JP2660091B2 - Camera film initial feeder - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention is used in an auto-loading camera, and feeds the film until the leading end of the film drawn from a patrone is wound around a take-up spool. It concerns the device.

[Conventional technology]

In order to simplify film loading, a drop-in loading compact camera is already commercially available as "Caldia" (trade name, product of the present applicant).
In this compact camera, when the back cover is opened, a patrone insertion opening is exposed at the bottom of the camera body, and a slit is formed between the camera body and the back cover. When the patrone is inserted from the patrone insertion port in the axial direction, the leading end of the film enters the camera body through the slit at the same time and is set in the film passage. In the case of a drop-in loading type compact camera that does not require the leading end of the film to reach the film winding chamber, the leading end of the film completely winds around the winding spool in the film winding chamber. Until,
It is necessary to advance the film.

A conventional film initial feeder is disclosed in, for example,
As described in Japanese Patent No. 61532, a rotatable film feed member is disposed near the exposure frame, and one feed claw formed on the outer periphery of the film feed member projects into the film passage. The film feed member is provided with a rotational force from a drive source for rotating the take-up spool via a one-way clutch or a gear train. When the patrone is loaded into the film supply chamber and the back cover is closed, the film feed member rotates. During the rotation of the film feed member, the feed pawl engages with the perforation at the leading end of the film, and feeds the leading end of the film toward the film winding chamber. When the leading end of the film reaches the take-up spool, the perforations at the leading end of the film are engaged with a plurality of claws provided on the outer periphery of the take-up spool. After the film leading end is completely wound around the take-up spool by this initial film feed, the film feed speed by the take-up spool is faster than the film feed speed by the film feed member. This is done by the spool. During film feeding and film rewinding by the spool drive, the film feeding member is rotated by the one-way clutch following the film so as not to hinder the film feeding. Also, after the initial film feeding is completed, the feeding claw of the film feeding member is
There are also known ones that retreat from a film passage.

[Problems to be solved by the invention]

Recent compact cameras tend to have higher functions by using a bifocal lens or a zoom lens as a photographing lens. However, such a photographing lens becomes large due to a large number of lenses. Therefore, in order to reduce the size of the camera when not in use, it is preferable that the rear end of the taking lens is sufficiently retracted into the camera body to a position close to the exposure frame. However, since the above-described film initial feed device is disposed near the exposure frame, it is necessary to avoid interference between the film initial feed device and the photographing lens. Therefore,
One of the improvements in reducing the size of the camera is to secure a space around the exposure frame where the film initial feeder is provided so that the taking lens can enter.

Further, the conventional film initial feeder requires a one-way clutch, a gear train for transmitting a rotational force to the film feed member, and the like, and therefore the number of parts is increased and the structure is very complicated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a film initial feeder that can reduce the space occupied by the photographing lens in the optical axis direction and has a simple configuration.

[Means for solving the problem]

In order to achieve the above object, the film initial feeding device according to claim 1 includes a film feeding member having a feeding claw that engages with a perforation at a leading end of the film, and a position off the center of the end surface of the take-up spool. And a drive lever for engaging the engaging portion to reciprocate the film feed member in the film feed direction with rotation of the take-up spool, and a feed pawl facing the take-up spool. Guide means for displacing the feed pawl from an initial state in which the feed claw is retracted from the film passage to a state in which the feed claw protrudes into the film passage, and in this state, moving the feed claw along the film passage. Is wound around the take-up spool, the drive lever is pressed by the side edge of the film and retracted from the rotation range of the engagement portion. Ri is intended that the film initial feed was to be terminated.

In the film initial feeding device described in claim (2), the film feeding member is reciprocated intermittently so that the leading end of the film is securely wound on the take-up spool.

The film initial feeding device described in claim (3) engages with the engaging portion within a predetermined range of one rotation of the take-up spool, and moves the film feed member to a position closest to the take-up spool. The drive lever is provided with a hook for moving, and a spring member for returning the film feed member to an initial position farthest from the take-up spool after the engagement between the hook and the engaging portion is released. .

According to a fourth aspect of the present invention, there is provided an initial film feed device, comprising: a film feed member having a feed claw engaged with a perforation at a film leading end; and a film feed member connected to the film feed member. A drive lever that reciprocates between a first position where the film feed member is closest to the take-up spool and a first position where the film feed member is closest to the take-up spool. During the movement of the engaging portion provided on the end face of the take-up spool by a predetermined angle in order to move to the position 2,
A hook lever that engages with the engagement portion, biasing means for returning the drive lever to the first position when the hook lever is disengaged from the engagement portion, and a hook lever integrally provided. After the film tip is wound around the outer periphery of the take-up spool, the film is pressed by the side edge of the film, and the hook lever is retracted from the rotation area of the engaging portion to terminate the initial film feed. It is composed.

In the film initial feed device described in claim (5), the drive lever and the hook lever are integrated into one arc-shaped lever.

The film initial feeding device described in claim (6) is a film feeding member having an engaging portion that engages with the perforation of the film tip, and a projection formed at a position off the center of the end surface of the take-up spool. A drive lever for contacting the projection and intermittently reciprocating the film feed member in the film feed direction, and a drive lever provided between the drive lever and the take-up spool; After being wound around the outer periphery, the film is constituted by a film side edge detecting member for displacing the drive lever by being pressed by the side edge of the film and retracting from the rotation area of the projection.

The film initial feed device according to claim (7), wherein a cam member rotatably disposed at an end of the take-up spool;
When the take-up spool rotates in the film take-up direction, the cam member is interlocked with the take-up spool, and when the take-up spool rotates in the film rewind direction, a one-way clutch for separating the cam member from the take-up spool, and a cam member are provided. A drive lever intermittently oscillated by the cam member when rotating together with the take-up spool, and a feed pawl engaged with the perforation at the film tip,
The drive lever intermittently reciprocates on the film passage, and comprises a film feed member for feeding the leading end of the film toward the take-up spool.After the leading end of the film is wound on the outer periphery of the take-up spool, When the drive lever is pressed by the side edge of the film and retracts from the rotation range of the cam member, the initial film feed is completed.

