DE1953329A1 - Front drive for photographic camera - Google Patents

Description

Before drive for photographic camera addendum to patent ... (Note P 19 38 622.2) The invention relates to a self-releasing front drive preferably for photographic cameras of the type as described in patent application P 19 58 622.2. The subject of this main application is a photographic camera with electronic shutter, which, in conjunction with an alternating film transport and recording lock and an inevitably wired flash cube socket, has a device in which a clamping lever is moved into a crank position during film transport by means of a friction clutch, which thereby releases a stop slide which blocks the film transport when the film is not inserted and initiates the blocking when the film is inserted, but this only takes place when the S t; opps slide finger enters the film perforation hole. Another nose of the clamping lever is used to operate the camera shutter. The clamping lever is mounted on a release slide and is shifted when the release is triggered in the direction of the release movement, whereby it is held in its clamped position by a fixed nose until the release point is reached, then the clamping lever can pass behind the nose and - driven by his spring - open the shutter. Cameras of this type without an electronic shutter are well known. So has z. B. the applicant has already shown in the patent applications P 12 67 969.5-51 and its additional application P 12 79 452.4-51 solutions for such cameras. This training Tours do not have any devices for self-release.

The aim of the present invention is to create a reliable and inexpensive forward drive for the camera concepts mentioned, which allows both the use of electronic locks according to the exemplary embodiment of the main application and the use of conventional locks according to the examples of the aforementioned applications P 12 67 969.5-51 and its additional application P 12 79 452.4-51. In order to achieve this goal, according to the invention, the previously stationary nose, which holds the tensioning lever in its tensioned position, is made displaceable in the direction of the trigger movement. For this purpose, a corresponding device is provided which, in the case of non-self-timer shots, leaves the nose in its place as before and thus the normal function of the shutter remains unchanged, while with self-timer shots the nose when depressing the shutter button is moved down by suitable means lin the same sense; and after reaching the trigger point - delayed by a mechanical or electronic escapement - returns to its starting position; and thus triggers the lock or releases the return of the clamping lever. For this purpose, the present invention has a transmission slide or lever, which controls a driver coupling via molded lugs, which establishes or removes the connection between the release slide and the movably mounted clamping mechanism slide and actuates another holding pawl that activates the release slide until the end of the lead mechanism holds its release position. In the following, the invention is explained in more detail with reference to an exemplary embodiment shown in the drawings.

It shows: FIG. 1 the front view of the board with the release slide, the clamping lever mounted on the release slide and the rest position as a dashed line of the escapement slide on the back of the board.

FIG. Ia shows a section along the line I-I of FIG. 1 with omission insignificant details.

Figure 2 shows the front of the board with the escapement, latch, self-timer switch and clamping lever in clamping position.

FIG. 2a shows a section along the line II-II of FIG. 2 with omission insignificant details0 Figure 3 in a rear view of the board with a Overall arrangement of levers and sliders.

FIG. 3a shows a side section along the line III-III in FIG omitting insignificant details.

FIG. 3b shows the rear view of the board with the inhibitor freewheel and bearing plate.

FIG. 4 shows the overall arrangement of the levers and slides in a front view before triggering with dashed line outlines.

FIG. 5 shows the overall arrangement of the levers and slides in a front view when the release slide is pressed down and locked, indicated by dashed lines PCB cracks.

Figure 6 shows the front view of an embodiment with electronic Inhibition mechanism, whereby according to the invention the already existing camera electronics of the shutter speed formation Is used.

Figure 6a shows the top view of an embodiment with electronic Inhibition.

Figure 6b shows the circuit for the embodiment with electronic Inhibition.

FIG. 6c shows the arrangement of the individual contacts with the letter designation.

FIG. 7 shows the arrangement of the indicator lamp for checking the recording angle.

In the figures, 1 is a board with the screw holes 2, 3, 4 placed on three mounting pins of the camera housing, not shown and is screwed there. The board 1 has to accommodate the release slide 31 the rectangular recess 9 and for guiding the release slide 31 the elongated holes 11a and 12 (Figures 1, 3b). For guiding a stop slide, not shown in detail 54 (Fig. 2, 1, 3b) serves the angular recess 13 and the adjacent tab 14 with the molded nose 15.

