tit<T+x has been described, the gap t may be set slightly smaller than the thickness T of the film 3. This is shown in FIG. 3, where the axial center of the spool 3 and the center of the roller 30 when the film 2 is fed into the gap 34 between the spool 3 and the roller 30 by the extrusion force S. The angle θ1 between the corner of the film tip 2b and the line segment connecting the centers of each axis with respect to the line segment connecting the axis centers. θ2 is smaller than when 1=0 shown in FIG. 12 due to the existence of the gap 34. Therefore, when feeding the leading edge 2a of the film into the wedge-shaped space, the wedge effect increases, and a smaller extrusion force S of the film 2 causes the roller 3
0 can be moved in a direction away from the spool 3 against the biasing force of the spring 33, thereby reducing the risk of the film 2 buckling, and the advantage of this can be easily understood.

Further, in the above embodiment, the large diameter portions 30b, 30b are formed at both ends on the roller 30 side, but instead of this, as shown in FIG. By shaping the large-diameter parts 3b, 3b with a larger dimension than the spool 3, and bringing a part of the presser part 30a on the roller 930 side into contact with the large diameter parts 3b, 3b, the distance between the outer peripheral part of the spool 3 and the presser part 30a is reduced. A gap 34 may also be formed.

By the way, in the examples shown in FIGS. 2 and 4 described above, the large diameter portions 30b, 30b on the roller 30 side, which are formed with a larger interval than the width dimension of the film 2 in the width direction, are connected to the outer periphery of the spool 3. or the large diameter portion 3b on the spool 3 side,
3b is attached to a part of the holding part 30a on the roller 30 side to form the gap 34 for passing the film 2. However, in such a configuration, the spool 3
This increases the length of the roller 30 and the roller 30 in the axial direction, which poses a problem in reducing the size of the camera.

In order to solve such problems, please refer to Figures 5 and 6.
It is preferable to adopt a configuration as shown in the figure.

That is, a large diameter portion 30b for forming the gap 34 is formed at the center portion of the roller 30 in the axial direction by being attached to the outer peripheral portion of the spool 3, and a large diameter portion 30b is formed so as to escape from this portion. The case is shown in which a notch groove 2C0 slightly wider than the width dimension of the film is cut from the film tip 2b. In addition, the outer circumference of the spool 3 and the holding part 3 of the roller 30
It is preferable that the gap t of the gap 34 formed between the film and the film 0a satisfies the above-mentioned relationship Tit<T+x, or is set slightly smaller than the film thickness T. In this way, the lengths of the spool 3 and roller 30 in the film width direction can be shortened, and the camera can be made smaller.

Even with such a configuration, the leading end 2b of the film can be fed between the outer circumferential portion of the spool 3 and the holding portion 30a of the roller 30 without causing problems such as buckling, as in the embodiment described above. It will be clear that it could be in a rollable state. Note that after the perforation 2a of the film 2 is engaged with the claw m3a and is wound up, the proximal end side of the notch groove 20 is located at the joining part between the large diameter part 30b and the outer peripheral part of the spool 3. However, at this time, the film 2 is hooked onto the claw portion 3a and wound onto the spool 3, and the film 2 is wound and travels by moving the roller 30 against the spring 33. Problems such as buckling deformation due to the extrusion force S acting on the film 2 do not occur during such intrusion.

By the way, in this embodiment, the groove depth of the notch groove 20 requires that the perforation 2a be engaged with the claw portion 3a before the base end of the groove reaches the large diameter portion 30b. , it is necessary to increase the depth k to some extent.

However, if such a tip shape of the film 2 is adopted, the rigidity at the tip portion of the film will be reduced.

When such a decrease in rigidity at the leading end of the film is undesirable, as shown in FIGS. 7 and 8, the depth k of the cut groove 2C is set to be small enough not to cause a decrease in rigidity, and Gap t of gap 34 in Fig. 6
It is preferable to set T/2. That is, with such a configuration, when the leading edge 2b of the film is fed, first,
The tip 2b moves the roller 30 with a relatively weak force against the urging force of the spring 33 (only φ corresponding to T-t=T-T/2-T/2), the presser part 30a and the outer peripheral part of the spool 3. It is possible to get in between. After that, the base end of the notch groove 2C immediately reaches the large diameter part 30b, and at this time, the perforation 2a is not hooked on the claw part 3a, so the extrusion force S is acting on the film 2. At this point, the film leading end 2b has already entered between the holding part 30a and the outer circumference of the spool 3, and as shown in FIG. Since T/2 has occurred, the base end of this notch yt2c can also move the roller 30 with a relatively weak force against the biasing force of the spring 33, and the film 2 can be moved onto the spool 3.
and the roller 30.

As a result, the film 2 can be reliably fed and wound at a suitable angle without causing a buckling phenomenon.