The film initial feeder described in claim (8) engages with a perforation at the leading end of the film to intermittently transport the leading end of the film toward the take-up spool, and a leaf spring. The film feed member is connected to the film feed member and swings between a first position where the film feed member is farthest from the take-up spool and a second position where the film feed member is closest to the take-up spool. A drive lever that moves, a toggle spring for holding the drive lever in a first position and a second position, respectively;
A projection provided on an end surface of the take-up spool, the projection being configured to contact a part of the drive lever to return the drive lever to the first position when the drive lever is at the second position; And a hook lever which is adapted to be engaged with the projection when the drive lever is moved to the second position and to be released from the projection when the drive lever is moved to the second position, so that the leading end of the film is wound around the outer periphery of the take-up spool. Later, the hook lever is pressed by the side edge of the film, the leaf spring bends, and the hook lever retreats from the rotation range of the projection, thereby terminating the initial film feeding.

[Action]

In the film initial feeder described in claim (1),
The engaging portion rotates with the rotation of the take-up spool, and the drive lever engaged with the engaging portion moves to reciprocate the film feeding member connected thereto in the film feeding direction. The film feed member projects the feed pawl into the film passage at the initial stage of its movement, engages with the perforation of the film leading end, and moves along the film passage in this state, thereby winding the film leading end. Feed toward. Then, when the leading end of the film is wound around the outer periphery of the take-up spool, the drive lever is pressed by the side edge of the film and retreats from the rotation region of the engaging portion, and the initial film feed is completed.

In the film initial feeder described in claim (2),
A drive lever intermittently reciprocates the film feed member.

In the film initial feeder described in claim (3),
A drive lever that engages with the engaging portion of the take-up spool within a predetermined range of one turn of the take-up spool, and moves the film feed member to a position closest to the take-up spool; and After the engagement between the hook and the engaging portion is released, a spring member is provided for returning the film feed member to an initial position farthest from the take-up spool.

In the film initial feeder described in claim (4),
When the take-up spool rotates, the hook lever engages with an engaging portion provided on the end surface thereof, so that the hook lever is interlocked with the take-up spool only while the take-up spool rotates a predetermined angle. When the drive lever moves together with the hook lever and the hook lever comes off the take-up spool, the bias lever returns the drive lever to the initial position together with the hook lever. Due to the movement of the drive lever, the film feed member reciprocates intermittently along the film path, and feeds the film leader toward the take-up spool. Then, when the leading end of the film is wound around the outer periphery of the take-up spool, the film side edge detecting member provided integrally with the hook lever is pressed against the side edge of the film, and the hook lever is retracted from the rotation range of the engaging portion. Then, the initial film feed is completed.

In the film initial feeder described in claim (5),
The drive lever and the hook lever are integrally formed as one arc-shaped lever.

In the film initial feeder described in claim (6),
When the take-up spool rotates, the drive lever is pushed by the protrusion formed on the end surface. Due to the swing of the drive lever, the film feed member reciprocates intermittently along the film path, and feeds the leading end of the film toward the take-up spool. When the leading end of the film is wound around the outer periphery of the take-up spool, the drive lever is pressed by the side edge of the film via the film side edge detecting member, and retracts from the rotation area of the projection, thereby completing the initial film feed.

In the film initial feeder described in claim (7),
When the take-up spool rotates, the cam member rotates via the one-way clutch, and the driving lever reciprocates by the cam member. Due to the swing of the drive lever, the film feed member reciprocates intermittently along the film path, and feeds the leading end of the film toward the take-up spool. Then, when the leading end of the film is wound around the outer periphery of the take-up spool, the drive lever is pressed by the side edge of the film and retracts from the rotation region of the cam member, and the initial film feed is completed.

In the film initial feeder described in claim (8),
When the take-up spool rotates, the hook lever engages with a protrusion provided on the end surface. When the hook lever moves by a predetermined stroke following the take-up spool together with the drive lever, the hook lever naturally comes off the projection.
Because a toggle spring is hung on this drive lever,
When the hook lever is disengaged from the projection, the drive lever is held in that position. When the take-up spool further rotates, the projection comes into contact with and pushes the drive lever, so that the drive lever is returned to the initial position together with the hook lever. When the drive lever crosses the dead point of the toggle spring during the movement,
It is biased in the direction of the initial position by this toggle spring.
When the drive lever swings within a predetermined range, the film feed member is moved along the film path, and the film leader is fed toward the take-up spool. When the leading end of the film is wound around the outer periphery of the take-up spool, the hook lever is pressed by the side edge of the film, and the hook lever is retracted from the rotation area of the projection while deforming the leaf spring, thereby ending the initial film feeding. .

〔Example〕

FIG. 1 shows a drop-in loading camera, in which the back cover is completely opened beyond the film loading position to show the inside in detail. Camera body 2
The back cover 3 is provided via a hinge 4 so as to be freely opened and closed. An exposure frame 5 for determining a screen size is provided in the center of the inside of the camera body 2, and a film supply chamber 7 and a film winding chamber 8 are provided on the left and right sides thereof. A patrone 10 is loaded into the film supply chamber 7, and the patrone 10 includes a patrone main body 2a and a spool 12b rotatably stored in the patrone main body 12a.
And 135 type film 9 wound on this spool 12b
It is composed of A film rewinding shaft 15 for rotating the spool 12b of the cartridge 10 at the time of film rewinding is provided in the film supply chamber 7 in a protruding state. On the bottom side of the film supply chamber 7, an insertion port 7a of the patrone 10 that is exposed when the back cover 3 is opened is formed. Behind the film supply chamber 7, a plate 16 for regulating the position of the cartridge 10 is provided. The film take-up chamber 8 is provided with a take-up spool 11 for taking up the film 9 rotatably.
(See FIG. 2).

