DE2460678C3 - Device for extending the exposure time for a film camera - Google Patents

Description

The invention relates to a device for extending the exposure time for a film camera with a rotary shutter and a reciprocating film transport claw.

A film reel drive for a film camera or a film projector is known from DT-Gbm 68 12 768, the take-up reel for the film does not have a conventional friction gear but a with the Film transport claw drives connected rack. The film transport claw is used to move past of the film on the exposure or projection window reciprocated in the vertical direction, with the Advance of the film a claw element of the film transport claw into the perforation of the film only when moving downwards the film transport claw engages. Before the subsequent upward movement of the film transport claw this is pivoted in a horizontal plane, whereby the claw element out of the perforation of the film is highlighted. Which can be brought into engagement with a drive gear of the take-up reel The rack is attached to the film transport claw so that it is when the film transport claw is pivoted then always comes into engagement with the gear for the take-up reel in the horizontal plane, when the claw element is lifted out of the perforation of the film. So it becomes a piece of the the film previously transported by the film transport claw is rolled up by the take-up spool when the Film is currently not being moved past the exposure or projection window. To their pivoting in the horizontal plane, the film transport claw has a cam scanner, which with a front cam in Engagement is, which is attached to the drive shaft for the rotary shutter. During a certain Rotational range of this end cam is therefore the claw element in engagement with the perforation of the Film, while it is out of engagement with the perforation in the rest of the rotation range of the front cam. the Film transparency claw also has an elongated recess extending in the horizontal direction on, in which an eccentric cam is guided, which is also from the drive shaft for the Revolving lock is driven. This eccentric cam has such a shape that in correct assignment to the respective rotary position of the front cam, the film transport claw in the vertical direction is moved up and down.

From DT-OS 20 55 976 a drive for a film transport claw is known, which is similar to in the previously explained known arrangement driven by the drive shaft for the rotary closure will. The cam scanner provided for the pivoting movement of the film transport claw in the horizontal plane is, however, displaceable on an actuating member with respect to the front cam acting on it arranged so that it is in relation to the respective rotational position of the drive shaft for the rotary shutter can be acted upon by parts of the front cam that are shifted by 18ö ° relative to one another. Through this it is achieved that the film transport claw with the help of this slidable cam scanner in its horizontal Level is swiveled so that it is at

the desired advance of the film during the downward movement the film transport claw engages in the perforation of the film and during the upward movement of the Film transport claw disengaged from the perforation while following a displacement of the cam follower for the desired return of the film during the upward movement of the film transport claw in the Is engaged with the perforation and disengaged during the downward movement of the film transport claw The perforation is In this way, the drive for the film transport claw can be reversed that both when the film is forwarded and when the film is rewound, a projection of the respective on film images passed through the projection window is possible. ,

From DT-PS 7 22 838 a rotary fastener is known in which the fan-shaped opening between two fastener sector parts can be changed with regard to its opening angle. For this purpose, a first sector is fastened in a rotationally fixed manner on a first shaft, while a second sector is fixed in a rotationally fixed manner on a second hollow shaft concentrically surrounding the first shaft. Both the hollow shaft and the first shaft are each connected to a gearwheel provided with helical teeth, into which a further gearwheel engages. These two further toothed wheels which are helically toothed in opposite directions, are located on a ^geme: nsamen shaft to move in the axial direction, whereby these against each other helical gears are shifted from the on the first shaft and the hollow shaft fixedly arranged toothed wheels , so that a mutual rotation of the first shaft and the hollow shaft takes place, whereby the two sectors are rotated against each other, so the opening angle between the two is changed.