The board 1 also has the perpendicular rectangular recess 21a, the horizontally extending rectangular opening 23a and the recess 24a. On the left side, the board 1 (Figure 1) has a contact edge 25a and on the on the right side a delimiting edge 20. On the front (Fig. 1,2) are In the case of the circuit board 1, the threaded sockets 26a and 27a are also nested, which are screwed on the -Hemmserkplatine 28a serve. On the back of the board 1 (Fig. 3, 3b) are the threaded sockets 29a, 30a riveted in, which are used for screwing on the bearing plate 16a are provided. The release slide 31 has on its upper half 31 a, the through the rectangular plate recess 9 engages and thus on the back of the plate is (Fig. 1, la) the riveted bearing pin 32, the his part from the back of the board again. the elongated guide hole 12 protrudes and the clamping lever 64 serves as a bearing shaft on the front of the board. The other bearing pin 17a in the lower release slide half 31b forms in connection with the plate slot Ila, the second guide point for the release slide 31. In the middle part in the area the angled, the release slide 31 has a stop lug 22a against which the tensioning lever 64 under the action of the spring 79 when the lock is not tensioned supported (Fig. 1, 1a, 2). The release slide 31 is by the spring 40 in his Basic position held. The one mounted on the bearing pin 32 of the release slide 31 Clamping lever 64 has an integrally formed actuating lug 67 pointing upwards (Fig. 1), which is not shown in detail with a stop slide 54 and the cam of an intermediate gear, not shown, interacts (see main application P 19 38 622.2). Furthermore, the clamping lever 64 has a downwardly molded one Actuating lug 71, which has a stop lug pointing towards the board 1 at its end 72 with the associated lateral stop surfaces 73, 74, as well as those according to downwardly directed nose 75a and the stop edge 75. On the right side has the Clamping lever 64 then still the active lug 76 for actuating a not shown Shutter blade. The threaded bushing 26a on the front of the board serves at the same time a holding pawl 41 a as a bearing point (Fig. 1, 2).

The Etalteklinke 41a is under the action of a spring 43a, the ßie with its angled nose 44a against the actuating nose 47a of the transmission slide 46a drilskt and allows it to interact with it.

Furthermore, the holding link 41a is at its upper end to a latching pin 45a is formed with the connecting nose 22s of the release slide 31 cooperates (Figures 3, 4). The transfer slide 46a has next to the actuating nose 47a on his right end (Fig. 2) nor the active nose 48a, which cooperates with a driver coupling 34a.

At its left-facing guide arm 40a (Fig. 2, 4) engages the transfer slide 46a with the angled oblique flag 49a in an oblique slot 51a of the self-timer switch-on slide 50a. The transfer slide receives its guidance 46a through the actuating nose 47a, which is inserted into the rectangular cutout 23a engages and through the guide arm 40a, which is located in the circuit board recess 24a. The self-timer switch-on slide 50a is guided by the contact edge 25a of the board 1 (Fig. 2, 2a) and through the opening 53b in the side wall of the camera 53a, through which the Betåt ngsgriff8tück 52a of the switch-on slide 50a from the outside becomes attainable. The switch-on slide has at the upwardly directed end face 60a 50a has an integrally formed pin 61a, which after the switch-on movement has been completed an opening 62a of the camera top 63a next to a release button, not shown protrudes (Fig. 4, 5) and thus the camera user is clearly and perceptibly unmistakable indicates that the camera is in the "self-timer" position.

Experience has shown that this is very important, otherwise it is easy to do can that the forward drive remains switched on and a snapshot recording because of of the switched-on forward drive fails.

On the back of the release slide 31 in the upper half 31a (Fig. 3, 4) the driver coupling 34a is rotatably mounted at point 33.

