JPH0769566B2 - Film feeder - Google Patents

Description

TECHNICAL FIELD The present invention relates to a camera. More specifically, the present invention relates to improvement of a technique for loading a film, which is stored in a film container, which is also called a film cartridge or a film cartridge, into a camera.

[Conventional technology]

In the conventional camera, the cartridge chamber has only the function of accommodating the film cartridge.
That is, when loading a film, for example, the back cover is first opened and the film cartridge is stored in the cartridge chamber. Then, the user holds the film coming out of the film cartridge by hand and positions it in the path from the film outlet of the cartridge chamber to the film exposure section. After that, the film is loaded by manually operating the winding lever or by operating the automatic film winding device by closing the back cover or the like.

[Problems to be solved by the invention]

However, in the case of the above-mentioned conventional technique, the user has to set the film at a predetermined position or insert the film into the film outlet when loading the film, which makes the handling of the film cumbersome and troublesome. there were. This has existed in both a camera for manually winding a film and a camera equipped with an automatic film winding device.

An object of the present invention is to make it easier to load a film stored in a film cartridge into a camera.

[Means for solving problems]

The characteristic configuration of the present invention includes a winding shaft (Px) around which a film (F) is wound, and a holding portion (Pa) frictionally coupled to the film, and accommodates the film together with the winding shaft. A film container (P) for storing the film container in a state in which the tip of the film does not advance, and a winding shaft of the film container in the film container storage chamber. The drive shaft (18) to be engaged and the drive shaft are rotationally driven in the film winding direction (B) to wind the film into the film container, and the drive shaft is rotated in the film winding direction (A). By driving the film, the film is rotated in the winding direction (A) together with the holding part, whereby the tip of the film frictionally coupled to the holding part is removed from the film container storage chamber. It is characterized by having a drive means having a winding-sending mechanism for sending the vessel housing the outdoor.

Further, it is preferable that a film delivery port (6c) for guiding the leading end of the film from the inside of the film container storage unit to the outside of the film container storage unit is formed, and this film delivery port is wide on the film container storage chamber side. It is more preferable if the width is narrowed outward.

Further, it is preferable to further have a spool (29) so that the film is wound by the spool after the leading end of the film, which has passed through the passage for the film delivered from the film container storage chamber, reaches the spool. that time,
It is desirable that the winding speed of the film by the spool be higher than the feeding speed of the film by the winding / feeding mechanism.

[Action]

That is, when the film container is stored in the film container storage chamber, the film held by the holding unit rotates together with the holding unit due to the rotation of the drive shaft, and the leading end of the film is reliably sent out of the film container storage chamber. And so on.

Further, if the film delivery port is provided, the leading end of the film can be delivered more reliably. Further, if the shape of the film delivery port is narrowed outward, the delivery is more reliable.

On the other hand, if the spool takes up the film after it has been sent out and passed through the film passage, the feeding of the film is more reliable. At that time, if the winding speed by the spool is higher, the film is wound without slack in the film.

〔Example〕

 Embodiments of the present invention will be described below with reference to the drawings.

FIG. 2 is a perspective view from below of the camera (CA) according to the present invention.

This camera (CA) has a flash emission window (3), a viewfinder window (4), and a flash emission window (3) above (below in FIG. 2) a taking lens (2) provided in the center of the front surface of the camera body (1). A subject distance measuring window (5) that also serves as a subject brightness detecting light receiving window is provided.

A substantially circular opening (7) for the cartridge chamber (6) is formed at the end of the lower surface of the camera body (1). The film cartridge (6) is a film cartridge (JIS
The 135 type film cartridge (P) defined in 1) is stored with the side where the cartridge shaft (Px) projects upward (downward in FIG. 2). Then, a lid (8) for opening and closing the opening (7) of the cartridge chamber (6) is rotatably attached to the camera body (1) around the axis (x ₁ ) to close the lid (8). A locking lever (9) that locks in position is provided adjacent the opening (7).

The lock lever (9) is supported so as to rotate between a lock position for locking the lid (8) in the closed position and an unlock position. At the lock position shown in FIG. 1, the action part (9a) causes the camera (C
The normally open lock switch (S3) inside A) is closed. Also, the lock lever (9)
An O-ring (10), which is interposed between the body (1) and the camera body (1) to make the inside of the camera (CA) a watertight structure, is fitted to the shaft (9b) of the. A locking member for locking the lock lever (9) at the lock position may be separately provided.

An annular O-ring (11) is held on the inner wall of the lid (8), and when the lid (8) is in the closed position, the O-ring (11) is attached to the lid (8) and the camera body (1). By being located between and, the inside of the camera (CA) is kept watertight.

A shaft (8a) is provided upright on the inner wall of the lid (8), and a conical guide member (12) is rotatably supported at the tip of the shaft (8a). The guide member (12) engages with the cylindrical cartridge shaft (hereinafter referred to as the lower cartridge shaft) (Pxb) on the non-projecting side in a state where the film cartridge (P) is stored in the cartridge chamber (6). Accordingly, the film cartridge (P) is positioned in the radial direction.

Further, the shaft (8a) of the lid (8) has a rotation blocking plate (1
3) is rotatably provided. On the upper surface of the rotation blocking plate (13) in the figure, the film cartridge (P) stored in the cartridge chamber (6) with the lid (8) in the closed position.
The annular elastic friction member (1
4) is attached. Further, as shown in FIG. 3, on the lower surface of the rotation blocking plate (13) in the figure, there are sawtooth projections (13a).
Are formed.

On the other hand, a pair of leaf springs (15) are attached to the inner wall of the lid (8), and the free ends of the pair of leaf springs (15) are
Each of them elastically abuts a projection (13a) of the rotation blocking plate (13). And the rotation stop plate (13) is
The elasticity of 5) urges it upwards, and the tip of the leaf spring (15) contacts the upright surface of the protrusion (13a) to prevent it from rotating counterclockwise in FIG. It has become.

That is, when the film cartridge (P) is stored in the cartridge chamber (6), the force exceeding the frictional force between the elastic friction member (14) and the lower end surface (Pb) of the film cartridge (P) is exceeded. Unless added, it does not rotate in the film rewind direction.