Above the exposure frame 5, a driven sprocket 17 which rotates following the film 9 and detects a feed amount of the film 9 is arranged. The driven sprocket 17 is related to a perforation 9a of the film 9. A plurality of teeth to be combined are formed at a constant pitch. Below the exposure frame 5,
A film feeding member 18 is arranged, and its feeding claw 18a
Engages with the perforation 9a to intermittently feed the film leading end 9b toward the take-up spool 11. In FIG. 1, the feed claw 18a is shown in a state protruding from the film guide surface 25. However, in actuality, when the film is loaded, the film tip 9b does not hit the feed claw 18a. Have been evacuated. On the outer periphery of one end of the take-up spool 11, a plurality of saw-toothed claws 11a that engage with the perforations 9a of the film 9 are formed. A film pressure plate 30 for pressing the film 9 on the film guide surface 25 is provided in the center of the inside of the back cover 3, and a film passage 19 is formed therebetween. Reference numeral 32 denotes a film guide plate that guides the leading end portion 9b of the film that has entered the film winding chamber 8 toward the outer periphery of the winding spool 11.

In FIG. 2, the film initial feeding device includes a feeding claw 18.
a, a drive lever 20 for driving the film feed member 18, and a take-up spool.
11, a spool cam 22 formed on the end face 11 b, a taper portion 23 provided in the film winding chamber 8, and a drive lever 20.
And a spring 40 for biasing the spring.
A hole 24 for connecting the drive lever 20 is formed at the other end of the film feed member 18. The connection pin 28 is inserted into the hole 24 and the hole 26 of the drive lever 20.
A spring 30 for applying a clockwise rotational force to the film feeding member 18 is applied to the connecting pin 28.

Two guide plates 34 are provided on the left and right of the film feed member 18.
Are arranged, and the guide pins 32 abut against these lower surfaces, whereby the film feed member 18 is guided.
An inclined surface 34a is formed at the left end portion of the guide plate 34 so that the feed claw 18a does not protrude above the film guide surface 25 when the film feed member 18 is at the initial position. . The drive lever 20 is formed in a substantially arc shape, and reciprocates the film feed member 18 by the rotational force of the take-up spool 11. A hole 36 is formed at one end of the drive lever 20, and a rotation shaft 38 supported by the camera body 2 is inserted therethrough. A spring 40 is inserted through the rotating shaft 38. The spring 40 urges the drive lever 20 counterclockwise and urges the drive lever 20 toward the take-up spool 11.

A hook 41 is provided on a part of the inside of the drive lever 20, and this hook 41 is engaged with the engaging portion 22a of the spool cam 22 only for a certain section when the spool cam 22 rotates clockwise in FIG. With the drive lever 20
Swings following the take-up spool 11 only by the section.
Further, the tip portion 42 of the drive lever 20 is bent in a V-shape, and when the tip portion 42 moves along the tapered portion 23,
The entire drive lever 20 is pushed outward along the rotation axis 38. As a result, the engagement between the hook 41 of the drive lever 20 and the engagement portion 22a of the spool cam 22 is temporarily released, and the drive lever 20 swings counterclockwise due to the accumulated force of the spring 40 and is initially It returns to the position.

Next, the operation of the above embodiment will be described with reference to FIG. In FIG. 3B, the pressure plate and the film guide plate are omitted. When a film is loaded in the camera 1, first, the back cover 3 is opened to a film loading position. In this state, the patrone insertion opening 7a is exposed, and a slit is formed between the camera body 2 and the back cover 3. When the patrone 10 is inserted into the patrone insertion portion 7a from the axial direction, the film tip 9b protruding from the patrone 10 is inserted.
Is inserted into the film passage 19 through the slit.
When the cartridge 10 is completely stored in the film supply chamber 7, the spool 12b is connected to the film rewind shaft 15.
When the back cover 3 is closed, the back cover detection switch (not shown) turns on.
Then, the motor 13 housed in the take-up spool 11 rotates. The rotation of the motor 13 is fed back to the take-up spool 11 via a drive gear 14 and a well-known gear train.

When the take-up spool 11 is rotated clockwise by the motor 13, the engagement portion of the spool cam 22 is rotated as shown in FIG.
The hook 41 of the drive lever 20 is engaged with 22a. At this point, the guide pins 32 of the film feed member 18 are
The feed claw 18a is retracted from the film guide surface 25. When the take-up spool 11 further rotates, the drive lever 20 follows the rotation of the rotation shaft 38.
Swings clockwise around the fulcrum. As a result, the film feeding member 18 moves toward the film winding chamber 8 while being guided by the guide plate 34, as shown in FIG. 3 (B). The film feed member 18 moves, and the guide pin 32
When the sheet passes through the inclined surface 34a, the feed claw 18a protrudes from the film guide surface 25, and the feed claw 18a engages with the perforation 9a to transfer the film leading end 9b toward the film winding chamber 8.

When the end portion 42 of the drive lever 20 comes into contact with the tapered portion 23, the drive lever 20 is pushed out along the rotation shaft 38 in a direction perpendicular to the paper surface. As a result, the engagement between the hook 41 of the drive lever 20 and the engagement portion 22a of the spool cam 22 is temporarily released, and the drive lever 20 swings counterclockwise by the force of the spring 40 and returns to the initial position. . At this time, the feed claw 18a slides under the stopped film 9. Take-up spool 11
Is rotated once, the drive lever 20 re-engages with the spool cam 22 to reciprocate the film feed member 18 in the film feed direction as described above. Hereinafter, the film feeding member 18
By repeating the same operation, the film tip
9b is intermittently transferred to the film winding chamber 8. The film leading end 9 b sent to the film winding chamber 8 is guided toward the outer periphery of the winding spool 11 by the film guide plate 32.