From the DT-AS 11 83 365 a film projector is known in which the film transport speed can be changed. For this purpose, the part of the drive shaft for the rotary seal which is coupled to the drive motor is connected to the part of the drive shaft connected to the rotary seal via a releasable coupling. In parallel with the clutch, a back gear is provided which, when the clutch is released, connects the part coupled to the drive motor with the part connected to the rotary lock via a specific gear reduction ratio. Simultaneously with the shifting of the counter gear into its operative position, the cam scanner of the film transport claw is lifted out of the front cam connected to the drive shaft and the film transport claw is actuated by another front cam connected to the shaft of the counter gear via a further cam scanner. This ensures that with the effectiveness of the back gear and a lower rotational speed of the drive shaft for the rotary shutter, the film transport claw only comes into engagement with the perforation of the film during a relatively small rotation range of the rotary shutter, so that after a ω downward movement of the film transport claw for the Transport of the film one or more downward movements of the transport claw take place without, however, the feed being transported, since the film transport claw is not in engagement with the fi.s perforation of the film during this time.

If the exposure time in a film camera is to be extended, the opening area of the rotary shutter can be increased for this purpose. As a result of such an increase in the opening time of the rotary shutter, however, the closing time of the rotary shutter is reduced at the same time, so that the film must be transported more quickly by the film transport claw, since this transport must be completed within the closing time interval. In order to be able to achieve such a rapid downward movement of the film transport claw, triangular cams were used, which, however, cause a very sudden change in the acceleration of the film transport claw, whereby the image stability of the film suffers with a correspondingly large increase in the film speed.

The object of the invention is to provide a new device for extending the exposure time for a film camera to create, with which the opening angle of the rotary closure can be increased without however, due to sudden changes in the acceleration of the film transport claw, the image stability suffers.

In a device of the type mentioned, this object is achieved according to the invention by the characterizing features Part of claim 1 specified combination of features solved.

In the new device, a claw drive shaft is preferably driven by the drive motor provided which causes the up and down movement of the film transport claw. Depending on your choice, one certain transmission ratio of an adjustable transmission device between the claw drive shaft and a parallel to this arranged sector shaft for the rotary shutter rotates the latter with the same or a correspondingly reduced speed as the claw drive shaft. Since the front cam controlling the pivoting movement of the film transport claw is also located on the Sector wave is located, this also runs with a corresponding reduction of the speed of the Claw drive shaft with a correspondingly reduced speed. When reducing the speed of the The claw feed shaft to the speed of the sector shaft in a ratio of 2: 1 is therefore the film transport claw of of the claw drive shaft up and down twice during one complete revolution of the end cam moved downwards. So that the front cam pivots the film transport claw so that it z. B. during is in the position of engagement with the film perforation during the first downward and upward movement. at a downward movement of the film transport claw? during the first quarter turn of the forehead cam therefore, the film is also moved downward by engaging the claw member in the film perforation. The film transport claw is in place during the next quarter turn of the front cam still in the engaged position, but the film transport claw is now driven by the claw drive shaft moved upwards. However, since the claw element has an obliquely downwardly sloping upper side, the Film transport claw with its downward movement automatically as with a so-called free-moving one Claw lifted out of the perforation, so that the film transport during this upward movement steal no movement of the film takes place. During the two subsequent quarter turns de On the other hand, the front cam is the film transport claw in its no engagement in the perforation de Film enabling position, so that also with the subsequent downward movement of the film transport steal and the subsequent upward movement

the film transport claw no transport of the film occurs. This means that the film can only be transported during a quarter turn of the sector shaft and thus also the face cam and the sectors of the Revolving fastener instead. Since two sectors are arranged on the sector shaft, one of which is opposite the sector shaft is rotatable, the opening area formed with both sectors can also be changed will. This is preferably done simultaneously with an adjustment of the transmission ratio the gear mechanism. This ensures that when the exposure time is extended, Enlargement of the opening area of the rotary shutter at the same time as the actual film transport by the film transport claw to a smaller area of one complete revolution of the sector shaft is limited. Will the motor driving the claw drive shaft at different speeds designed to be adjustable, so can with an increase in the speed of the claw drive shaft by the motor by choosing an appropriate gear ratio of the gear mechanism to the sector shaft original speed of this sector shaft are maintained, whereby z. B. only the length of time for the actual film transport per revolution of the sector shaft is reduced, while the actual Image speed in frames / second is maintained. With the new device can therefore in very the exposure time can easily be extended without, however, affecting the image stability during transport of the film is impaired.