The driver coupling 34a has an angled nose 35a, a stop nose 36a and the inclined surface 37a, which in a manner to be described in more detail with the SteiLoxzenter 85a cooperates. Furthermore, the Driver coupling 34a under the action of a spring 38a. The inhibition or forward mechanism consists of the Intermediate wheels 55a, 55bt 57a, 57b, the jamming wheel 58a, 58b and the jamming anchor 59a. In In the illustrated embodiment, the drive pinion 55a and drive wheel 55b are of the escapement on the back of the plate with the aid of a bearing plate 16a stored, which is screwed in points 29a, 30a (Fig. 3, 3a, 3b). The drive wheel 55b is connected to the drive pinion 55a via a freewheel spring 54a, so that the power is only transmitted in one direction.

Plan-the drive pinion 55a is in constant engagement with the wheel teeth 80a of the escapement slide 81a. The inhibiting mechanism slide 81a further engages with its angled nose 82a through the perpendicular rectangular recess 21a of the board 1 and thus protrudes into the area of action of the clamping lever 64 on the front side of the board. Furthermore, the escapement slide u1a has the recess 83a and is under the action of a spring 84a. A setting eccentric 85a is fastened in the bearing plate 16a and cooperates with the inclined surface 37a of the driver coupling 34a. According to the invention, the latch 41a and the driver coupling 34a are actuated by the transmission slide 46a by means of its lugs 47a, 48a. In the illustrated embodiment, the transfer slide 46a is actuated by an inclined slot 51a of a switch-on slide 50a. The mode of operation of the forward mechanism results as follows: If the switch-on slide 50a is moved to its upper end position in the direction of arrow A to turn on the self-release (Fig. 3, 4), the transfer slide 46a is moved to the right in the direction of arrow B via the inclined slot 51a pushed. By means of the transmission slide lugs 47a and 48a, the retaining pawl 41a and driver coupling 34a are released, so that the driver coupling 34a enters the recess 83a of the escapement slide 81a under the action of the spring 38a with the nose 35a, while the retaining pawl 41a moves under the action of the spring 43a first rests with the locking lug 45a against the stop lug 22a of the release slide 31. The camera is now ready to take a picture with a forward drive, provided that the clamping lever 64 is connected to the Vtransport related oeke 4Feeo of an intermediate wheel was rotated counterclockwise into its tensioned position (Fig. 2), as shown in the above-mentioned applications the driver coupling 34a down to the lower edge of the recess 83a of the escapement slide 81a (FIG. 4). The stop surface 73 of the stop lug 72 of the tensioning lever 64 has set itself behind the angled lug 82a of the inhibitor slide 81a. From this moment on, when the trigger is further depressed, the inhibiting mechanism slide 81a is carried along by the trigger slide 31 via the driver coupling 34a through the angular nose 35a; the spring 84a is tensioned in the process. About the iion- Toothing 80a, the drive pinion 55a is rotated, at the same time the freewheel 54a, 55a is effective, so that the wheels of the escapement are not set in rotation.

After the major part of the release path, the inclined surface 37a arrives with the adjusting eccentric 85a in contact and when the trigger is depressed further the driver coupling 34a with the angular nose 35a becomes through the sohrag surface 37a moved out of the recess 83a of the escapement slide 81a. (Fig. 5). The eccentric 25a is used to determine the time of the final step out of the Winkelease 35a adjust the recess 83a so that it timed exactly with the incidence of Holding pawl 41a behind the stop lug 22a of the release slide 31 coincides 0 When this moment is reached, the escapement slide 81a moves below the Action of the spring 84a to return to a starting position. At the same time begin each other to turn the wheels of the escapement, as in this direction of rotation the freewheel between the drive wheel 55a and the freewheel spring 54a is switched off.

Has the escapement slide 81a reached its starting position, what usually after six to seven seconds, the stop nose kicks in 75a of the clamping lever 64 above the angular nose 82a and the clamping lever 64 quickly - driven by the spring 79 - back to its starting position, Irobei he opens the shutter blade, not shown, by means of the active lug 76, which then is closed again by a spring built into the lock.

Another molded downwardly directed nose 75a can now shortly before reaching the clamping lever end position against the locking lug 45a of the retaining pawl 41a hit and thus cancel the lock of the release slide 31, 8o that this can return to its end position by the action of its spring 40. Since this, however with a certain shock happens, the unwanted shaking of the camera appears possible, this feature can also be dispensed with. In this Trap would have to operate the shutter with the self-timer again Switch-on slide 50a briefly returned to its starting position (no self-triggering) and then brought back to the position t "self-release" this movement, the holding pawl 41a is pressed into its basic position and gives with its Rastnaae 45a the release pin 31 free, which is under the action a spring 40 is moved back to its original position.

