JP2751234B2 - Film camera - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a film camera.

[Summary of the Invention]

According to the present invention, in a camera using a 35 mm-wide film having an enlarged effective photographing area, an appropriate amount of film can be supplied by detecting a film feeding amount by a predetermined detecting means.

[Conventional technology]

Currently, widely used photographic films are
Although it is a 35 mm film (System 135), its size and characteristics of the photosensitive material are specified by JIS and ISO.

FIG. 7 shows a part of the prescribed size (the tolerance is omitted), the width of the film (1) is 35 mm, and the facing distance of the perforation (2) for feeding the film (outside). Is 25 mm and the pitch of perforation (2) is 4.75 mm. A frame (3) is formed into a rectangle having a size of 24 mm in the width direction of the film (1) and 36 mm in the length direction of the film (1). ) Is 38mm, 8 times the pitch of the perforation (2).
It has been.

By the way, as a method for improving the image quality, particularly the resolution, of the film (1), the photosensitive material applied to the i-film is improved.

ii Increase the width of the film to make the pieces larger. Can be considered.

However, in general, the fineness of the particles of the photosensitive material, that is,
Since the resolution is inversely proportional to the film sensitivity, it is difficult to improve the image quality by the term i unless a new photosensitive material is discovered.

In this regard, according to the method of item ii, it is possible to improve the image quality with the current photosensitive material as it is, but since the width of the film becomes large, the camera becomes large and heavy, and various products are used. Does not match the current trend of miniaturization and weight reduction.

For this reason, it has been proposed by the inventor of the present invention to improve the image quality by using a film having the same width as the current 35 mm film as the film.

That is, in this case, the camera does not increase in size and weight. In addition, the equipment such as the current film production equipment and the processing equipment for photographed film can be used as it is, and the present equipment can be used in combination with the current 35 mm film equipment. For example, 35 mm wide film coated with photosensitive material
Equipment for cutting to a width of mm, standardized patrone manufacturing equipment, or equipment for winding the cut film into the patrone is automated and large-scale equipment, but these equipment must be used as they are. Can be.

In addition, post-shooting processes, ie, development, printing, and stretching, are automated, and all processing equipment is designed based on a 35 mm film width. Is not practical.

Therefore, it is practical to improve the image quality by setting the width of the film to 35 mm, which is the same as the current 35 mm film.

By the way, the current 35 mm film has a width of 35 mm, but the length of the frame in the width direction is 24 mm, and the effective shooting area is narrow. This is because the perforations (2) for the sprocket of the camera to feed the film are provided on both sides of the film (1).

On the other hand, with the advance of computerization in cameras, drive control by a motor can be performed with considerable accuracy, and it is possible to drive a film with sufficient accuracy without using a large sprocket and perforation as in the past. It was confirmed by experiments.

Therefore, it has been proposed by the inventor of the present invention that the perforations are removed from the 35 mm wide film and the length of the frame in the film width direction is increased to the position where the perforations exist. That is, by doing so, the effective effective photographing area can be enlarged by about 40%, and therefore the image quality can be improved accordingly.

That is, as shown in FIG. 8A, the width of the film (1) is 35 mm, which is equal to the current film width, and no perforation is provided.

The length of the frame (3), which is the effective shooting area, in the film width direction and the length in the film length direction are 30 mm and 40 mm.

Further, the pitch of the frame (3), that is, the feed pitch of the film (1) is 42.0 mm.

However, the size and pitch of the frame (3) correspond to the current television broadcasting system, and the aspect ratio of the frame (3) is 3: 4.

When dealing with HDTV (so-called high-definition), the size of the piece (3) is 30 as shown in FIG.
mm × 53.3mm, pitch is 57.75mm. The aspect ratio is 9:16.

Further, the above numerical values are for the full size, and for the half size, as shown in FIGS. C and D, the size of the frame (3) is 30 mm × 22.5 in the current television broadcasting system.
mm, the pitch is 26.2mm, and the size of the piece (3) is 30 when using HDTV
mm × 16.9mm, pitch is 21.0mm.

And a film having the above format (1)
Although not shown, is stored in the same cartridge (cartridge) as the current 35 mm film.

Therefore, if the length of the frame (3) in the film width direction is 30 mm as shown in FIGS.
1.25 of length 24mm in the width direction of 35mm film
As a result, image quality (resolution) is improved by 25%.

In addition, if the length of the frame (3) in the film length direction is also enlarged at the same ratio, 1.25 × 1.25 ≒ 1.56, which means that the image quality is improved by 56%.

Furthermore, when comparing the area per one frame, the current row: 24mm × 36mm = 864mm ² Figure 8 A: Since a 30mm × 40mm = 1200mm ^2, the area of one frame is increased by about 39%, i.e., about 39 % Improvement in image quality.

Furthermore, if the image quality is the same, the image can be enlarged even more.

Also, as shown in FIGS. C and D, even in the half size, the long side of the frame (3) is close to the current full size film width of 36 mm in the longitudinal direction, so that an image quality close to the full size is obtained. be able to.