As shown in FIG. 3 (B), when the film tip 9b reaches the take-up spool 11, the perforations 9a engage with the pawls 11a of the take-up spool 11, and the film tip 9a is wound around the take-up spool 11. . The film feed member 18
Since the film tip 9b is intermittently transported, the claw 11a can reliably hook the perforation 9a while the film tip 9b is stopped. Film tip
When 9b winds around the take-up spool 11, the film tip 9b
The side edge 9c of the drive lever pushes against the side of the drive lever 20, so the drive lever
20 moves outward against spring 40. As a result, the drive lever 20 retreats from the rotation range of the spool cam 22, so that the link between the drive lever 20 and the take-up spool 11 is released. The interlock between the drive lever 20 and the take-up spool 11 is released even while the drive lever 20 returns to the initial position shown in FIG. 3A or while the drive lever 20 is engaged with the spool cam 22. I do. In the latter case, since the drive lever 20 is disengaged from the spool cam 22, the spring 40
Swings counterclockwise to return to the initial position. In either case, the film feeding member 18 is in a state where the feeding claw 18a is retracted from the film guide surface 25 as shown in FIG. The state in which the hook 41 is out of the rotation range of the spool cam 22 is maintained until the film leading end 9b is separated from the take-up spool 11 by film rewinding described later.

After the completion of the initial film feed, the film 9 is fed by the rotation of the take-up spool 11, and the first frame is set in the exposure frame 5. When the shutter button is operated by pressing the release button, the first frame is exposed.
After this exposure, the motor 13 rotates and the film 9 is wound around the winding spool 11 by one frame. When all frames have been photographed, the film 9 cannot be pulled out of the cartridge body 12a. Therefore, an increase in load is detected by a well-known torque detecting mechanism (not shown), and a motor circuit (not shown) is set to the film rewind mode. Is done.

In the film rewind mode, the motor 13 rotates in the reverse direction to rotate the spool 12b in the cartridge 10 via the film rewind shaft 15.
To rotate. The exposed film 9 is returned into the cartridge 10 by the rotation of the spool 12b. At this time, the take-up spool 11 is rotated by the film 9. During film rewinding, the film 9 is stopped while the side surface of the drive lever 20 is pressed by the side edge 9c of the film 9. And
When the film leading end 9b moves away from the take-up spool 11, this rotation stops. At the same time, the drive lever 20 is pushed back to the take-up spool 11 by the force of the spring 40, and the drive lever 20 can be engaged with the spool cam 22,
Preparation for the next film initial feed is completed. The motor
13 stops when all of the exposed film 9 is rolled into the cartridge 10.

FIGS. 4 and 5 show an embodiment in which a hook lever is provided separately from the drive lever so that the hook lever is naturally released from the spool cam. The same reference numerals are given. In FIG. 4, the film initial feeding device includes a film feeding member 18.
A drive lever 50 for reciprocating the spool cam 52, a spool cam 52, a hook lever 54 for connecting the spool cam 52 and the drive lever 50, and a film side edge detecting member.
And 68. Guide plate 56 has a guide pin
A guide hole 56a through which the film 32 is inserted is formed, and when the film feeding member 18 moves toward the film winding chamber 8, the guide pin 32 moves along the upper inner edge of the guide hole 56a. Further, the left end portion of the guide hole 56a is an inclined surface, so that the feeding claw 18a
Are not projected above the film guide surface 25. Below the film feed member 18, two fixing pins
A spring member 58 fixed to the guide plate 56 by 57 is arranged. The spring member 58 includes a leaf spring 58a that constantly urges the film feed member 18 upward, and a base plate 58b that holds the leaf spring 58a in a cantilever manner.

The drive lever 50 is made of a spring material, and has a lower end formed in an arc shape so as to follow the inner wall of the film winding chamber 8. A pin 59 is provided at the upper end of the drive lever 50 to be inserted into the hole 24 of the film feed member 18. A rotary shaft 60 is fixed to an intermediate position of the arc portion of the drive lever 50, and the rotary shaft 60 is rotatably attached to the camera body 2. The lower end portion 61 of the drive lever 50 is thin to provide spring properties, and has a convex portion 61 at its tip.
a is formed. Thus, when the drive lever 50 swings clockwise around the rotation shaft 60, the convex portion 61
a is pressed against the inner wall of the camera body, and stores a force for restoring the drive lever 50.

The hook lever 54 swings the drive lever 50, and a hole 63 through which the pin 64 of the drive lever 50 is rotatably inserted.
Is formed at one end. A spring 66 for urging the hook lever 54 clockwise is disposed between the hook lever 54 and the pin 64 of the drive lever 50. The spring 66 has one end hooked on the projection 65 of the hook lever 54 and the other end hooked on the drive lever 50.
A hook 54a that engages with the engaging portion 52a of the spool cam 52 only when the spool cam 52 rotates clockwise is formed at the tip of the hook lever 54. Hook lever 54
A film side edge detecting member is provided on the surface on the take-up spool 11 side.
The hook lever 54 is moved along the pin 64 by being pressed by the side edge 9c of the film 9 wound around the take-up spool 11.

Next, the operation of the embodiment shown in FIG. 4 will be described with reference to FIG. Winding spool as in the previous embodiment
When the clock 11 rotates clockwise, the hook 54a of the hook lever 54 is engaged with the engaging portion 52a of the spool cam 52 as shown in FIG. When the take-up spool 11 further rotates, the rotation of the spool cam 52 is transmitted to the drive lever 50 via the hook lever 54, and the drive lever 50 swings clockwise about the rotation shaft 60. The swing of the drive lever 50 causes the guide pin 32 of the film feed member 18 to move upward along the inclined surface from the lower left portion of the guide hole 56a of the guide plate 56, and the feed claw 18a projects into the film passage 19. Let it. As shown in FIG. 5B, the feed claw 18a linearly moves from left to right on the film passage 19 by cooperation of the guide pin 32 and the guide hole 56a. This feed claw 18a
Engages with the perforations 9a of the film leading end 9b and transfers the film leading end 9b toward the film winding chamber 8.