Further embodiments of the invention relating to the special design of the new device are specified in the subclaims.

An embodiment of the invention is shown in the drawings and will be described in more detail below explained. It shows

Fig. 1 is a perspective view of the new device,

F i g. 2 shows a longitudinal section through the in F i g. 1 shown device,

F i g. 3A is a graph showing the movement of the claw of the device, with the claw works in the usual way when filming,

Fig.3B is a graph showing the movement the claw of the new device shows, the claw working in the same way as!, ie when filming with extended exposure time occurs, and

F i g. 3C is a graph showing the movement of the cam follower used in FIG Device used claw control cam follows.

Reference is now made to Figs. 1 and 2, the details of the construction of the show new device for extending the exposure time in a film camera. A pair of wing-shaped, thin sectors 1 and 2 is mounted on a sector shaft 3. A sector 1 is rotatable on the sector shaft 3 mounted, while the other sector 2 is attached to this. On the sector shaft 3 there are two spur gears 4 and 5 mounted, which are axially displaceable on the sector shaft. One parallel to the Sector shaft 3 extending claw drive shaft 6 is provided with two gears 7 and 8, which on the Claw drive shaft are attached, have different numbers of teeth and are elongated in the axial direction. The claw drive shaft 6 is also provided at one of its ends with a spur gear 9 which meshes with a drive gear 11 of a drive motor 10 stands. In this way, the claw drive shaft 6 and the sector shaft 3 rotated by the drive motor 10 uniformly. At the other end of the claw drive shaft 6, an end plate 12 is attached with an eccentric pin 13. A claw element 14, which is substantially perpendicular to the shafts 3 and 6 and has a pawl 14a is so arranged and adapted to be moved up and down in the vertical direction, whereby it

ίο is guided along a guide rod 15. The claw 14a has a flat bottom and a sloping downwardly sloping top, as shown in FIG. 1 is shown. The claw member 14 is provided with a horizontally extending guide slot 16 through which the eccentric pin 13 passes in engagement with the slot so that the claw member 14 by the rotation of the end plate 12 with the eccentric. Pin 13 can be moved up and down. The guide rod 15 is attached to a fixed window plate 17 and guides the claw element 14 in the vertical direction. Furthermore, the claw element 14 can be pivoted horizontally around the guide rod 15. The sector shaft 3 is provided with a face cam 18, and the claw element 14 is provided with a cam scanner 19 in the form of a pin, which follows the face or side surface of the slirn cam 18. A leaf spring 20 serves to press the claw element 14 with spring force in such a direction that the cam scanner 19 is in contact with the end cam 18. Therefore, the claw member 14 is simultaneously moved up and down on the guide rod 15 and pivoted about the same, so that a film F is transported frame by frame. The film perforations formed in the film F to be engaged with the claw 14a are denoted by reference character Fp. The reference character A denotes the film window of the camera, and the reference character L denotes the optical axis of the taking lens or the objective lens of the film camera. The relationship between the movement of the claw 14a and the movement of sectors 1 and 2 is very similar to the relationship between the movement of the sector and the claw in a conventional film camera.

In the new device, the two sectors 1 and 2 can be adjusted relative to one another in the circumferential direction, so that the opening angle formed by them can be changed. Furthermore, the relationship between the movement of the claw 14a and the movement of the Sektpren 1 and 2 changed when that of

so the sectors 1 and 2 formed opening angles is changed.