As shown in FIGS. 5 (a) to 5 (c), the cartridge chamber (6) is formed in a substantially cylindrical shape, and the film cartridge (P) having the film pull-out portion (Pa) is connected to the cartridge shaft (Px). ) Has an inner diameter that allows it to rotate around. That is, if the inner diameter of the cartridge chamber (6) is [D ₁ ] and the distance from the center of the film cartridge (P) to the outermost edge of the film drawing portion (Pa) is [d ₁ ], then D ₁ > 2d ₁ is there.

Further, as shown in FIG. 4, at the top of the cartridge chamber (6), there are three guide levers (16), a cartridge detection pin (17), and a tubular side on which the film cartridge (P) projects. A drive shaft (18) that is engaged in the Patrone shaft (hereinafter, referred to as the upper Patrone shaft) (Pxt) and transmits the rotational drive to the Patrone shaft (Px) is provided.

The three guide levers (16) are arranged with their phases differing from each other by 120 ° in the circumferential direction of the cartridge chamber (6). Each of the guide levers (16) is raised by about 50 ° from the ceiling surface (6a) of the patrone chamber (6) to the standing position shown by the chain double-dashed line in FIG. 1 and the groove (6b) formed on the ceiling surface (6a). ) It is attached rotatably over a retracted position that goes inside. Then, springs (not shown) are respectively urged toward the standing position.

As the loaded film cartridge (P) is inserted into the inside of the cartridge chamber (6), the three guide levers (16) are connected to the upper end surface (Pt) around the upper cartridge shaft (Pxt).
While being pushed to the retracted position against the biasing force of the spring by abutting with, the tip of the pusher pushes the upper patrone shaft (Pxt) toward the center of the patrone chamber (6), and the upper patrone shaft ( Guide the drive shaft (18) into the Pxt). The number of guide levers (16) is not limited to three, but a film cartridge (P)
It is sufficient if the number is such that there is no hindrance to guiding the upper Patrone axis (Pxt) of (1) toward the center of the Patrone chamber (6).

The patrone detection pin (17) can be moved back and forth between a projecting position projecting from the ceiling surface (6a) of the patrone chamber (6) to the patrone chamber (6) and a retracted position retracted from the patrone chamber (6). Mounted on the spring (19)
Is urged toward the protruding position. The cartridge detection pin (17) is pushed by the upper end surface (Pt) of the film cartridge (P) inserted into the cartridge chamber (6) to move to the retracted position, and the normally open loading switch (S2) is closed. It is supposed to do.

The drive shaft (18) includes a protrusion (18a) and an upper cartridge shaft (P).
xt) plate (18b) with a width that can be engaged, and gear (G2
Cylindrical part (18c) that is fitted onto the transmission shaft (20) connected to 6)
Etc. Then, a pin (20a) provided on the peripheral surface of the transmission shaft (20) is fitted in a longitudinal hole (18d) formed in the cylindrical portion (18c), and the drive shaft (18)
Is configured so as to be slidable in the axial direction with respect to the transmission shaft (20) and rotate integrally with the transmission shaft (20). The drive shaft (18) is urged toward the film cartridge (P) side (lower side in the figure) by a spring (21). And the plate part (18b) is
By engaging a groove (not shown) in the upper Patrone shaft (Pxt), drive can be transmitted to the Patrone shaft (Px).

As shown in Fig. 5 (a) to (c), the camera (CA)
Inside the chamber, in addition to the cartridge chamber (6), the film transport roller (22) and the pressure contact roller (23) that make up the film transport mechanism (FT), the taking lens (2), the shutter (24), and the film exposure unit. (25), film crimping plate (26), film measuring sprocket (27), spool chamber (28), spool (29) incorporating motor (M), film guide lever (30), and battery (E) A battery room (31) for housing is provided.

A slit-shaped film delivery port (6c) is formed on the sidewall of the cartridge chamber (6) along the axial direction of the film cartridge (P). As shown in FIGS. 5 (a) to 5 (c), the film delivery port (6c) is formed so that the side of the cartridge chamber (6) is wide and the width becomes narrower toward the front, and the leading end of the film. To guide you. The film conveying roller (22) and the pressure contact roller (23) each have peripheral walls made of an elastic rubber material, and are arranged in the vicinity of the film outlet (6c). The film transport roller (22) is fixed to a shaft (22a) driven by a motor (M). The pressure contact roller (23) is rotatably supported and is in pressure contact with the film transport roller (22). Then, by rotating the film transport roller (22), the film (F) sandwiched between the rollers (22) and (23).
However, according to the rotation direction, they are conveyed in the left-right direction in the drawing.

Sprocket for film measurement (27) is film (F)
When the film is conveyed, it engages with the perforation of the film (F) and rotates, and as described later, it drives the film counter (39) and also the film (F) for one frame.
The one-piece switch (S5), which is closed when the transport of is completed, is operated. The guide lever (30) has a roller (30a) rotatably provided at its tip, is rotatably mounted around a mounting shaft (30b), and is rotated by a spring (not shown) so that the roller (30a) Are urged to elastically press against the peripheral wall of the spool (29). The guide lever (30) guides the tip of the film (F) reaching the spool chamber (28) so as to move around the spool (29) in the counterclockwise direction in the figure, and at the same time, to the spool (29). The wound film (F) is suppressed to ensure the wound film.

The photographing lens (2) is designed so that the lens drive device (not shown) automatically adjusts the focus of the subject based on the distance information to the subject detected by the distance measuring device (not shown). Is configured. Also, shutters (24)
Is a so-called program lens shutter that changes its aperture over time, and the exposure is automatically controlled by an exposure control device (not shown) based on the brightness information of the subject detected by a photometric device (not shown). Is configured to.