When the take-up spool 11 rotates beyond the state shown in FIG. 5 (B), the hook lever 54 is regulated by the outer peripheral surface of the spool cam 52, so that the hook 54a naturally comes off the engagement portion 52a.
Therefore, the drive lever 50 swings counterclockwise by the spring force of its lower end 61 and returns to the initial position shown in FIG. 5 (A). At this time, the feed claw 18a moves leftward along the lower surface of the film tip 9b while deforming the leaf spring 58a. The film feeding member 18 intermittently transfers the film leading end 9b to the take-up spool 11 while repeating this operation. As described above, when the film leading end 9b winds around the take-up spool 11, the film side edge detecting member 63 is pushed, and the hook lever 54 moves outward along the pin 64 while resisting the spring 66, Retreat from the rotation range of the spool cam 52. If the drive lever 50 is
When the hook lever 54 is
52, the drive lever 50 swings counterclockwise by its own spring force, and the film feed member 18
Return to the initial position as shown. As described above, the hook lever 54 does not engage the spool cam 52 between the film winding following the initial film feeding and the film rewinding. Then, when the film leading end portion 9b comes off the take-up spool 11 by film rewinding, the take-up spool 11 is stopped, and the hook 66 is pushed back to the take-up spool 11 by the spring 66, and the next initial film feed is performed. Preparation is completed.

In this embodiment, the hook 54a of the hook lever 54 naturally comes off the engaging portion 52a by the downward movement of the engaging portion 52a of the spool cam 52 in FIG. The space in the axial direction of the film winding chamber 8 can be small, which is suitable for designing a short camera. Further, since the hook lever 54 has a one-way clutch function, the take-up spool 11 can be reversed by the motor 13 at the time of film rewinding. Also, since only the hook lever 54 moves in the axial direction, the take-up spool 11
Is smoothly released.

FIGS. 6 and 7 show an embodiment in which the film feed member is reciprocated using a cam mechanism. The same members as those in the above-described embodiment are denoted by the same reference numerals. The film feed member 70 is cut into two arms 71 and 72, and a feed claw 71a is formed at the tip of one arm 71. The other arm 72 is curved in order to impart a spring property, and a convex portion 72a provided at the tip is a concave portion of the camera body 2 as shown in FIG.
It fits in 2a.

A guide plate 74 is disposed above the film feed member 70, and a feed claw 71a enters a guide groove 74a formed in the center. In order to prevent the feed claw 71a from protruding above the film guide surface 25, an inclined convex portion 74b is formed on the lower surface of the end of the guide plate 74 on the film supply chamber 7 side.
Are formed. The drive lever 73 is substantially fan-shaped, and is wound into a long hole 75 formed in the upper right portion thereof.
The eleven drive pins 76 are fitted. In addition, in part of long hole 75,
A recess 75a for allowing the drive pin 76 to escape is provided.

A shaft 77 serving as a rotation center penetrates a lower end of the drive lever 73, and the shaft 77 is provided with a hole 79 of a base plate 78 and a bearing plate 80.
It is rotatably supported by the hole 81. This base plate 78
Is fixed to the camera body 2. Bearing plate 80 and shaft
A spring 83 whose one end is hung on a pin 82 of the drive lever 73 is disposed between the drive lever 73 and the drive lever 73 to urge the drive lever 73 toward the base plate 78. The bearing plate 80 has screw holes
The base plate 78 is provided by two screws 84 and 85 that are screwed into 86 and 87.
It is fixed to. A spring 90 is hung on the drive lever 73, and the spring 90 urges the drive lever 73 counterclockwise. Drive lever 73
The slide pin 91 penetrates the arc groove 92 of the base plate 78 and fits into the hole 93 of the film feed member 70.

The base plate 78 has a shaft hole 94 into which the end of the take-up spool 11 is rotatably fitted, and a protrusion of the film side edge detecting member 95.
An arc hole 96 through which 95a passes is formed. When the film side edge detecting member 95 is pushed by the side edge 9c of the film leading end portion 9b, it moves the drive lever 73 in a direction away from the base plate 78, whereby the elongated hole 75 of the drive lever 73 and the take-up spool Controls engagement / disengagement of the eleven drive pins 76. Reference numeral 97 denotes a pin for fixing the film side edge detecting member 95 to the base plate 78.

Next, the operation of the embodiment shown in FIG. 6 will be described with reference to FIGS. 7 (A) to 7 (C). When the back cover 3 is closed after loading the film, the take-up spool 11 rotates clockwise as described above. Drive pin 76 of this take-up spool 11
Enters the long hole 75 through the concave portion 75a formed between the long hole 75 and the side edge of the drive lever 73. In such an early stage, the feed pawl 71a of the film feed member 70 is located below the projection 74b of the guide member 74, and the projection 72a is in the recess 2a. When the take-up spool 11 further rotates, the drive lever 73 swings clockwise about the shaft 77 by rotation of the drive pin 76. By the swing of the drive lever 73, as shown in FIG.
Take-up spool while being guided by the lower surface of guide plate 74
Move to 11 side. At the beginning of this movement, the feed pawl 71a
Protrudes into the film passage 19 through the slit 74a, engages with the perforation 9a, and feeds the film leading end 9b toward the take-up spool 11.

When the drive pin 76 passes through the position shown in FIG. 7B, the drive pin 76 faces the recess 75a, so that the drive lever 73 rapidly swings counterclockwise due to the accumulated force of the spring 90. Move to the position shown in FIG. 7 (C). On the other hand, the drive pin
76 continues to rotate, and when it reaches the concave portion 75a again,
Through this, it enters the elongated hole 75, and the state shown in FIG. 7A is obtained. The drive lever 73 and the film feeding member 70 repeat this operation, so that the film leading end 9b is intermittently fed toward the take-up spool 11. As described above, when the film leading end 9b is wound around the outer periphery of the take-up spool 11, the side edge 9c of the film leading end 9b presses the leading end 95a of the film side edge detecting member 95. by this,
The drive lever 73 moves outward against the spring 83,
At the same time, the drive lever 73 is rotated counterclockwise by the spring 90, and the film feed member 70 is brought into the state shown in FIG. 7A. In this state, as described above, the film leading end 9b is wound by the take-up spool 11 by the film rewinding.
It is maintained until it leaves.