Furthermore, in the above embodiment, the notch groove 2C is formed at the center of the tip of the film 2, but on the contrary, notch grooves 2c, 2c are formed at both ends, and the central protrusion 2d is It is first inserted between the presser part 30a formed correspondingly and the outer circumferential part of the spool 3,
It goes without saying that the base end portions of the notch grooves 2c and 2c may be inserted into the grooves 2c in the next step.

Note that the present invention is not limited to the structure of the embodiment described in -E, and the shape and structure of each part, including the type of film cartridge I and the configuration of each part including the film feeding device 10, etc., may be modified as appropriate. , are free to change, and various modifications may be considered. For example, in the embodiment described in -1 above, the case where the claw portion 3a for hooking the perforation 2a is formed on the take-up spool 3 has been described, but the invention is not limited to this.
For example, it goes without saying that a spool having a friction material such as rubber on its surface may be used. Further, the present invention provides 4;
It goes without saying that the present invention is not limited to the film cartridge 1 described in the above-mentioned embodiments, but may also be used in a camera feeding system using a 35 mm film cartridge carried on a boat.

Furthermore, in the embodiment described above, the case where the roller 30 or 4 is provided with a large diameter part on the spool 3m to restrict the movement of the roller 30 is explained, but the present invention is not limited to this. An appropriate regulating member may be provided.

〔Effect of the invention〕

- As explained above, according to the film winding device for a camera according to the present invention, at least a portion of the film in the width direction at the outer periphery of the presser roller that is attached so as to press the film against the outer periphery of the take-up spool. A presser part is formed to press the film against the outer circumference of the spool, and when the leading edge of the film is fed between the spool and the presser roller, the presser part is placed between the outer circumference of the spool and the film nozzle or the like. A regulating means for regulating the movement of the presser rollers toward the spool is provided so that they face each other with a predetermined gap in consideration of the tip shape, etc., so that the spool at the tip of the film, despite the simple structure, The film can be fed smoothly and reliably into the gap between the rollers using a relatively weak extrusion force, and the film may buckle due to the extrusion force and be unable to fit between the spool and roller, making it impossible to wind the film correctly onto the spool. There are various excellent effects such as preventing problems such as not being able to remove the film, and making it possible to wind the film efficiently, appropriately, and reliably around the outer periphery of the spool.

BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1 and 2 are a schematic perspective view of the main structure of a first embodiment of a film winding device for a camera according to the present invention, and a side view thereof as seen from the direction of the arrow; FIG. 3 is a schematic view showing a modified example of the state in which the leading edge of the film is fed between the take-up spool and the presser roller, FIG. 4 is a schematic perspective view showing yet another modified example, and FIGS. 6 is a schematic perspective view showing a second embodiment of the present invention and a side view thereof seen from the direction of arrow B, and FIGS. 7 and 8 are schematic perspective views showing a third embodiment of the present invention and its side view seen from the direction of arrow C. A side view showing the state in which the leading edge of the film has entered between the take-up spool and the presser roller when viewed from the direction, FIG. 9 is a schematic perspective view of a modification thereof, and FIG. 10 is a film suitable for applying the present invention. Outline of the feeding device 6: A perspective view of essential parts showing the bottom of the tank; FIG. 11 is a schematic exploded perspective view of the one-way clutch used in the installation shown in FIG. 10;
FIG. 12 is an explanatory diagram for explaining the problem when the leading edge of the film is fed between the take-up spool and the presser roller, whose outer peripheral portions are in contact with each other. l・◆・◆Film Patrone, 2◆・◆・Film,
2a...Perforation, 2b...Film tip, 2C...Notch groove, 2d...Protrusion piece, 3
...Take-up spool, 3a...Claw part, 30...
...Press roller, 30a...Press section, 30b...
・Large diameter part (regulating means), 30c...Small diameter part for claw escape, 34...Gap, T...Film thickness, t
...Gap gap, X...Claw protrusion height. 4￥ Applicant: Nikon Corporation Co., Ltd.

Claims (1)

[Claims] The device comprises a take-up spool for winding the film, and a press roller attached to the take-up spool for pressing the film against the outer circumference of the spool, and between the take-up spool and the press roller. In a film winding device for a camera, in which the leading edge of the film is fed so that the leading edge of the film can be wound around the outer periphery of the take-up spool, the film is wound at least partially in the width direction of the film at the outer periphery of the presser roller. forming a presser portion that presses the film against the outer peripheral portion of the take-up spool, and when the leading edge of the film is fed between the take-up spool and the press roller,
A camera film characterized in that a regulating means is provided for regulating the movement of the presser roller toward the take-up spool so that the presser portion faces the outer peripheral portion of the take-up spool with a predetermined gap therebetween. Winding device.