A pair of light shielding members (32) and (33) are provided on the sides of the film transport roller (22) and the pressure contact roller (23). The pair of light blocking members (32) and (33) are
Each of them is made of an elastic member such as rubber having a light-shielding property, and is attached in a posture in which tip portions thereof elastically abut each other. The pair of light shielding members (32) and (33) are provided on the lid (8).
The light leaking from the film delivery port (6c) of the cartridge chamber (6) with the film open is prevented from entering the film exposure section (25) and the spool chamber (28). . Therefore, even if the lid (8) is inadvertently opened while the film has not been rewound after taking a few frames, it is possible to prevent the film having been taken from being exposed.

In addition, on the surfaces of the light shielding members (32) and (33) that are in contact with each other,
The light blocking may be more surely performed by sticking a light blocking cloth such as a telemp.

Next, drive shaft (1) for the film cartridge (P)
8), film transport roller (22), and spool (2
The drive transmission mechanism that transmits the drive force from the motor (M) is described in 9).

As shown in FIG. 6, the gear (G1) fixed to the rotation shaft (Ma) of the motor (M) constitutes the reduction gear train (G1).
2), (G3), (G4), (G5), (G6), and (G7) are interlockingly connected to the gear (G8). The gear (G8) has
In the figure, a pair of upper and lower gears (G9) and (G10) are
It is fixed so that it rotates together with 8). The lower gear (G10) in the figure is a gear (G10) that rotates integrally with the spool (29).
11).

That is, the spool (29) is rotationally driven in the direction opposite to the rotation direction of the motor (M) by the rotation of the gear (G1) accompanying the rotation of the motor (M).

On the other hand, the upper gear (G9) in the figure that rotates together with the gear (G8)
Are gears (G12), (G13), (G14), (G15), (G1
6) is connected to the sun gear (G17) via. The planet gear (G18) that meshes with the sun gear (G17) is the sun gear (G1
The lever (3) rotatably supported by the rotary shaft (34) of (7)
It is rotatably attached to 5). This planetary gear (G
18), when the sun gear (G17) rotates in the direction A in the figure,
Move to the position that meshes with the gear (G19), and then the sun gear (G17)
When is rotated in the B direction in the figure, it moves to a position where it meshes with the gear (G20).

The gear (G19) is fixed to the drive shaft (22a) of the film transport roller (22), and the gears (G21) and (G2).
It is connected to the gear (G23) via 2). The gear (G23) is connected to the drive shaft (18) for the film cartridge (P) via the one-way clutch (36). The one-way clutch (36) applies its rotational force to the drive shaft (18) only when the gear (G23) rotates in the direction A in the figure.
To tell. On the other hand, the gear (G20) is connected to the gear (G26) fixed to the drive shaft (20) via the gears (G24) and (G25).

The operation of the drive transmission mechanism configured as described above will be described.

When the rotation shaft (Ma) of the motor (M) rotates in the B direction in the figure, the spool (29) rotates in the A direction in the figure, that is, in the direction in which the film (F) is wound. Also, the sun gear (G1
7) rotates in the direction of A in the figure, and the planet gear (G18) turns into the gear (G1
By meshing with 9), the film transport roller (22) rotates in the direction A in the figure, that is, in the direction of transporting the film to the spool chamber (28) side in cooperation with the pressure roller (23). Furthermore, the drive shaft (18) for the film cartridge (P)
Rotates in the direction A in the figure, and drives the cartridge shaft (Px) in the direction in which the film (F) is loosened.

As a result, the film (F) in the film cartridge (P) is conveyed leftward in the drawing by the film conveying mechanism (FT), passes through the film exposing section (25) and reaches the spool chamber (28), and the spool ( It is wound around the outer circumference of 29). At this time, the transport speed of the film (F) by the film transport mechanism (FT) is higher than the winding speed of the film (F) by the spool (29) and the loosening speed of the Patrone shaft (Px). It is configured.

On the other hand, when the rotation shaft (Ma) of the motor (M) rotates in the A direction in the drawing, the spool (29) rotates in the B direction in the drawing. Further, the sun gear (G17) rotates in the B direction in the drawing and the planet gear (G18) meshes with the gear (G20), so that the drive shaft (18) for the film cartridge (P) rotates in the B direction in the drawing. Then, the Patrone shaft (Px) is driven in the direction in which the film (F) is wound. The rotation of the drive shaft (18) in the B direction in the figure is transmitted to the gear (G23) via the one-way clutch (36), and further to the gear (G22) and (G21). G19), the drive shaft (22a) of the film transport roller (22) is driven to rotate in the B direction in the figure.

As a result, the film (F) wound around the spool (29) is conveyed rightward in the drawing by the film conveying mechanism (FT) and rewound into the film cartridge (P).

On the other hand, the film measuring sprocket (27) is configured to be driven by being engaged with the perforation of the conveyed film (F), as described above. The film measuring sprocket (27) is linked to a one-frame switch operating mechanism (38) and a film counter (39) via a sprocket operating mechanism (37).

The one-frame switch actuating mechanism (38) is linked to the shutter (24), and closes the one-frame switch (S5) when the exposure for one frame on the film (F) is completed, and the sprocket for film measurement is closed. (27) is driven to open the one-frame switch (S5) when the sprocket operating mechanism (37) detects that the winding of one frame of film (F) is completed.

The film counter (39) changes the display of the display device (40) according to the operation of the sprocket operating mechanism (37), and the initial hoisting switch operating mechanism (41) is used. Open and close (S4). The initial winding switch actuating mechanism (41) closes the initial winding switch (S4) until the film counter (39) detects the first frame of the film (F), and the film counter (39) The initial hoisting switch (S4) is opened when the first frame of (F) is detected.

Next, the motor drive circuit shown in FIG. 7 for driving the motor (M) for transporting the film (F) will be described.

In this circuit, (S1) is the main switch, (S2) is the loading switch shown in FIG. 1 which is closed when the film cartridge (P) is stored in the cartridge chamber (6),
(S3) is the lock switch shown in FIG. 1, which is closed when the lock lever (9) is in the lock position, and (S4) is closed until the film counter (39) counts the first frame from the initial state. Initial winding switch shown in Fig. 6, (S5)
Is a one-frame switch shown in FIG. 6 which is opened when the winding of one frame of film (F) is completed and is closed when the exposure is completed, and (S6) is a rewinding lever (not shown) rewinding. A rewinding switch that is closed when it is in the position, and (S7) is a rewinding completion switch (S7) that is closed when the rewinding of the film (F) is completed.