FIGS. 8 and 11 show an improvement of the embodiment shown in FIGS. 6 and 7. FIG. In this embodiment, a one-way clutch mechanism is disposed between the take-up spool and the drive lever so that the take-up spool can be rotated in reverse during film rewinding. As shown in FIGS. 8 and 9, a spool cam 116 is formed integrally with the end surface 11b of the take-up spool 11. This spool cam 116
Is provided with a shaft portion 116a at a central portion thereof, and a shaft hole 115a of the clutch cam 115 is rotatably fitted to the shaft portion 116a, thereby forming a one-way clutch mechanism. As shown in FIG. 11 (A), the clutch cam 115 has a clutch lever 115b and a locking claw 115c integrally formed of plastic. The clutch lever 115b has a spring property and is elastically deformed in the notch 115d.

As shown in FIG. 10, the shaft 1 fixed to the drive lever 106
04 is fitted in the shaft hole 105 of the film feed member 100.
Since the film feeding member 100 has the same structure as that of the above-described embodiment, only the reference numerals are given and the description is omitted.
A central portion of the drive lever 106 is supported by a shaft 108, and a spring 110 is bridged between the drive lever 106 and a stopper 109 fixed to the camera shown by a two-dot chain line, and biases the drive lever 106 in a counterclockwise direction. doing. Further, the shaft 108 is a hole of the member 111 on the camera side.
112 is freely fitted in the axial direction so that it can
The drive lever 106 is urged toward the take-up spool 11 by 10. At the tip of the drive lever 106, an arc-shaped projection 106b provided with a hook 106a is provided. A winding spool 1 is provided on the lower surface of the lower portion of the drive lever 106.
A tapered portion 106c pressed by the side edge 9c of the film leading end 9b wound around 1 is formed.

Next, the operation of the above embodiment will be described with reference to FIGS. 11 (A) to 11 (D). Feed claw 1 of film feed member 100
In the initial position shown in FIG. 11 (A), the taper portion 01a of the camera body 2 does not come into contact with the film leading end portion 9b.
It is under 103. After loading the film,
When the take-up spool 11 is rotated clockwise together with the spool cam 116 by 3, the clutch lever 115b of the clutch cam 115 is engaged with the spool cam 116.
The clutch cam 115 rotates clockwise together with the spool cam 116. Here, the drive lever 106 is urged in the counterclockwise direction by the spring 110, and the protrusion 106b is always in contact with the outer peripheral portion of the clutch cam 115. Therefore, as the clutch cam 115 rotates, the drive lever 106 Is axis 10
Rotated clockwise around 8.

The film feed member 100 moves toward the take-up spool 11 in conjunction with the rotation of the drive lever 106. Eleventh
As shown in FIG. 2B, at the beginning of the movement of the film feed member 100, the feed pawl 101a projects into the film passage 19 and engages with the perforation 9a. As the rotation of the clutch cam 115 progresses, as shown in FIG. 11 (C), the portion having the largest radius comes into contact with the projection 106b, and at this time, the film feed member 100 moves closest to the take-up spool 11. Is done.
When the clutch cam 115 further rotates, the clutch cam 115
Drive lever 10
6 is rapidly rotated counterclockwise by the accumulated force of the spring 110, and returns to the initial position shown in FIG. 11 (A). Such an operation is repeated, and the film leading end 9b is intermittently fed to the film winding chamber 8 side and wound around the outer periphery of the winding spool 11.

When the film leading end 9b is wound around the outer periphery of the take-up spool 11, the side edge 9c pushes the tapered portion 106c. As shown in FIG. 10, the drive lever 106 is moved from the position shown by the two-dot chain line to the position shown by the solid line against the bias of the spring 110, and the drive lever 106 moves away from the rotation range of the clutch cam 115. When the initial film feed is completed, the film is continuously wound by the take-up spool 11. In this film winding, the spool cam 104 and the clutch cam 115 rotate together, but the drive lever 106 engages with the clutch cam 115. Therefore, it stops at the position shown in FIG. 11 (A).

In rewinding the film, the spool 12b of the cartridge 10 and the take-up spool 11 are rotated by the motor 13. Since the back of the pawl of the spool cam 116 contacts the clutch lever 115b of the cam 115, the spool cam 116 and the clutch cam 115 rotate together in the counterclockwise direction. However, the drive lever 106
Is retracted from the rotation range of the clutch cam 115,
The drive lever 106 remains stopped. When the film leading end 9b is separated from the take-up spool 11 near the end of the film rewinding, the drive lever 106 is turned on by the spring 110.
Is returned to the take-up spool 11 by the accumulating force. As shown in FIG. 11 (D), the hook 106a of this drive lever 106 is engaged with the locking claw 115c of the clutch cam 115.
As a result, the rotation of the clutch cam 115 stops, but since the clutch cam 115 of the spool cam 116 constitutes a one-way clutch mechanism, the spool cam 116 is
It rotates with 1 as it is. Then, film tip 9
When b is completely wound into the cartridge 12a, or when a part of the film leading end 9b comes out of the cartridge body 12a by a predetermined length, the motor 13 stops and the film is rewound. Ends.

FIG. 12 and FIG. 13 show an embodiment in which the drive lever is not immediately returned when the hook lever comes off the take-up spool. One end of the drive lever 120 is rotatably attached to the lower end surface of the film winding chamber 8 via a pin 121, and the other end is connected to a hook lever 124 via a leaf spring 123. The toggle spring 122 is
One end 122a is hung on a part of the drive lever 120, and the other end 1a
22b is fixed to the lower end surface of the film winding chamber 8.
Since the toggle spring 122 has a dead point between the positions shown in FIGS. 13 (A) to 13 (C), the drive lever 120 is biased counterclockwise at the position shown in FIG. 13 (A). In the position shown in (C), the drive lever 120 is urged clockwise.

A hook 125 is formed on the hook lever 124, and the hook 125 is a spool cam 126 provided on the take-up spool 11.
Can be engaged with the projection 126a. Accordingly, when the take-up spool 11 rotates clockwise during the initial film feeding, the hook lever 124 is moved by the spool cam 126, and the drive lever 120 rotates clockwise about the pin 121. The engagement between the hook lever 124 and the spool cam 126 is naturally released at the position shown in FIG. 13 (C). To guide the movement of the hook lever 124,
The protrusion 127 is in contact with the inner wall 8a of the film winding chamber 8.