The sector shaft 3 is also provided with an axially elongated, helical toothed, on the sector wel Ie attached gear 21 and another, ir

ss axially elongated, helical toothed tooth racer 22, which rotatably mounts on the sector shaft and is attached to the wing-shaped sector 1, which is rotatably mounted on the sector shaft 3. The elongated one Helical gear 22 is approximately accurate

constructed like the elongated, helical toothed rack 21, the only difference being that di < Opposite directions of the gears. The helical gears 21 and 22 on dci Sector shaft 3 are in engagement with two obliquely

(, s toothed gears 23 and 24. The helical gears 23 and 24 are firmly connected to one another via a shaft 25 with an incised section 25a. As FIG. 2 clearly shows, the Scktorwelli

3 has two wedges 41 and 51 which can come into engagement with grooves 4a and 5a of the spur gears 4 and 5, respectively. The Spur gear 4 or spur gear 5 transmits the rotation of the claw drive shaft 6 to the sector shaft 3 only when its groove 4a or 5a is in engagement with the key 41 or 51 of the sector shaft 3. Furthermore, the Sector shaft 3 with the claw drive shaft either via the spur gear 4 and the wide gear 7 or via the other spur gear 5 and the other wide gear 8 constantly connected. This means that at least one of the two spur gears 4 and 5 transmits the rotation of the claw drive shaft 6 to the sector shaft 3. One Switching device is used to switch the transmission of rotation from one wheel set to the other. In the embodiment shown, a manually operable switching lever 26 is used for switching the transmission between the gears 4 and 5. The switching lever 26 extends from the helical Gears 23 and 24 to the spur gears 4 and 5. One end 26a of the switching lever 26 protrudes into the cut portion 25a of the shaft 25 of the helical gears 23 and 24, and the other End 26 b of the switching lever 26 is provided with wide recesses 27 and 28, which to the Spur gears 4 and 5 fit. Between the end 26a of the switching lever 26 and the cut portion 25a and between the wide recesses 27 and 28 and the spur gears 4 and 5 there is play, so that the Rotation of the gears 23, 24, 4 and 5 is not prevented by friction. When the toggle lever is 26 in Slides axially along the shafts 3 and 25, the gears 23,24,4 and 5, which mesh with the gears 21, 22, 7 and 8 are moved in the axial direction. Due to the axial displacement of the gears 23, 24, 4 and 5 become the helical gears 21 and 22 in mutually opposite directions rotated so that sectors 1 and 2 change the opening angle they form, and becomes one of the Spur gears 4 and 5 separated from the wedge 41 and 51, while the other spur gear in engagement with the associated wedge is brought.

The sector shaft 3 is also provided with a control plate 45 which has a recess 45a. The control panel 45 is attached to the sector shaft 3, and the end 26b of the switching lever 26 is provided with a further recess 29 which can come into engagement with the control plate 45. Only if the recess 45a of the Control plate 45 is aligned with the recess 29 of the switching lever 26, the switching lever 26 can so be moved in the axial direction that an Axialbewe- ίο supply of the spur gears 4 and 5 is possible. The control plate 45 is used to ensure quick switching, by allowing the switching lever 26 to move in the axial direction only when the grooves 4a and 5a of the spur gears 4 and 5 are aligned with the splines 4t and 51 on the sector shaft 3.

The sector shaft is also provided at its end with a stop pin 30 in such a way that the Stop pin 30 is blocked by a locking lever 31 when the locking lever 31 is in its Spcrrstel- <« is located. The locking lever 31 is pivotably mounted on a pivot pin 22 and is of a Tension spring 33 pulled clockwise and normally held in its locked position, as shown in FIG. 1 is shown. The locking lever 31 has a bent section 31a on which a shutter release button 34 is attached can press, which overcomes the spring force of the tension spring 33. An electrical switch 35 is like this provided that it is closed by the locking lever 31 when the shutter release button 34 is on the locking lever 31 and turns it counterclockwise. The electrical switch 35 is connected to the drive motor 10 connected, so that the drive motor 10 for driving the device only runs when the shutter release button 34 is depressed.