The motor (M) is connected to a battery (E) as a power source via a main switch (S1) and a pair of relay switches (RL1) and (RL2). Both relay switches (RL1),
(RL2) is a separate transistor (T1), (T2)
Is activated to connect the motor (M) and the power supply battery (E). Both relay switches (RL
When neither 1) nor (RL2) is in the operating state, both electrode terminals of the motor (M) are short-circuited and the motor (M) is stopped. And a pair of transistors (T
1), (T2) base has transistors (T3), (T4)
The collectors of are connected separately, and when the transistors (T3) and (T4) are in the "ON" state, the transistors (T1) and (T2) are in the "OFF" state, and the corresponding relay switch ( RL1) and (RL2) are deactivated.

One input terminal of the AND circuit (AN1) has a loading switch (S2), a lock switch (S3), a pull-down resistor (R
1) is connected to the connection point, and the other input terminal is connected to the connection point between the initial hoist switch (S4) and the pull-down resistor (R2). That is, the AND circuit (AN1) outputs an "H" level signal when all the three switches (S3), (S4), (S5) are closed.

One input terminal of the OR circuit (OR1) is an AND circuit (AN1)
, And the other input terminal is connected to the connection point between the one-piece switch (S5) and the pull-down resistor (R3). The output terminal of the OR circuit (OR1) is connected to the bases of the two transistors (T1) and (T4). That is, the OR circuit (OR1) receives the "H" level signal from the AND circuit (AN1) or the one-piece switch (S1).
When “5” is closed, it outputs a “H” level signal. As a result, the two transistors (T1) and (T4) are turned on, the relay switch (RL1) is activated, and the motor (M) is normally rotated.

The output terminal of the OR circuit (OR1) is connected to the inverter (IN
3) is connected to the base of the transistor (T5) via. This transistor (T5) is a constant current circuit (CC),
The capacitor (C1), the constant voltage circuit (CE), and the comparator (CP1) form a timer circuit.
The comparator (CP1) is a capacitor (C1) in the "ON" state.
When the charging voltage of the capacitor (C1) becomes higher than the voltage of the constant voltage circuit (CE) because the transistor (T5) that short-circuits the circuit continues to be "OFF" for a predetermined time, it outputs the "H" level signal. To do. The output terminal of the comparator (CP1) is connected to one input terminal of the OR circuit (OR2). The other input terminal of the OR circuit (OR2) is connected to the connection point between the one-piece switch (S5) and the pull-down resistor (R3) via the inverter (IN2). That is, the OR circuit (OR2) outputs the "H" level signal when the comparator (CP1) outputs the "H" level signal or when the one-frame switch (S5) is opened.

One input terminal of the AND circuit (AN2) is an OR circuit (OR2)
, And the other input terminal is connected to the output terminal of the AND circuit (AN1) via the inverter (IN1). And the output terminal of the AND circuit (AN2) is
It is connected to the base of the transistor (T3). That is,
The AND circuit (AN2) outputs an "H" level signal when the AND circuit (AN1) outputs an "L" level signal and the OR circuit (OR2) outputs an "H" level signal. To do. As a result, the transistor (T3) is turned on and the motor (M) is stopped.

On the other hand, the bases of the two transistors (T2) and (T3) are
It is connected to the connection point between the rewind switch (S6) and the pull-down resistor (R4). That is, when the rewind switch (S6) is closed, the two transistors (T2) and (T3) are both in the "ON" state, the relay switch (RL2) is activated, and the motor (M) is reversely rotated. To do. The base of the transistor (T4) is the rewind completion switch (S7) and pull-down resistor (R
5) is connected to the connection point with. That is, when the rewind completion switch (S7) is closed, the transistor (T4) turns "O".
The state becomes "N", and the motor (M) in reverse rotation stops.

The rewinding completion switch (S7) is provided for the film transport roller (22) and the pressure roller (23) in the transport path of the film (F).
It is provided in the vicinity of and. The film (F) is present at that position and is opened by contacting the film (F), and is closed when the film (F) is not present. The rewind completion switch (S7)
Instead of this configuration, for example, a film transport roller (2
2) The pressing roller (23) and the pressing roller (23) are both made of a conductive material, and when the film (F) does not exist, they are brought into contact with each other to be closed, and the film (F) exists between them. It may be configured to be opened by.

Next, each operation of the camera configured as described above will be described.

<1> Film loading operation As shown in FIG. 2, with the lid (8) of the patrone chamber (6) open, the film patrone (P) is placed in the patrone chamber (6) with the upper patrone shaft (Pxt) side first. ). At this time, the film take-out portion (Pa) of the cartridge (P) may be located anywhere around the cartridge axis (Px).

Further, in this camera (CA), a film can be loaded by a method different from the above method without touching the film cartridge (P). Next, it will be explained.

As shown in FIG. 8 (a), the film cartridge (P)
Is generally stored in the cartridge case (42) in a posture in which the upper cartridge shaft (Pxt) is positioned on the lid (42a) side. When loading the film, first, as shown in FIG. 8 (a), the camera (CA) is inverted to open the lid (8) of the cartridge chamber (6), and the cartridge case (42).
Remove the lid (42a). Next, as shown in FIG. 8B, the cartridge case (42) is inverted and positioned at the opening (7) of the cartridge chamber (6). As a result, the film cartridge (P) falls into the cartridge chamber (6) as shown in FIG.

In either method, when the lid (8) is closed, the film cartridge (P) is stored in the cartridge chamber (6) as shown in FIGS. 1 and 5 (a). At this time,
Even when the patrone shaft (Px) is inserted into the patrone chamber (6) with a slight inclination, the guide lever () is inserted as the film patrone (P) is inserted by closing the lid (8). The tip of 16) is the upper Patrone shaft (Pxt)
Is pushed toward the drive shaft (18) located in the center of the ceiling surface (6a) of the cartridge chamber (6), and the lid (8)
The guide member (12) attached to the lower part of the film cartridge (Pxb) is inserted into the lower cartridge shaft (Pxb) so that the film cartridge shaft (Px) stands upright with respect to the ceiling surface (6a) of the cartridge chamber (6). Posture is corrected.

Then, as shown in FIG. 1, with the lid (8) closed and locked, the elastic friction member (14) fixed to the rotation blocking plate (13) causes the biasing force of the leaf spring (15). Elastically presses against the lower end surface (Pb) of the film cartridge (P), and within the range of the frictional force between the members (P) and (14), the rotation prevention plate (13) and the film cartridge (P) Are integrally connected around the Patrone axis (Px). As a result, the film cartridge (P) has a serrated projection (13
Due to the engagement of a) with the leaf spring (15), only rotation in the direction A in FIG. 5 is allowed in FIGS.

The drive shaft (18) for the film cartridge (P) is inserted into the upper cartridge shaft (Pxt) and its plate portion (18b)
Engages with a groove in the upper Patrone shaft (Pxt), so that the rotational driving force can be transmitted to the Patrone shaft (Px). When the film cartridge (P) is inserted, the protrusion (18a) at the tip of the plate (18b) smoothly engages the groove in the upper cartridge shaft (Pxt) and the plate (18b) of the drive shaft (18). It is provided to match.

When the plate portion (18b) of the drive shaft (18) does not engage with the upper cartridge shaft (Pxt) when the film cartridge (P) is inserted, the drive shaft (18) is urged by the spring (21). Against the structure, it is pushed into the ceiling surface (6a) of the patrone chamber (6) and then engaged in the upper patrone shaft (Pxt) when the drive shaft (18) starts rotating. Has been done. In this state, the tip of the film (F) is in elastic contact with the inner wall of the cartridge chamber (6) by its own elasticity.

Further, in FIG. 1, when the film cartridge (P) is inserted, the cartridge detection pin (17) moves upward in the drawing against the biasing force of the spring (19), and the loading switch (S2) closes. Is made. Further, the lock switch (S3) is closed by rotating the lock lever (9) to the lock position. At this time, the main switch (S1) is assumed to be closed. Also, the initial hoist switch (S4)
Is closed because the film counter (39) is in the initial state.

Therefore, in FIG. 7, the AND circuit (AN1) and the OR circuit (OR1) output the "H" level signal, the transistor (T1) is in the "ON" state, and the motor (M) starts the normal rotation. To do. In this normal rotation, the film counter (39) detects the first frame of the film (F), and the initial winding switch (S4)
Is opened and the one-piece switch (S5) is opened.

5 (a) to (c) and FIG. 6, the spool (29) is rotated by the normal rotation of the motor (M), that is, the rotation shaft (Ma) rotating in the B direction in the figure. It rotates in the direction A in the figure. The planet gear (G18) is the gear (G1
9), and the film transport roller (22) and the drive shaft (18) rotate in the direction A in the figure.

By rotating the drive shaft (18) in the direction A in the figure, the cartridge shaft (Px) is rotated in the direction in which the film (F) is wound. That is, the drive shaft (18) that engages with the groove in the upper patrone shaft (Pxt) and the drive transmission mechanism for the drive shaft (18) cause the film patrone (P) in the patrone chamber (6) to move to the film (P). F) constitutes a cartridge rotation drive mechanism (PM) that rotates in the loosening direction.

Due to this rotation, the film (F) has a frictional resistance between the film (F) and the telemeter at the film drawing portion (Pa) of the film cartridge (P). Therefore, the rotation of the film cartridge shaft (Px) causes the film (F) to rotate. (P)
Inside, it spreads in the axial direction and comes into pressure contact with the inner wall of the film cartridge (P). In this state, the film cartridge shaft (Px), the film (F), and the film film cartridge (P) rotate integrally.

On the lower end surface (Pb) of the film cartridge (P), the first
As shown in the figure, the elastic friction member (14) urged by the leaf spring (15) is in contact with the elastic friction member (14), but the rotation prevention plate (13) and the leaf spring (13) are connected to the elastic friction member (14). 15) means that the film (F) can be rotated in the feeding direction, and the film cartridge (P) is the film (F).
At the same time, rotation starts in the direction A in FIG. With this rotation, the tip of the film (F)
The film transfer port formed in the patrone chamber (6) is moved in the direction A in the figure while being guided by slidingly contacting the guide surface (6A) formed on the inner wall of the patrone chamber (6). 6c).

Then, as shown in FIG. 5B, the leading end of the film (F) passes through the film delivery port (6c) and is inserted between the film transport roller (22) and the pressure contact roller (23). Be done.

That is, the film (F) is rotated around the axis along the cartridge axis (Px) by the cartridge rotation drive mechanism (PM) and the guide surface (6A) formed over almost the entire circumference of the cartridge chamber (6). A film insertion mechanism (FI) that is rotated to and inserted into the film delivery port (6c) is configured.

On the other hand, the film transport roller (22) is driven and rotated in the direction A in the figure, and the film (F) is transported in the left direction in the figure. Then, the film (F) is exposed to the film exposure section (2
5) and the film crimping plate (26) are passed to reach the spool chamber (28), and as shown in FIG. 5 (c), the spool (29) is moved along the guide lever (30) in the direction A in the figure. ).

As described above, the motor (M) rotates normally and the film (F)
When the film winding operation is performed, as described above, the speed at which the film (F) is unwound from the cartridge shaft (Px) by the rotation of the drive shaft (18) is set to
It is set to be slower than the transport speed of the film (F) according to 2) and (23). Therefore, the film (F)
As the winding operation of (1) proceeds, the initial looseness of the film (F) gradually decreases and eventually disappears.

After that, the film (F) wound around the Patrone shaft (Px) is forcibly released by the rotation of the film transport roller (22).
8) is rotated faster than the rotation speed of the gear (G23). However, as shown in FIG. 6, between the drive shaft (18) and the gear (G23), the gear (G23) rotates in the direction A in the figure, that is, the drive shaft (18) in the figure. Since the one-way clutch (30) that transmits only the rotation in the B direction is interposed, no inconvenience occurs.

Then, the sprocket for measuring film (27) starts rotating from the time when it is engaged with the perforation at the leading end of the conveyed film (F), and as described above, operates the film counter (39) and the one-frame switch. Activate the mechanism (38). When the film counter (39) detects the leading edge of the first frame of the film (F) based on the perforation count, the initial winding switch (S4) is opened, and then the first frame of the film (F) is changed to the film. Exposure unit (25)
When it is detected that the switch is located at, the one-piece switch (S5) is opened. As a result, in FIG. 7, the AND circuit (AN1) and the OR circuit (OR1) both output a signal of "L" level, the transistor (T3) is in the "ON" state, and the motor (M) is stopped. To do.

<2> Shooting operation and winding operation After the initial winding of the film (F) in the film loading operation of <1> described above is completed, the initial winding switch (S4) remains open and the AND circuit ( The output signal from AN1) maintains "L" level.

In this state, when a shutter release operation is performed by a release button (not shown), after the film (F) is exposed by the shutter (24), a single frame switch (S
5) is closed. Therefore, in FIG. 7, the "H" level signal is output from the OR circuit (OR1), the transistor (T1) is turned on, and the motor (M) is normally rotated.

As a result, in FIG. 6, the drive shaft (18), the film transport roller (22), and the spool (29) all rotate in the direction A in the drawing, and the film (F) moves to the left in the drawing. Be transported. At this time, the released shutter (24) is recharged by a shutter charging mechanism (not shown).

On the other hand, the film measuring sprocket (27) is driven by the conveyed film (F) to rotate in the direction A in the figure, and actuates the film counter (39) via the sprocket actuating mechanism (37). When the transport of one frame of the film (F) is completed, the one-frame switch (S5) is opened via the one-frame switch operating mechanism (38), and the motor is operated by the same operation as the film loading operation of <1> above. (M) stops.

<3> Film thrust detection operation During the film winding operation of <2> described above, the OR circuit (OR
While 1) is outputting “H” level signal, the output signal from the inverter (IN3) is “L” level.
The transistor (T5) is in the "OFF" state. Therefore, the capacitor (C1) is charged by the current from the constant current circuit (CC).

Then, even if the winding operation of the film (F) continues for a predetermined time (that is, a time that is usually slightly longer than the time required to wind one film of the film (F)), the one-frame switch (S5)
If is not opened, the charging voltage of the capacitor (C1) rises, becomes higher than the voltage of the constant voltage circuit (CE), and is inverted to the output signal “H” level of the comparator (CP1).
At this time, since the output signal from the AND circuit (AN1) is at "L" level, the gate of the AND circuit (AN2) is open, and the "H" level signal from the comparator (CP1) is at the OR circuit. It passes through (OR2) and is output from the AND circuit (AN2). Therefore, the transistor (T3) is turned on and the motor (M) is stopped.

This state is usually caused by the fact that the film (F) is not fed when shooting of all frames of the film (F) is finished or when trouble occurs. That is, the film measuring sprocket (27) is not driven, and the one-frame switch (S5) is not opened even after a lapse of a predetermined time.

On the other hand, during normal film transport, the output signal from the OR circuit (OR1) becomes "L" level by opening the one-frame switch (S5) within a predetermined time. Then, since the transistor (T5) is turned on via the inverter (IN3), the electric charge charged in the capacitor (C1) is discharged, whereby the capacitor (C1) is returned to the initial state.

<4> Film rewinding operation The film rewinding operation is set by the operation of the rewinding lever (not shown), and in FIG. 7, when the rewinding switch (S6) is closed, the transistor (T2) is turned on. It will be in the "ON" state, the relay switch (RL2) will operate, and the motor (M) will rotate in reverse. As a result, in FIG. 6, the drive shaft (18), the film transport roller (22), and the spool (29) all rotate in the direction B in the figure, and the film ( F) is conveyed to the right in the figure.

During the rewinding operation, the drive shaft (18) rotates to cause friction between the film (F) locked to the patrone shaft (Px) and the telempe of the film draw-out portion (Pa), whereby the film patrone ( P) itself receives a rotational force. But,
The elastic friction member (14) is in contact with the lower end surface (Pb) of the film cartridge (P), and the frictional force thereof is larger than the frictional force between the film (F) and the telem. The rotation blocking plate (13) to which the elastic friction member (14) is attached prevents the film (F) from rotating in the rewinding direction by the engagement between the protrusion (13a) and the plate spring (15). The film cartridge (P) does not rotate because it is blocked.

In other words, a patrone reverse rotation prevention mechanism (RI) for preventing the rotation of the film cartridge (P) during the film rewinding operation by the elastic friction member (14), the rotation blocking plate (13), and the leaf spring (15). Configured.

Therefore, the film conveyed rightward in FIG. 6 is rewound on the Patrone shaft (Px) which is driven and rotated by the drive shaft (18). When the film (F) is all rewound into the film cartridge (P), the rewinding completion switch (S7)
Is closed. As a result, in FIG. 7, the transistor (T4) is in the "ON" state, the transistor (T2) is in the "OFF" state, and the motor (M) is stopped.

In the previous embodiment, the drive shaft (1) that engages with the groove in the upper cartridge shaft (Pxt) is used as the cartridge rotation drive mechanism (PM).
8) has been explained. The specific structure of the cartridge rotation drive mechanism (PM) can be appropriately changed, and an example thereof will be described below.

As shown in FIGS. 9 (a) to 9 (c), the pair of support levers (51), on the ceiling surface (6a) of the cartridge chamber (6),
(52) is rotatably supported by the respective mounting shafts (51a), (52a). At the tips of both levers (51) and (52), patrone support rollers (53) and (54) are rotatably supported, respectively.

The support levers (51) and (52) are linked to the operation of the lid (8) of the cartridge chamber (6) through an interlocking mechanism (not shown), and when the lid (8) is in the open position. It is in the retracted position shown in FIG. 9 (a), and when the lid (8) is closed, it moves to the operating position shown in FIGS. 9 (b) and 9 (c).
When the support levers (51), (52) are in the operating position, the pair of patrone support rollers (53), (54)
Are each configured to laterally support the upper Patrone shaft (Pxt).

In the figure, (55) is a sun roller, which is supported by a mounting shaft (55a) and is linked to a drive mechanism (not shown) so as to be bidirectionally rotationally driven. This drive mechanism is almost the same as the drive mechanism in the previous embodiment shown in FIG. 6, and this embodiment has a sun roller (55) in place of the drive shaft (18) in FIG. You can think of it.

The mounting shaft (55a) of this sun roller (55) has a lever (5
6) is rotatably supported. A pair of planet rollers (57) and (58) are rotatably supported on both free ends of the lever (56). And both planet rollers (57),
Both (58) are frictionally coupled to the sun roller.

When the sun roller (55) rotates in the direction A in the figure, the lever (56) rotates to move the planet roller (58) to the outer periphery of the upper Patrone shaft (Pxt), as shown in Fig. 9 (b). Abut,
The rotation of the sun roller (55) is transmitted through the planetary roller (58) to rotate the patrone shaft (Px) in the direction A in the figure. On the other hand, when the sun roller (55) rotates in the direction B in the figure, the lever (56) rotates and the planetary roller (57) moves to the upper patrone shaft (Pxt) as shown in FIG. 9C. The sun roller (55) rotates around the outer circumference and the rotation of the sun roller (55) causes the planet roller (57) to rotate.
Is transmitted through the shaft and rotates the Patrone shaft (Px) in the B direction in the figure.

In this configuration, for example, as shown by the broken line in FIG. 9 (a), even if the upper Patrone axis (Pxt) is inserted at a position slightly off the center of the Patrone chamber (6), the lid (8) The support levers (51),
When the (52) moves from the retracted position to the working position, the upper patrone shaft (Pxt) is pushed toward the center position by the pair of patrone support rollers (53) and (54), and the film patrone (P). The posture has been corrected.

The lever (56) is biased by a weak force so as to stop at the position shown in FIG. 9 (a) when the sun roller (55) is not rotationally driven. Therefore, even when the upper patrone axis (Pxt) of the film patrone (P) inserted in the patrone chamber (6) is biased toward the sun roller (55), the sun roller (55) is driven and rotated. , Is pushed to the center by either planetary roller (57 or 58).

Next, still another embodiment will be described. In FIG. 10 and FIG. 11, the structure of the cartridge chamber (6) is different, and the cartridge rotation drive mechanism (PM) is configured to match it.

As shown in FIGS. 10 (a) to 10 (c), the inside diameter of the cartridge chamber (6) faces the outermost edge of the film drawing portion (Pa) of the film cartridge (P) through the center of the cartridge shaft (Px). It is formed to be slightly larger than the distance to the peripheral wall of the film cartridge (P). That is, the inner diameter of the cartridge chamber (6) is [D ₂ ], the distance from the center of the film cartridge (P) to the outermost edge of the film drawing portion (Pa) is [d ₁ ], and the tubular portion of the film cartridge (P) is If the radius of is [d ₂ ], then 2 · d ₁ > D ₂ > d ₁ + d ₂ . Therefore, the Patrone room (6)
Inside, the film cartridge shaft (Px) is eccentrically rotated with the rotation of the film cartridge (P).

Therefore, as shown in FIG. 11, a protrusion (59a) and a plate (59b) corresponding to the protrusion (18a) and the plate (18b) of the drive shaft (18) in the embodiment shown in FIG. A drive plate (59) having a bracket) is interlocked with the transmission shaft (20) in the embodiment shown in FIG. 2 via a transmission spring (60). In the free state, the transmission spring (60) stands upright and supports the drive plate (59). Meanwhile, the Patrone room (6)
With the loading of the film cartridge (P) into the cartridge, the drive plate (59) is elastically deformed as shown in FIG. 11 in a state of being engaged with the groove in the upper cartridge shaft (Pxt). The drive plate (59) is allowed to transmit the driving force to the cartridge shaft (Px) in a state of being eccentric with respect to the center of the cartridge chamber (6).

As a result, the film cartridge (P) is driven and rotated with the cartridge shaft (Px) being eccentric with respect to the cartridge chamber (6).

In this structure, the inside diameter of the cartridge chamber (6) can be reduced. In addition, by setting the inside diameter of the cartridge chamber (6) to an appropriate size, the cartridge shaft (Px) of the inserted film cartridge (P) causes the center (C) of the cartridge chamber (6) to be seen in a plan view. Can always be included.

That is, for example, by arranging the protrusion (59a) of the drive plate (59) almost at the center of the cartridge chamber (6), the film pull-out portion (Pa) can be located at any position around the cartridge axis (Px). Even when the film cartridge (P) is inserted in the state of being on, the protruding portion (59a) and the upper cartridge shaft (P
xt), the plate portion (59b) of the drive plate (59) smoothly engages with the groove in the upper Patrone shaft (Pxt).

In this way, Fig. 10 (a) shows the upper Patrone shaft (Px
The drive plate (59) is engaged with the groove in t). After that, the lid (8) of the cartridge chamber (6) is closed and the drive plate (59) is rotated in the direction A in the figure by the same operation as in the previous embodiment, the film cartridge (P) is moved to the cartridge chamber (P). 6) Rotate while eccentric from the center (C).

As a result, the leading end of the film (F) moves in the direction A in the figure while being guided by sliding contact with the inner wall (6A) of the cartridge chamber (6), and as shown in FIG.
leading to c). As the film cartridge (P) is further driven and rotated, the leading edge of the film (F) passes through the film delivery port (6c) as shown in FIG. (Not shown in Figure C)).

Fig. 12 shows the cartridge (P) during the film rewinding operation.
Reverse rotation prevention mechanism (RI) to prevent the rotation of the
FIG.

In this embodiment, the size and shape of the cartridge chamber (6) are the same as those shown in FIGS. 10 (a) to 10 (c). Then, a slit recess (6d) is formed in a part of the inner wall (6A) of the cartridge chamber (6), and the slit recess (6d) is formed.
A locking lever (61) is provided inside.