The drive lever 120 has a protrusion 126a of the spool cam 126.
The cam surface 130 is provided so as to abut against the drive lever 12 when the cam surface 130 is pressed by the spool cam 126.
0 rotates counterclockwise against the toggle spring 122 and returns to the position shown in FIG. 13 (C). At the end of the drive lever 120,
One end of the film feed member 132 is connected via a pin 131. When the initial film feed is completed, the film feed member 132 is pushed by the side edge of the film in a direction perpendicular to the plane of FIG. 13 (A) to rotate the hook 125 and rotate the spool cam 126 while bending the leaf spring 123. Evacuate the area. The other end of the film feeding member 132 has a pin 132
The pin 132b is fitted in a substantially V-shaped guide groove 133. Reference numeral 132a is a feed claw that engages with the perforation 9a.

Next, the operation of the above embodiment will be described. Immediately after the film is loaded, the feed claw 132a of the film feed member 132 is retracted from the film passage 19, as shown in FIG. When the take-up spool 11 rotates clockwise, the protrusion 126a of the spool cam 126
In order to engage with 5, the hook lever 124 moves along the inner wall 8a. In conjunction with the hook lever 124, the drive lever 120 rotates clockwise, and the film feed member 132
Moves toward the film winding chamber 8. At the initial stage of the movement of the film feed member 132, the pin 132b is
It moves along the portion 133a of 33 to reach the position shown in FIG. 13 (B). In this position, the feed claws 132a of the film feed member 132 project into the film passage 19, and can be engaged with the perforations 9a. Next, the film feed member
The pin 132b moves to the position shown in FIG. 13 (C) with its pin 132b guided by the portion 133b of the guide groove 133. During this movement, the feed claw 132a of the film feed member 132 is
b is hooked and sent to the film winding chamber 8 side.

When the take-up spool 11 rotates to the position shown in FIG. 13 (C), the hook lever 124 naturally comes off the spool cam 126. In the state shown in FIG. 13C, since the toggle spring 122 urges the drive lever 120 in the clockwise direction, the drive lever 120, the hook lever 124, and the film feed member 132 are maintained at the illustrated positions. When the take-up spool 11 further rotates clockwise, the protrusion 126a of the spool cam 126 pushes the cam surface 130 of the drive lever 120, so that the drive lever 120 passes through the position shown in FIG. ). In FIG. 13 (A), since the drive lever 120 is biased counterclockwise by the toggle spring 122,
The film feeding member 124 is kept in a state of being retracted from the film passage 19. Similarly, each time the take-up spool 11 makes one rotation, the film feed member 132 is moved to the position shown in FIG.
The film reciprocates between the two positions shown in FIG. 3C, and the film leading end 9b is intermittently fed toward the take-up spool 11 therefrom.

When the film tip 9b winds around the take-up spool 11,
Since the hook lever 124 is pushed by the film side edge 9c, the leaf spring 123 is deformed. As a result, hook lever 1
24 is retracted from the rotation range of the spool cam 126. On the other hand, since the drive lever 120 is located in the rotation range of the spool cam 126, when pushed by the spool cam 126, the drive lever 120 is returned to the position shown in FIG. 13A together with the hook lever 124 and the film feed member 132. .

After the initial film feed is completed, take-up spool
By the rotation of 11, the film 9 is wound around its outer periphery. In film winding, the film initial feeder is stopped at the position shown in FIG. 13 (A). In film rewinding, the take-up spool 11 is pulled by the film 9 and rotates in the counterclockwise direction, but the film initial feeding device remains stopped. When the film leading end 9b separates from the take-up spool 11 near the end of the film rewind, the rotation of the take-up spool 11 stops, and the hook lever 124
Enters the rotation range of the spool cam 126 by the leaf spring 123 to prepare for the next initial film feed.

In this embodiment, since the hook lever 124 is connected to the film feed member 132 via the leaf spring 123, the hook lever 124 can be displaced without difficulty when the hook lever 124 is pressed by the film side edge. Further, since the displacement of the hook lever is not transmitted to the film feed member 132, the film feed member 132 does not rub against the wall of the guide groove 133 when returning to the initial position, and the operation becomes smooth. Therefore, even if the engagement between the hook lever 124 and the spool cam 126 is released, the hook lever 124 does not return immediately, and remains at that position until the take-up spool 11 has rotated substantially half way. Therefore, the take-up spool 11 can reliably hook the film leading end 9a. That is, when the hook lever 124 immediately returns together with the film feed member 132, the film feed member 132 slightly lifts the film leading end 9b.
The engagement between the claw 11a and the perforation 9a becomes uncertain, but in this embodiment, the film feed member 132 starts to return after the winding spool 11 has rotated substantially halfway, so that the hooking of the film leading end portion 9b is stopped. Operation becomes stable.

The above embodiment is a compact camera of a drop-in loading type, but the present invention is a conventional compact camera in which the back cover is completely opened and a film is loaded, or an unexposed film is once wound on a take-up spool and photographed. The present invention can also be used for a prewind-type compact camera in which an exposed film is wound into a patrone every time.