As can be seen, it is easily possible for aleo to use the forward drive to be switched on or off at any time.

Experience has shown that when taking pictures with the self-timer, "cut off" occurs Heads "," cut off legs "and" halved bodies "often lead to annoying error results, because the photographer taking into account by reducing the viewfinder image the distance between the camera and the location that it was after the Self-timer, to misjudgment of the real size of the image section tends. A simple and inexpensive additional device can alleviate this deficiency Self-timer cameras can be remedied. Namely - as FIG. 7 shows - a known per se lamp 5a arranged in the camera 6a. However, there is the lamp Bo in contrast to the known devices in a tube 18a, which is so dimensioned and inclined that the falling from the tube opening 19a Light cone 8a of the lamp 5a has such an angle that it is largely with the Recording angle 7a of the lens coincides or is slightly smaller.

The person to be photographed standing in front of the camera 6a, who sees the lamp S, is thus given the flexibility to stand within the taking angle 7a of the lens. In FIGS. 6, 6a and 6b, the execution of the advance mechanism is described as an electronic escapement for the use of already existing camera electronics for the formation of the shutter speed. According to this particularly advantageous embodiment of the invention, the escapement slide 81a is preferably made of non-conductive material, for. B. made of high-strength plastic such as acetal resin or the like and carries three switching sliding contact springs 90a, 91a, 92a, which interact with circuit paths of a circuit board 112, taking into account the electronic circuit known per se for controlling the shutter speed. For this particular embodiment of the lock with forward mechanism, it is expedient to place the horizontally lying printed circuit board 112 described in the main application P 19 38 622.2, arranged parallel to the direction of movement of a stop slide 54, now vertically, but still parallel to the direction of movement of the stop slide 54, so that in this arrangement a vertically lying printed circuit board 112a can carry out both the switchovers by the stop lever 54 and the switchovers by the escapement slide 81a and thus can be made in one piece. Of course, the inhibitor plate 26a as well as the Remmwerk gearwheels 54a to 58b and Remmanker 59a are omitted for the electronic forward mechanism. Instead, an electromagnet 93a is provided, which interacts with an armature 94a which is movably attached to an articulated lever 95a. The articulated lever 95a is rotatably mounted on the threaded rivet 30a and is coupled to the escapement slide 61a at point 96a via a pin-and-slot connection. In a modified embodiment, the holding magnet 93a could also be attached directly under the escapement slide 81a, so that the armature 94a fastened to the note slide 81a would be moved immediately into the area of attraction of the holding magnet 93a. According to the invention, the sliding contact springs 90a, 91a and 92a are inserted into the circuit for electronic shutter timing control known per se (Fig. 6a). The individual contacts of the springs 90a, 91a, 92a are marked with the letters A to H (Fig. 6c). The mode of operation of the arrangement is as follows: If the forward mechanism of the camera is not switched on, the inhibiting mechanism slide 81a is not taken along by the driver coupling 34a and remains in the rest position shown in FIGS. In this case, the switch GH, which is formed from the contact 92a, also remains closed. The switch DEF, consisting of the contact 90a, remains in the rest position in which the contacts ED are connected to one another and the switch ABC, formed from the contact 91a, maintains the behavior binding AB closed. Thus, the holding magnet, which is not shown here in the main application P 19 38 622.2, denoted by 95, for the shutter time control is connected to the electronic circuit. If, however, the self-timer switch-on slide 50a is actuated and the forward drive is switched on, when the release button is pressed, the inhibiting slide 81a is carried along in the manner already described and the switching springs 90a, 91a and 92a are moved approximately to the contact points A to H on the circuit board 112a half of the distance covered, the contact springs 90a and 91a have switched from contact ED to EF and A-3 to AC (Fig. 6c) and thus on the one hand a variable resistor 97a for setting the lead time and on the other hand the holding magnet 93a for the escapement in the electronic circuit included. The switch GH (contact 92a) is initially kept closed, so that the capacitor 98a, which is already in the circuit for the formation of the shutter speed, remains discharged. The switching path H is arranged so that the contact spring 92a leaves it at the moment when the driver coupling 34a disengages from the escapement slide 81a through the eccentric rivet 85a and the inclined surface 37a. From this moment on, the charging of the capacitor 98a begins via the variable resistor 97a and the voltage at the input of the monostable multivibrator rises until the electronic circuit causes the holding magnet 93a to be de-energized. Now the holding magnet 93a lets go of the armature 94a and the escapement slide 81a, pulled by the spring 84a, snaps back into its basic position. At the same time, its angled nose 82a releases the stop nose 72 of the tensioning lever 64 and allows it to return. At the same time, the clamping lever 64 actuates the locking lamella, not shown in detail, with its operative nose 76. While the escapement slide 81a is snapping back, the switching state required for the formation of the shutter speed is restored via the switching springs 90a, 91a and 92a, e.g. B. the discharge of the capacitor 98a via the switch HG, so that - when the angular nose 82a has reached its end position - the electronic circuit is again ready for the formation of the shutter speed. The present invention thus makes it possible, in an extremely cost-saving manner, to use the relatively expensive electronic components of the shutter position control also to establish the lead time of a self-timer.