Furthermore, the length of the frame (3) in the film width direction is 30.
mm, a 2.5mm non-shooting area can be obtained between the frame (3) and the two edges of the film (1).
As a result, it is possible to secure the flatness of the film (1) at the time of photographing and to read and write data.

Further, since it is not necessary to provide a sprocket for film feeding in the camera, the camera can be reduced in size and weight.

FIG. 9 shows another example of the pitch of the frame (3). In this pitch, the same effect as in the first format can be obtained.

[Problems to be solved by the invention]

As described above, the present invention relates to perforation (2).
This enables the film (1) to be fed at the correct frame pitch for the film (1) having no frame.

[Means for solving the problem]

Therefore, in the present invention, a detection roller which rolls on the film (1) is provided in the camera, and the film (1) is fed at a correct frame pitch based on the rotation amount of the detection roller.

[Action]

The amount of rotation of the film winding shaft is controlled based on the detection output of the detection roller, and the film (1) is set at the correct frame pitch.
Is fed.

〔Example〕

FIG. 1 is a partial cross-sectional view of an example of a camera according to the present invention, in which a plane parallel to a bottom surface in a dark box portion of the camera is a cross section. FIG. 2 is a rear view with the back cover removed.

The center of the body (11) is a dark box (12), and a lens (13) is provided in an opening in front of the box (12). The inside of one side of the body (11), the left side in the figure, is a patrone storage section (14), and a film supply shaft (15) is provided above the patrone storage section (14). The cartridge (5) containing the above-mentioned film (1) is set so as to perform the above operation.

Further, a film winding shaft (16) is provided on the other inner side of the body (11), that is, on the right side in the figure. The winding shaft (16) is driven by a motor, which will be described later, to wind the film (1). On the peripheral surface of the winding shaft (16), for example, as shown in FIG. A high friction material (17) is coated, and, for example, three film guides (18A) to (18C) are provided around the winding shaft (16).

The guides (18A) to (18C) are linear in a direction parallel to the center axis of the hoisting shaft (16), and arc-shaped in a direction perpendicular to the center. Then, as shown in FIG. 4, one end of the guides (18A) to (18C) on the arc side is connected to the shaft (181).
The shaft is supported by the body (11) by the torsion spring (182), and the other end is wound by the winding shaft (1).
6) to be pressed against. In addition, the guide (18
Film holding rollers (10A) to (10C) are axially supported at ends of the winding shaft (16) of A) to (18C) so as to be parallel to the center axis of the winding shaft (16).

Then, as shown in FIG. 4, the peripheral surface of the roller (10A) is coated with a high friction material (101), and the roller (10A)
The diameter of the roller (10
Part A) includes a permanent magnet (3
1) is integrated, and the guide (1) is opposed to this magnet (31).
8A) is provided with a Hall element (32).

The opening behind the dark box (12) has a rectangular opening (aperture) of, for example, 30 mm (film width direction) × 40 mm (film length direction) corresponding to the frame (3) of the film (1). (19). However, the opening (19)
Since the light reaching the film (1) from the lens (13) is not a parallel light beam when it is photographed without being in close contact with the film (1), the frame (3) of the film (1)
If the size of the opening is 30 mm x 40 mm, the size of the opening (19) is
Slightly smaller than 30mm x 40mm.

Further, behind the dark box (12), on both sides of the opening (19) in the film width direction, along the opening (19),
A pair of film guide rails (21) are provided in parallel over at least the area of the opening (19).

The viewfinder, aperture, shutter, and the like are configured in the same manner as a current camera. Further, a film feed amount detection circuit as shown in FIG. 5, for example, is provided.

According to such a configuration, at the time of shooting, the patrone (5)
Is set in the storage section (14), and the film (1) reaches the winding shaft (16) from the patrone (5) through the opening (19). At this time, the film (1)
Is pressed against the winding shaft (16) by the film guides (18A) to (18C) and the pressing rollers (10A) to (10C), so that when the winding shaft (16) rotates, the film (1) is wound. The film (1) will be fed without perforations, ie, wound on the shaft (16).

When the film is fed, the roller (10A) and the magnet (31) rotate in response to the feeding of the film (1), and the rotation of the magnet (31) is detected by the Hall element (32). The amount of rotation of the hoisting shaft (16) is controlled based on the detection output.

Therefore, the film (1) is fed at the pitch of the frame (3) corresponding to the format.

 FIG. 5 shows an example of a film feed amount detection circuit.

In this case, if the pitch of the piece (3) is the numerical value described in FIG. 8, these values are as follows: 42.0 mm = 5.25 mm × 8 57.75 mm = 5.25 mm × 11 26.25 mm = 5.25 mm × 5 21.0 mm = 5.25mm × 4, which is an integral multiple of all 5.25mm, and 5.25mm = π × 3.34mm / 2. Therefore, the feed amount of the film (1) is only required to detect the integer number of rotations of the detection roller (10A) by setting the diameter of the detection roller (10A) to 3.34 mm, and the resolution can be reduced to 1/2 rotation in any case.