In the case of the previously described and shown in FIGS. 1 and 2 construction shown is the relationship of the The speed of the sector shaft 3 is set to the speed of the claw drive shaft 6 to 1: 1 when the There is engagement between the spur gear 4 and the gear wheel 7, and set to 1: 2 when the engagement between the spur gear 5 and the gear 8. Therefore, the ratio of the speed is the Sector shaft 3 the transmission of the rotation through the spur gear 4 to the speed of the sector shaft 3 Transmission of the rotation through the spur gear 5 2: 1. When the switching lever 26 is moved so that the Groove 4a of the spur gear 4 is brought into engagement with the wedge 41 and that the spur gear 4 is the rotation of the Claw drive shaft 6 transmits to sector shaft 3, the helical gears 23 and 24 moved in the axial direction so that they are elongated in the axial direction, helical teeth Rotate gears 22 and 23 in opposite directions so that the relative position of one, Sector 1 attached to helical gear 22 with respect to the other sector attached to sector shaft 3 Sector 2 is changed. In the embodiment shown in the drawings are by Switching movement of the switching lever 26 from the spur gear 5 to the spur gear 4, the sectors 1 and 2 relative rotated by 70 ° to each other, the opening angle formed by the two sectors 1 and 2 of 230 160 ° is reduced.

When operating the described device for switching the exposure time in a film camera, the shutter release button 34 is depressed, thereby the locking lever 31 is rotated counterclockwise and the switch 35 is closed, so that the drive motor 10 energy is supplied. At the same time, the stop pin 30 is released so that the sector shaft 3 can rotate. Since the sector shaft 3 is connected to the claw drive shaft 6 driven by the drive motor 10 via a transmission device which comprises the gears 4 and 7 or 5 and 8, the sector shaft 3 begins to rotate driven by the drive motor 10, the driving force of which is transmitted to it via the gears 11 and 9 and the gear mechanism of the gears 4 and 7 or 5 and 8 is transmitted when the shutter release button 34 has been depressed. As a result of the rotation of the claw drive shaft 6, the claw element moves upwards and downwards, due to the engagement of the eccentric pin 13 attached to the end plate 12 of the claw drive shaft 6 with the horizontally extending slot K in the claw element 14 at the same time the Stimnocke 18, de sector 2 and the helical gear 21 attached to the sector shaft 3 rotated together. Due to the engagement between the wide, obliquely toothed gears 21 and 22 and the obliquely toothed gears 23 and 24, the wide «helical toothed wheel 22 and attached to it sector 1, both rotatable on the sector shaft
are mounted, with respect to the wide helical gear 21 and the sector 2 rotated.

During normal film operation, during which the sector shaft 3 is connected to the claw drive shaft 6 via the gear mechanism with the gears 4 and 7, the opening angle formed by the sectors 1 and 2 is set to 160 ° and is the ratio of the speeds of the two shafts 3 and 6 set to 1: 1. While with this setting the claw drive shaft 6 rotates 180 ° from the initial position (0 °) into the position after half a rotation (180 °), the cam scanner 19 of the claw element 14 follows the front cam 18 on its lower part, as shown in Fig. 3C, and the pawl 14 moves downward to advance the film F by one frame. During this process, sectors 1 and 2 close image window A of window plate 17, as shown in FIG. 3A. While the claw drive shaft 6 rotates a further 180 ° from the position after half a turn (180 °) to the position after a full turn (360 °), the cam scanner 19 follows the claw element 14 of the end cam 18 on its higher part, like this as shown in Fig. 3C, and the pawl 14a moves upward, returning to its original position without contacting or engaging the film F. During this retraction of the claw 14a, the sectors 1 and 2 open the image window A of the window plate 17, as shown in Fig. 3A, and expose the film F to the light entering through the lens of the film camera.

For filming with a longer exposure time, the switching lever 26 is moved in the axial direction along the sector shaft 3 and the spur gear 5 is brought into engagement with the wedge 51, so that the sector shaft 3 is connected to the claw drive shaft 6 via the gears 5 and 8. During the axial displacement of the switching lever 26, the helical gears 23 and 24 are moved in the axial direction so that they rotate the elongated helical gears 21 and 22 relative to each other so that the opening angle formed by the sectors 1 and 2 is increased. This movement increases the opening angle formed by sectors 1 and 2 from 160 ° to 230 °. The ratio of the speed of the claw drive shaft 6 to the speed of the sector shaft 3 becomes 2: 1. Therefore, the sector shaft 3 makes one revolution, while the claw drive shaft 6 makes two rotations. While the claw drive shaft 6 rotates through the first 360 ° and the claw 14a moves back and forth over a cycle, the end cam 18 rotates through 180 °, as shown in FIG. 3B and 3C is shown. When the claw 14a returns upward while the cam follower 19 follows the lower part of the end cam 18, the claw 14a is automatically released from the perforation of the film F because the end of the claw 14a is sloped as shown in FIG . 1 is shown. During this process, the claw 14a behaves like a so-called free claw. As the pawl 14a is returning upward, sectors 1 and 2 release the image window A of the window plate 17, as shown in Fig. 3B. Then the claw 14a moves up and down again during the further rotation of the claw drive shaft 6. During this reciprocation of the pawl 14a, the cam follower 19 follows the higher part of the end cam 18 so that the pawl 14a reciprocates without engaging with the perforation of the film F. During this process, sectors 1 and 2 keep the image window A open so that the film is exposed to the light entering through the taking lens, not shown, as shown in FIG. 3B is shown.

As can be seen from the above description, the switching of the Exposure time can be carried out in a simple manner by moving a movable toggle lever.

In the described embodiment, the following six combinations of the speeds of the Claw drive shaft and the sector shaft when using a drive motor with three different Speeds, namely 24, 36 and 54 revolutions per second, achieved:

Speed of the claw drive shaft

(Revolutions / second)

Rotation speed of the sector wave (image speed: 12

Frames / second)

opening angle (degree)

24 36 24 54 36 54 opportunity: 12 18th 24 27 36 54 230 230 160 230 160 160 For this 3 13UiIt Z ek'hnuiigen

Claims (4)

Patent claims: 1. Device for extending the i. nting time for a film camera with a Umlaui shutter and a film transport claw that can be moved back and forth, characterized by the combination of the following features: a horizontally pivotable and vertically displaceable claw element (14) with a claw (14a, /, which has a flat underside and an obliquely downwardly extending upper side, and a horizontally extending guide slot (16) and a cam scanner (19), a claw drive shaft ( 6) which has an eccentric pin (13) at one of its ends which engages with the guide slot of the claw element so that the claw element is moved up and down by rotation of the claw drive shaft,
a sector shaft (3) running parallel to the claw drive shaft, a first sector (2) attached to the sector shaft, a second sector (1) attached to a helical, elongated first gear (22), which is rotatably mounted on the sector shaft and together with the first sector delimits a wing-shaped or fan-shaped opening, a helical, elongated second gear (21) being attached to the sector shaft, the direction of the helical teeth being opposite to that of the first gear and two axially displaceable, firmly connected, helical third Gears (23, 24) with oppositely directed helical teeth, each meshing with one of the first and second gears, a face cam (18) which is concentrically attached to the sector shaft and whose face is in contact with the cam scanner (19) so that the Claw element is pivoted by the rotation of the sector shaft, an electric drive motor (10), to which one of the shafts (3, 6) is assigned for its rotation, an adjustable gear device (4, 7; 5, 8) for transmitting the rotation of the claw drive shaft (6) to the sector shaft (3) with different transmission ratios and a switching device (26), with which an axial displacement of the third gears and an adjustment of the transmission device can be carried out at the same time. 2. Apparatus according to claim 1, characterized in that the transmission device (4,7,5,8) has two on one of the claw drive or sector shaft (3,6) attached gears (7, 8) and two more Includes gears (4, 5) each meshing with one of the other two gears and optionally can be engaged with the other of the shafts. 3. Apparatus according to claim 1 or 2, characterized in that the one transmission ratio the gear mechanism (4, 7, 5, 8) 1: 1 and the fm other 2: 1 and that with the latter transmission ratio the claw drive shaft (6) executes two revolutions, while the sector shaft (3) executes one revolution. 4. Apparatus according to claim 3, characterized in (^ shows that the opening angle formed by the sectors (1, 2) is increased when the transmission device (4, 7, 5, 8) is switched from the transmission ratio of 1: 1 to the other transmission ratio of 2: 1.