Claims (7)

Claims Cl) Photographic camera with forward mechanism for self-release after Patent application P 19 38 622.2 characterized in that with self-timer exposures the Vlinkel- or retaining lug (82a) cooperating with a clamping lever (64)) of a Escapement slide (81a) by means of a coupling member (34a) of the triggering movement follows, moves out of its original active position and at the end of the release movement while at the same time locking the release slide (31) by means of a retaining pawl (41a) is delayed by means of a mechanical or electronic escapement and only then returns to its original active position, there the clamping lever (64) releases and thereby triggers the shutter with a delay. 2.) Camera according to claim 1, characterized in - that a common Transmission member (46a) is provided, which both the coupling member (34a) with the jig slide (81a) as well as the retaining pawl (41a) with the release slide (31) engages and disengages. 3.) Camera according to claim 1 to 2, characterized in that -with the transmission element (46a) or with the self-timer switch-on element (50a) directly or indirectly an indicator pin (61a) is connected, which is next to when the forward drive the release button protrudes from the camera housing (63a) and thus indicates to the user both optically and via his tactile sensation that the forward drive is switched on and / or that the display pin (61a) makes it visible in a suitable manner in the camera viewfinder that the camera is located is in the 'rSelf-triggering' position. 4o) Camera according to claim 1 to 3, characterized in that the Escapement slide (8pa) after reaching its lowest position by an electrical one Holding magnet (93a) is held directly or indirectly, which him after expiration lets go of an electronic time constant in order to then trigger the trigger cause. 5.) camera ~ according to claim 1 to 4, characterized in that on the movable escapement slide (81a) devices for electrical switching (9Oa, 91 a, 92a) are provided, which in connection with a circuit board (1; i2a) the electronic switching means already present in the camera for the locking function Switch on when switching on the feed mechanism and for the electronic escapement function make usable, the resetting of this switchover takes place automatically, when the Hemmlrerk slide (81a) returns to its rest position. 6.) Camera with a visible from the object, during the lead time luminous display lamp according to claims 1 to 5, characterized in that the lamp (5am) one through Tubular reflector or lenses (18a) emits bundled directed light cone (8a), which is arranged and dimensioned in this way is that its scattering angle corresponds to the recording angle (7a) of the lens, so that the person to be photographed only sees the lamp (5a) when they are is within the angle of view (7a) of the lens. 7.) Camera according to claim 1 to 6, characterized in that the scattering angle of the light cone (8a) by placing aperture masks or moving the lamp in its longitudinal axis the different shooting angles of telephoto or wide-angle lenses can be adapted or that by appropriately shaped aperture masks for single person shots a light beam with a small opening angle aimed precisely at the center of the image can be generated and for group shots a narrow strip of light at eye level across the width of the recording angle.