The locking lever (61) extends between a working position that projects into the cartridge chamber (6) shown by the solid line in the figure and a retracted position that retracts to the outside of the cartridge chamber (6) shown by the two-dot chain line in the figure. It is rotatably attached. Then, when the film rewinding operation is set, it is moved to the operating position in conjunction with the operation of the rewinding lever (not shown) linked to the rewinding switch (S6).

When the film rewinding operation is performed, the patrone shaft (Px) is driven in the B direction in the figure, so that the film patrone (P) itself also receives a force to rotate in the B direction in the figure. However, since the locking lever (61) in the operating position abuts the film pull-out portion (Pa), the clockwise rotation of the film cartridge (P) is blocked, and the film (F) is blocked.
Is smoothly rewound into the film cartridge (P).

On the other hand, the locking lever (61) is at the retracted position outside the cartridge chamber (6) when the film (F) is loaded or when the film (F) is wound up. In addition, this locking lever (6
The thickness of 1) may be about [1.0 mm], and the width of the slit recess (6d) required for its withdrawal may be about [1.0 mm]. In operation, it does not hinder the transfer of the film (F).

It is of course possible to apply the structure in which the locking lever (61) is provided to the patrone chamber (6) in the embodiment shown in FIGS.

In each of the above-described embodiments, in order to rotate the film cartridge (P) in the cartridge chamber (6), the upper cartridge shaft (Pxt) of the film cartridge (P) is rotated in the direction in which the film (F) is wound. Although the driving structure is shown, the lower patrone shaft (Pxb) on the opposite side may be driven in a direction in which the film (F) is wound and loosened.

Further, the film (F) is wound and loosened by the rotation of the patrone shaft (Px), and the film patrone (P) is rotated by the contact between the film (F) and the inner wall of the film patrone (P). The film cartridge (P) itself may be directly driven to rotate. As an example, although not shown, in the embodiment shown in FIG. 1, the fact that the elastic friction member (14) is in contact with the lower end surface (Pb) of the film cartridge (P) is used to prevent rotation. Board (1
It is conceivable that a disk is provided instead of 3) and the disk is interlockingly connected to the motor (M) via a wire or the like.

〔The invention's effect〕

As described above, in the camera according to the present invention, the film is rotated by the rotation of the drive shaft that engages with the winding shaft of the film container housed in the film container housing chamber, and the rotation causes the leading end of the film container to be housed in the film container. Delivered outdoors. At this time, since the film rotates together with the holding portion that holds the film by frictional coupling, the film is reliably delivered.

Therefore, when the film is loaded into the camera, the user does not need to set the film at a predetermined position or insert the film into the film delivery port, and simply store the film container in the film container storage chamber. Now you can easily load films.

Further, if the film delivery port is provided, the leading end of the film is guided to the delivery port and delivered more reliably. Further, if the shape of the film delivery port becomes narrower toward the outside, the delivery will be more reliable.

On the other hand, if the spool takes up the film after it has been sent out and passed through the film passage, the feeding of the film is more reliable. At that time, if the spooling speed is higher than the delivery speed, the film is wound without sagging.

[Brief description of drawings]

The drawings show an embodiment of a camera according to the present invention. Fig. 1 is a vertical sectional view of a cartridge chamber, Fig. 2 is an overall perspective view from below of the camera, Fig. 3 is a perspective view of a rotation blocking plate, and 4 FIG. 5 is a perspective view of the top of the cartridge chamber, FIGS. 5 (a) to 5 (c) are bottom views showing the internal structure of the camera, FIG. 6 is a perspective view of the drive transmission mechanism, and FIG. 7 is a circuit of the motor drive circuit. FIGS. 8 (a) to 8 (c) are schematic views showing the film loading operation, and FIGS. 9 (a) to 9 (c) are bottom views showing another embodiment of the cartridge rotation drive mechanism, and FIG. (A) to (c) are bottom views showing another embodiment of the cartridge chamber,
FIG. 10 is a sectional view showing a patrone rotation drive mechanism for the patrone chamber of the embodiment of FIGS. 10 (a) to 10 (c), and FIG. 12 is a bottom view showing another embodiment of the patrone reverse rotation preventing mechanism. (6) …… Film container storage room, (18) …… Drive shaft,
(FI) ... Control means, (P) ... Film container, (F)
……the film.

 ─────────────────────────────────────────────────── ─── Continuation of the front page Examiner Mitsunobu Machida (56) References JP 60-57334 (JP, A) JP 52-23566 (JP, B2) JP 51-13072 (JP, Y2)

Claims (6)

[Claims] 1. A winding shaft (Px) around which a film (F) is wound, and a holding portion (P) frictionally coupled to the film.
a) and a film container (P) for accommodating a film together with the winding shaft, and a film container accommodating chamber (6) for accommodating the film container in a state where the tip of the film does not advance, A drive shaft (18) that engages with the winding shaft of the film container in the film container storage chamber, and a film is wound into the film container by rotating the driving shaft in the film winding direction (B). ,
By rotating the drive shaft in the film winding loosening direction (A), the film is rotated together with the holding portion in the film winding loosening direction (A), whereby the tip of the film frictionally coupled to the holding portion is moved to the film holding direction. A film feeding device comprising: a drive unit having a winding / delivery mechanism for feeding the film from the container storage chamber to the outside of the film container storage chamber. 2. The film according to claim 1, further comprising a film delivery port (6c) for guiding the leading end of the film from the film container storage chamber to the outside of the film container storage chamber. Feeding device. 3. The film feeding device according to claim 2, wherein the film feeding port is formed so that it is wide on the film container storage chamber side and narrows toward the outside. 4. The film feeding apparatus according to claim 1, wherein said driving means further comprises a drawing means for drawing out the film fed from the film container storage chamber. 5. The drawing means includes a spool (29), wherein the film is wound by the spool after the leading end of the film delivered from the film container storage chamber and passing through the film passage reaches the spool. The film feeding apparatus according to claim 4, which is characterized in that. 6. The film feeding device according to claim 4, wherein the drawing speed of the film by the drawing means is faster than the film feeding speed of the winding / feeding mechanism.