Also, in the case of the pitch of the piece (3) in FIG. 9, 44.0 mm = 6.28 mm x 7 56.5 mm = 6.28 mm x 9 25.1 mm = 6.28 mm x 4 18.8 mm = 6.28 mm x 36.28 mm = π x 4.00mm / 2, the number of rotations of the detection roller (10A) becomes an integer number of times, and the resolution becomes 1/2 rotation.

Therefore, the diameter of the detection roller (10A) is 3.34mm or 4.0
mm, and the magnet (31) is of a bipolar donut type as described above.

Accordingly, a detection voltage Ea as shown in FIG. 6A which changes in accordance with the rotation of the magnet (31) is taken out from the Hall element (32), and this voltage Ea is supplied to the voltage comparison circuit (33). As shown in FIG. 7B, the square wave voltage Eb having a period corresponding to the rotation of the magnet (31) is integer-numbered, and this voltage Eb is supplied to the differentiating circuits (34A) and (34B), as shown in FIG. The falling differential pulse Pa and the rising differential pulse Pb are extracted.

Then, these pulses Pa and Pb are supplied to the voltage comparison circuit (35), and as shown in FIG. D, one pulse is generated every half cycle of the voltage Ea, that is, every half rotation of the magnet (31). One pulse Pd is taken out and supplied to the system controller (34).

The system controller (36) is used to set the operation of the entire camera, for example, the aperture value and the shutter speed. Each time the roller (10A) of the guide (18A) rotates once, the film (1) is Since it is fed by 5.25 mm or 6.28 mm, the drive motor (38) of the winding shaft (16) is driven through the drive amplifier (37) so that the number of pulses Pd becomes a count value corresponding to the size of the frame (3). ) Is controlled. For example, if the pitch is 42 mm, the film (1) is fed until eight pulses Pd are obtained.

Therefore, the film (1) is fed at the pitch of the frame (3) corresponding to the format described above.

Thus, according to the present invention, even if the film (1) does not have the perforation (2), the film (1) can be fed at a correct frame pitch. In this case, since the magnet (31) for detecting the feed amount of the film (1) may be a dipole magnet, the cost is very low. Further, since both the rising point and the falling point of the obtained voltage Eb are counted and used for detecting the feed amount of the film (1), even if the magnet (31) is a bipolar magnet, the detection and detection are performed. The resolution when the roller (10A) detects the feed amount of the film (1) can be reduced to 1/2 rotation.

Further, when the diameter of the detection roller (10A) is small,
When the slip between the film (1) and the roller (10A) increases, the detection accuracy decreases. On the other hand, when the diameter of the roller (10A) is large, the roller (10A)
Requires a large torque when feeding, and the slip also increases to lower the detection accuracy.
If the diameter of A) is as described above, the feed amount of the film (1) can be appropriately detected without such a problem.

In the above description, the film (1) may be either a positive film or a negative film. It is also possible to write photographic data or the like in a non-effective photographic area between the edge of the film (1) and the frame (3), or record data indicating the standard of the film (1) in advance. it can. Further, the Hall element (32) can be provided on the back cover or the pressure plate (23).

H According to the present invention, the film (1) can be fed at a correct frame pitch even if the film (1) does not have the perforation (2). And in this case, the film (1)
Since the magnet (31) for detecting the feed amount of the magnet may be a dipole magnet, the cost is very low. Also, the obtained voltage
Since both the rising and falling points of Eb are counted and used to detect the feed amount of the film (1),
Even if the magnet (31) is a bipolar magnet, the detection roller (10
A) The resolution when detecting the feed amount of the film (1) can be reduced to 1/2 rotation.

Further, when the diameter of the detection roller (10A) is small,
When the slip between the film (1) and the roller (10A) increases, the detection accuracy decreases. On the other hand, when the diameter of the roller (10A) is large, the roller (10A)
Requires a large torque when feeding, and the slip also increases to lower the detection accuracy.
If the diameter of A) is as described above, the feed amount of the film (1) can be appropriately detected without such a problem.

[Brief description of the drawings]

1 and 2 are a sectional view and a rear view showing an example of a camera according to the present invention, FIGS. 3 and 4 are exploded perspective views of essential parts thereof, and FIG. 5 is a connection diagram of an example of a detection circuit thereof. 6 to 9 are views for explaining the present invention. (1) is a 35mm film, (3) is a piece, (5) is a patrone, (12) is a dark box, (16) is a film winding axis, (2)
1), (22) are film guide rails, (24) are rails, (31) are permanent magnets, (32) are Hall elements, (33),
(35) is a voltage comparison circuit.

Claims (1)

(57) [Claims] 1. A roller which abuts on one surface of a film and rotates according to the feeding of the film, a magnet provided on the roller, and a hole for detecting a change in magnetic flux which changes due to the rotation of the magnet. A film-type camera comprising: an element; detecting a rotation of the roller based on a change in voltage generated in the Hall element; and using the detected output as a frame feed control signal for the film.