DE931691C - Photographic central shutter with swinging sectors and escapement - Google Patents

Description

Photographic central shutter with swinging sectors and Escapement The invention relates to a photographic central shutter with oscillating Sectors (double lamellas) that rotate in the opposite direction of rotation after each exposure a sector ring are moved according to the set exposure time acts on the drive member of an escapement. The invention has the task basis, through the sector ring in its two directions of movement the inhibition to drive so that its inhibiting effect as possible in the area of the full sector opening falls. To this end, according to the invention on the escapement drive member for a drive finger od. The like. Of the sector ring a holding member attached that is mounted so that it can be oscillated between stops in both directions of movement, that the sectors are each in the middle of the escapement drive the maximum open position take in. According to one embodiment of the invention, this holding member can be double-sided Have cam surfaces to directly drive the sector finger to convert into a pivoting movement of the escapement drive member. But it can also according to a second embodiment of the invention, an additional clamping cam for Tensioning of a spring connected upstream of the escapement drive element can be provided with the advantage that the holding member now has the sector drive finger in the middle of the escapement drive path and up to End of the inhibiting effect can hold. While according to the first embodiment, the restrained movement of the sectors distributed over a symmetrical stretch on both sides of the point of maximum opening and therefore part of the exposure process when the .open and another part occurs when sectors are already partially closed again In the second embodiment, the inhibited sector movement time turns out to be a Stopping point in the middle of the escapement drive path.

Two embodiments of the invention are explained with reference to the drawings; it shows, in each case omitting the generally known functional parts of the photographic central shutter with oscillating sectors, FIG 3 the setting curves in front view, FIG. 4 in front view the position of the escapement parts after exposure has taken place with the escapement drive member returned to the initial position, FIG. 5 the movement phase following FIG .6. The next following movement phase with the drive finger falling from the escapement drive member, FIG. 7 a section CD through FIG. 4, FIG. 8 in the second exemplary embodiment the escapement in a front view, corresponding to FIG Inhibitor drive 9 in an enlarged view a section through the escapement drive element, FIG. 10 the escapement drive element in a front view, drawn enlarged, FIG. 12 shows the movement phase during a new exposure after the shutter has been released with the sector drive finger stopped in the middle position, FIG. 13 shows the movement phase following FIG.

The escapement according to the first embodiment (Fig. I to 7) consists from the escapement drive member i, hereinafter referred to as tooth segment i, a holding member, also referred to as Wippet, the impellers 3 and 4, escape wheel 5, anchor 6, anchor rocker 7 and the leg spring B.

A pin 14 is riveted into the toothed segment i. which one with the Setting curve i2a of an adjusting disk i2 interacts in a known manner. As can be seen from Fig. 3, the lowest position of the exposure time is "i second" assigned. After the exposure process, the leg spring 8, which on pushes the pin 14, the toothed segment is brought back into its initial position According to the setting of the curve i2a.

The type of closure on which this is based are double-armed, when Exposure process. Swinging sectors provided, but their direction of rotation changes with each subsequent locking process. The sector ring 15 carries a pin 16, the one with medium and long exposure times in connection with the escapement can kick. .

So that in both directions of movement of the sector ring 15 by its Pin 16, the toothed segment i receives a drive, is in the first embodiment the rocker: 2 provided. In Fi: g. i is the position of the parts immediately after one exposure. The sector ring 15 with pin 16 has just been countered the clockwise direction moves, and the toothed segment i is still in its end position; it was by the pressure of the pin 16 against the inclined surface 2a of the rocker 2 in brought this position. The driving force emanating from the finger 16 was thereby from the rocker 2 via the pin 26 attached to it, which is on the segment cutout ia struck, transferred to the segment. As soon as the pin 16 reaches the tip (Fig. 6) the seesaw 2 had reached, it fell off. Then came the sector ring 15 in Fig. I in its end position shown, where he only by his inertia and friction and that of the sectors was delayed.

The arrangement of the rocker 2 on the toothed segment i has the following reason. The phases of movement of the sector ring 15 are approximately as follows: First quarter of the Movement path: Free movement of the sector ring; Second and third quarters: Through the escapement delayed movement of the sector ring; Fourth quarter: Free movement of the sector ring.

Since the sectors are only completely in the middle position of the sector ring 15 are open, this position is only achieved after half the expiry time, whereby the half opening and closing of the sectors (first and fourth quarters of the movement path) for a short time, because there is no involvement of the inhibitor. To the z. B. the exposure time In this exemplary embodiment, it would be necessary to let the corresponding amount of light through "130 seconds" the actual exposure time can be increased somewhat, e.g. B. to 1/25 of a second because the exposure in the second and third quarters, d. h..bci not yet fully open and sectors that have not yet been fully closed again, i.e. with a reduced amount of light, he follows. However, this correction can be accepted because it is a comparative simple structure of the span. and drive elements i, 2 and 8. Through the Formation of the holding member for the drive finger 16 as a rocker 2, which is in the cutout i ° of the tooth segment can be taken along a bit empty by the drive finger, will cause the route the blocked sector movement symmetrically to the middle position, d. H. the maximum opening position.

From the position assumed at the end of an exposure process (Fig. i) the toothed segment i, driven by the leg spring 8, moves into its Starting position back (Fig. 4,), d. H. to: the stop of the pin 14 on the Curve 12a according to the respective setting. The segment i is then located back on standby.

When the shutter is released again, the sector ring 15 rotates again initially only hampered by the inertia and friction of the sectors, clockwise, namely until the pin 16 comes to rest on the inclined surface 20 of the rocker: 2 (Fig.5), where he turns the rocker counterclockwise around its bearing pin 14 to. takes with it to the stop at the cutout edge 1b. Now the speed is back delayed according to the setting time, since the sector ring controls the escapement via the Must drive segment i. Only when pin 16 is at the extreme tip of rocker 2 has arrived (Fig. 6), the sector ring can g again without additional delay keep walking and close the sectors.

The spring 8 must, of course, be so weak that they are fishy The escapement is driven by the force of the (not shown) drive spring of the Sector ring 15 can be overcome.

The stop pin 17 for the end of the leg spring 8 can be used as an eccentric be trained.

In the second embodiment (Fig. 8 to 13) is unnecessary Correction to the exposure time explained above by the fact that the drive finger 16 can move freely up to the middle position and during this middle position the inhibitor delay time is stopped in order to continue running freely at the end to be able to. The following facility has been set up for this purpose.

The Teilei to 7.12 and 15 to 17 are the same as in the first embodiment, only the toothed segment is constructed differently; it is labeled ioo. A clamping cam ioi is mounted on the same axis as the segment ioo. Furthermore, a rocker 1o2 is mounted on the segment ioo. A leg spring 104 is assigned to segment ioo and a leg spring 103 is assigned to clamping cam ioi.

Fig. 8 shows the same position of the locking parts as Fig. i: The drive finger 16 has just made a counterclockwise movement, is in its one end position, and segment ioo is also in a radial direction Direction still completely pivoted outwards. Then it is from the pen 1o4. returned to its initial position (Fig. ii).

As can be seen from FIG. 2, the drive finger 16 can reach its central position without delaying the inhibition mechanism, the stop pin 1o5 of the rocker 102 coming to a stop on the segment cutout iooa. On its way into this position, the finger i6 comes into contact with the clamping cam ioi, swings it outward and thereby tensions the leg spring 103. The end 103a of the spring 103 rests on a pin 1o6 of the clamping cam ioi.

The driving force emanating from the tensioned spring 103 drives the segment ioo and thus the escapement until at the end the segment with the rocker 102 reaches its outermost position (FIG. 13) and the rocker releases the sector ring pin 16. During the run-off ice of the segment ioo, the clamping cam ioi is held in the clamping position by the pin 16.

The rocker 1o2 is activated by a double-acting spring 107 when it is not touched held with the pin 16 in the middle position with respect to the cutout iooa. These The device should ensure that the rocker 1o2 from the Pin 16 is reliably detected. (Such a spring could also be used in the first embodiment ..) The spring 107 is with a: perpendicular Provided bent nose 107a, which for the purpose of their fixation in a groove io2a engages on the segment.

The edge io2b of the rocker 1o2, on which the pin 16 (Fig. 12) to Appearance comes, runs equidistantly curved to the pivot point of the segment ioo, see above that when the rocker moves outward, the pin 16 remains in its place, d. H. does not migrate around its central position in the opening or closing direction, until he can fall off the seesaw.

The rocker 1o2 is mounted on a bearing post 1o8 on the segment ioo. The post 1o8 has an extension ioSa, which corresponds to the pin 14. cooperates in the first embodiment with the curve 12c.

An approach io8b on the bearing post 1o8 (Fig. 9) moves in the one cut out in the clamping cam ioi. oval guide rail ioia. If the segment ioo is moved more or less outward by the setting ring 12, the clamping cam ioi is also moved, since the bearing post 1o8 with its attachment io8b carries the clamping cam ioi by resting against the cutout ioia. The complete outward movement of the de, s clamping cam and the tension of the spring 103 assigned to it then take place via the drive finger 16.

When rotating: the sector ring 15 is counterclockwise the finger 16 on the edge io, 2c of the rocker. This edge also runs in the same center to the pivot point of the segment ioo when the stop pin 1o5 is in contact with the cut-out edge ioob.

The spring 103 -must be stronger than the spring 104, because when driving of the escapement at the same time the spring 104 must be tensioned.

The spring end 1oq.a of the spring ioq. could also at the same time - with the end of the spring 103 be hooked on the pin 1o6. In this case, both springs would be released from the tension lever ioi stretched, and the spring 103 could be made a little weaker, i. H. approximately deliver the same torque as Feather 10q .. the advantage would be are in a .lower stress on the springs.

Claims (3)

PATENT CLAIMS: i. Photographic central shutter with swinging through Sectors (double lamellas), which in the direction of rotation reversing after each exposure of a sector ring are moved according to the set exposure time -acts on the drive member of an inhibiting mechanism, characterized in that on the escapement drive member (i, ioo) for a drive finger (i6) of the sector rin-ges (i5) a holding member (2, red) between stops in both directions of movement in this way swings mounted eats,. that the sectors are each in the middle of the escapement drive path take the maximum open position. 2. Central lock according to claim i, thereby characterized in that on the drive member (i) designed as a toothed segment of the A cam (2) is mounted so that it can swing as a holding member, the effective Drive surfaces (2a and 2c) extend at such angles that the drive finger (i6) on the sector ring in each drive direction the same way under: same Covered by friction. 3. Central lock according to claim i, characterized by arranging a clamping cam (ioi) for a spring force accumulator (1o3) in the area of the drive finger (i6) on the sector ring and one part of the drive element (ioo) forming the escapement gear with a holding element (1o2) for the drive finger and further characterized in that the spring force accumulator (1o3) switched on between the clamping cams (ioi) and the escapement drive element (ioo) is such that the drive finger after full tension of the energy storage device and full opening of the sectors by the holding element (io2): is caught.