〔The invention's effect〕

As described above in detail, according to the present invention, the film feed member is reciprocated along the film path in accordance with the rotation of the take-up spool, so that compactness and space saving in the optical axis direction are achieved. be able to. Further, since the film feed member is reciprocated intermittently, the leading end of the film can be reliably wound around the take-up spool. Further, in the present invention, the film feed member is reciprocated in conjunction with the take-up spool, so that a gear train or a one-way clutch for connecting the drive source and the film feed member as in the related art is used. This is unnecessary, and the structure can be simplified and the cost can be reduced. Furthermore, since the side edge of the film wound around the take-up spool releases the interlock between the take-up spool and the film feed member, the initial film feed can be reliably stopped with a simple configuration.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a drop-in loading compact camera provided with a film initial feed device of the present invention. FIG. 2 is an exploded perspective view showing one embodiment of the film initial feed device of the present invention. FIGS. 3A and 3B are cross-sectional views showing the operation of the embodiment of FIG. FIG. 4 is an exploded perspective view showing an embodiment in which the drive lever and the hook lever are separated. FIGS. 5A and 5B are cross-sectional views showing the operation of the embodiment of FIG. FIG. 6 is an exploded perspective view showing an embodiment using a cam mechanism. 7A to 7C are cross-sectional views showing the operation of the embodiment of FIG. FIG. 8 is a perspective view showing a part of an embodiment using a one-way clutch mechanism. FIG. 9 is a sectional view of the clutch cam shown in FIG. FIG. 10 is a cross-sectional view of a main part of the embodiment shown in FIG. 8 as viewed from the back cover side. 11 (A) to 11 (D) are cross-sectional views showing the operation of the embodiment shown in FIG. 8, respectively. FIG. 12 is a sectional view showing an embodiment in which the drive lever is swung by the cam mechanism and the engagement mechanism. 13A to 13C are cross-sectional views showing the operation of the embodiment shown in FIG. 12, respectively. 10… patrone 11… take-up spool 18… film feed member 18 a… feed claw 20… drive lever 22… spool cam 22 a… engaging part 41… hook 50… drive lever 52… spool Cam 52a Engaging part 54 Hook lever 56 Guide plate 68 Film edge detecting member 70 Film feed member 71a Feeding claw 73 Driving lever 74 Guide plate 95 Film Side edge detecting member 106 Drive lever 115 Clutch cam 116 Spool cam 120 Drive lever 122 Toggle spring 123 Plate spring 124 Hook lever 126 Spool cam 132 Film feed member 133 …… Guide grooves.

Claims (8)

(57) [Claims] 1. A film initial feeding device for feeding a film toward a take-up spool until the leading end of the film is wound around a take-up spool after loading of the patrone, comprising a feed claw engaged with a perforation at the leading end of the film. A film feeding member, an engaging portion formed at a position deviated from the center of the end surface of the take-up spool, and with the rotation of the take-up spool, engaging with the engaging portion to move the film feed member in the film feeding direction. When the drive lever for reciprocating and the feed pawl move toward the take-up spool, the feed pawl is displaced from an initial state retracted from the film path to a state projected to the film path, and in this state, the film It consists of guide means for moving along the path, and after the film tip is wound around the outer periphery of the take-up spool, The film initial feed device is characterized in that the initial feed of the film is terminated when the drive lever is pressed by the side edge of the film and retracted from the rotation area of the engaging portion. 2. The film initial feeder according to claim 1, wherein said drive lever intermittently reciprocates a film feeder. 3. The drive lever is engaged with the engagement portion within a predetermined range of one rotation of the take-up spool,
A hook for moving the film feed member to a position closest to the take-up spool; and, after the engagement between the hook and the engaging portion is released, the film feed member is moved to an initial position farthest from the take-up spool. 2. The film initial feeder according to claim 1, further comprising a return spring member. 4. A film initial feeder for feeding a film toward a take-up spool until a leading end of the film is wound around a take-up spool after loading of a patrone, comprising a feed pawl engaged with a perforation at the leading end of the film. A first position where the film feed member is furthest from the take-up spool and a state where the film feed member is closest to the take-up spool. A drive lever that reciprocates with the second position;
And a hook lever engaged with the engaging portion while the engaging portion provided on the end surface of the take-up spool moves by a predetermined angle in order to move the hook lever to the second position. A biasing means for returning the drive lever to the first position when the film is disengaged and a hook lever are provided integrally with the hook lever. A film side edge detecting member which is pressed by the side edge of the film and retracts the hook lever from the rotation area of the engaging portion to terminate the initial film feeding. 5. The film initial feeder according to claim 4, wherein the drive lever and the hook lever are integrally formed as one arc-shaped lever. 6. An initial film feeding device for feeding a film toward a take-up spool until the leading end of the film is wound around the take-up spool after loading of the patrone, wherein an engaging portion that engages with a perforation at the leading end of the film. A film feed member provided with a projection formed at a position deviated from the center of the end surface of the take-up spool, and a drive lever for contacting the projection and intermittently reciprocating the film feed member in the film feed direction. After the leading end of the film is wound around the outer periphery of the take-up spool, the drive lever is displaced by the side edge of the film to displace the drive lever, and the rotation range of the protrusion is provided between the drive lever and the take-up spool. A film side edge detecting member for retracting the film from the film. 7. A film initial feeding device for feeding a film toward a take-up spool until the leading end of the film is wound around the take-up spool after loading the patrone, wherein a cam rotatably disposed at an end of the take-up spool. A one-way clutch for interlocking the cam member with the take-up spool when the take-up spool rotates in the film winding direction, and disconnecting the cam member from the take-up spool when rotating in the film rewind direction; When the cam member rotates together with the take-up spool, the drive member includes a drive lever intermittently oscillated by the cam member, and a feed claw that engages with perforations at the leading end of the film. A film feed that reciprocates intermittently and feeds the film tip toward the take-up spool. After the leading end of the film is wound around the outer periphery of the take-up spool, the drive lever is pressed by the side edge of the film and retracted from the rotation area of the cam member, thereby completing the initial film feed. An initial film feeder characterized in that: 8. A film initial feeder for feeding a film toward a take-up spool until the leading end of the film is wound around the take-up spool after loading the cartridge, wherein the film is engaged with a perforation at the leading end of the film. A film feed member for intermittently transporting the portion toward the take-up spool, and a first position where the film feed member is connected to the film feed member via a leaf spring, and the film feed member is in a state farthest from the take-up spool; A drive lever that swings between a second position where the film feed member is closest to the take-up spool, a toggle spring for holding the drive lever at the first position and the second position, respectively, The drive lever is provided on the end surface of the take-up spool. When the drive lever is in the second position, the drive lever comes into contact with a part of the drive lever to move the drive lever to the first position. And a hook lever engaged with the projection when the drive lever is in the first position and disengaged from the projection when the drive lever is moved to the second position. After the leading end of the film is wound around the outer periphery of the take-up spool, the hook lever is pressed by the side edge of the film, the leaf spring is bent, and the hook lever is retracted from the rotation area of the projection, whereby the initial film feeding is completed. An initial film feeder characterized in that: