DE1282441B - Photographic shutter with oscillating sectors and electronic exposure time formation - Google Patents

Description

Photographic shutter with reciprocating sectors and electronic exposure time formation sector driving part for the duration of the time formation of blocking controls locking bolt, wherein the sector drive a retarding the opening movement, serving for compensation of time constants of the mechanical lock - is allocated means.

With closures of the above type with one the opening and closing movement of the sectors causing the mainspring the timing is done in such a way that the shutter drive in a position corresponding to the open position of the sectors blocked by means of an electromagnetically releasable lock and the latter in dependence is released again by an electronically formed time interval, whereupon the drive spring closes the sectors again. This can preferably be done by training the lock be made in such a way that the lock drive is not driven by the armature itself, but is intercepted by a special locking bolt, which in turn from the sloping The magnet armature is operated after the magnet coil has been de-energized. This stands for the magnet armature under the action of a return spring influencing it in the direction of release, which, however, must be weaker than the holding force of the magnet, so that in the tension state the magnet coil held the armature against the action of the spring on the magnet core in contact will. In this way of working, the lock cannot be released immediately take place in which the magnet is de-energized, but only a few milliseconds after this point in time. The reason for this is to be seen in the fact that the magnet armature and the locking bolt must cover certain distances before the latter on blocked shutter drive part, for example the sector drive ring, except Intervention is coming.

To despite the aforementioned, between the de-energization of the magnet and a time interval existing by a photoresistor becomes ineffective controlled continuous and automatic exposure time formation following a geometric series to achieve, one already has the arrangement of one of the compensation of time constants proposed the mechanical locking device serving. This enables with the shortest, i.e. exclusively dependent on the mechanical lock drive Exposure time, e.g. B. 1 / äoo second, a sequence completely unaffected by the lock of the shutter drive, as the start contact, which is decisive for the timing, is through the delay effect of the compensation mechanism so early in relation to the achievement the fully open position of the shutter is closed that at full opening the sectors of the magnet armature has already fallen and thus the locking bolt on prevents falling into the shutter drive.

But it has now been shown that even with the use of a compensation mechanism of the type mentioned above, the goal set, namely to ensure a certain continuity in the time formation process, could not be achieved with ultimate consequence. This is especially not the case with the shortest exposure times of about Him sec, where, despite the continuous exposure time formation to be expected from the automatic control, a certain discontinuity occurs in this time range due to the fact that there is no intermediate time, for example between 1.fam and 1 / 2.5o sec, but alternatively either 1 / noo sec or 1 / 25o sec is achieved. When examining this phenomenon, the cause was found to be that certain deviations occur in the movement time of the locking mechanism consisting essentially of magnet armature and locking bolt, depending on whether the locking bolt is loaded or unloaded by the lock drive before the lock is released. It has been shown that if the locking bolt is loaded by the lock drive, the restoring movement of the locking parts takes more time until the moment of inactivity than in the case in which the parts can move without prior loading by the driving force. This is due in turn to the fact that in the loaded state of the lock, the release of the same has to take place against the frictional force existing between the lock drive and the locking bolt or the prevailing surface pressure.

The problem underlying the invention is now one certain continuity in the functional sequence of the device used to form the exposure time even in the shortest exposure time range of the shutter, i.e. up to the shortest Exposure time, without significant additional structural effort for shutter arrangements of the genus mentioned at the beginning.

This object is achieved in that between the Magnetic armature and the locking bolt blocking the sector drive part on the latter acting spring relay is arranged, which can be released by the armature and for actuating the locking bolt is designed such that the time interval from Beginning of actuation of the locking bar until it disengages on the sector drive part approaches zero. In this way it is achieved that the unlocking required movement time both for the loaded by the shutter drive and unloaded locking bolt practically one and the same size, so that starting from the shortest down to the longest exposure time of the shutter, one steady and continuously decreasing time formation is guaranteed.

To achieve a relatively simple, the structural conditions easy to adapt to a locking concept with electronic timing device Execution of a spring relay is also proposed that this one rotatable mounted, two-armed under the action of a relatively strong spring Actuating lever is formed, one lever arm of which by means of one through the armature lever from the locking position movable locking blade can be blocked and the other Lever arm cooperates with the locking bolt. In structural terms, this arrangement can be simplified by the fact that the two-armed operating lever is on the same axis is mounted with the anchor lever.

. In order to ensure the simplest possible operation of a shutter equipped with a spring relay with an electronic timing device, it is further proposed in a further development of the invention that a clamping arm is provided which is inevitably moved during the clamping process of the shutter, by means of which the actuating part in the clamping position and the magnet armature on the magnet assigned to it is brought to the plant. Furthermore, to ensure a trouble-free function sequence that cannot be adversely affected by any manufacturing inaccuracies, the Spannarin is formed from two levers mounted on the same axis and non-positively supported against each other by means of a cover spring, one with a movable part of the lock drive mechanism and the other with the actuating lever of the spring relay and the armature lever cooperates.

The invention is described in more detail below using an exemplary embodiment and shown in the drawing. It shows F i g. 1 an electronic shutter equipped with a compensation mechanism in the tensioned position, the mechanism used to release the shutter being merely indicated by dash-dotted lines and by the release button on the camera, FIG . FIG. 2 shows a partial illustration of the FIG. 1 illustrated locking concept, the slider crank mechanism has moved the sectors in the open position and the mechanism used to lock the sector ring is still in the locked position, FIG. 3 again shows a partial representation of the sector drive mechanism as well as the locking mechanism used to block it in the open position of the sectors, which in the given representation has just released the sector drive after the armature has dropped to the return movement transferring the sectors into the closed position, FIG . 4 shows a schematic representation of the division of the time interval that is required between the de-energization of the magnet of the timing device and the disengagement of the locking mechanism of the locking mechanism holding the sector drive in the open position, and finally FIG . 5 shows a partial section through the electronic lock according to the method shown in FIG. 2 indicated section line 1-1.

In the drawing, 1 denotes the base plate of a photographic shutter, which is arranged in a shutter housing 2 and provided with a pipe socket la. The base plate 1 serves to support the lock drive mechanism, consisting of a tensioning and drive shaft 4, a drive pulley 5 non-rotatably connected to this, a drive spring 6 acting on this and a drive pawl 7 articulated on the drive pulley, the free end of which is formed as a ring and with a tab 8a provided drive part 8 of the sectors 9 cooperates in such a way that when the drive pulley 5 runs in the direction of the arrow, the sector ring 8 and the sectors 9 perform a reciprocating movement. To lock the drive pulley 5 in the position shown in FIG. 1 , a two-armed locking lever 10 is used, on whose one lever arm that of another, shown in FIG. 1 also only indicated two-armed release lever 11 attacks. This lever is actuated by means of the in FIG. 1 also only indicated camera trigger 12, which is in operative connection with the lever via suitable intermediate elements, which are only illustrated in the drawing by a dash-dotted line.

In order to keep the sectors 9 of the shutter in the open position for the duration of the electronic switching device described in more detail below, the sector ring 8 has a further tab 8b which passes through a slot in the base plate 1 and which, in the open position of the shutter blades, as in F i g. 2 and 5 , can be blocked by a spring-loaded locking bolt 14. This latch is for this purpose as shown in FIG. 5 a laterally bent tabs 14 b provided in the movement range of provided on the sector ring 8 flap 8 b in and one by one on the base plate 1 is rotatably mounted, under the action of means of acting on the latch spring 15 with a driving pin 14a and relatively strong spring 16 standing operating lever 17 can be moved out of the blocking position. The seated on a Zapfen13 Betätigungshebe117 turn, the two Arme17a and has 17b can be locked by a Sperrklinke18 in eagerly location. A one-armed lever 19, at the free end of which an armature 20 is articulated, is mounted on the pin 13 on the same axis as the actuating lever 117, which is designed as a spring relay. An electromagnet 21 located in the circuit of an electronic timing device works together with the armature 20. The timing device for its part has a delay circuit 23 which is not illustrated in detail in the drawing and is designed in a manner known per se. This can preferably be designed as a trigger circuit, i. H. be equipped with several feedback transistors.

In the circuit of a battery B, in addition to the electromagnet 21 and the electronic delay circuit 23, the time-determining elements consisting of photoresistor R and capacitor C are located. In addition to these RC elements, a main switch S1 which can be actuated by the release mechanism 11 of the lock is located in the circuit of the battery B. a charging of the capacitor C introductory charging start contact S2 as well as the photo-resistor R to the beginning of the start-up movement of the sector ring 8 by a moving coil instrument 1 umlegender to the circuit time educational institution switch S ... The charging start contact S, includes in the in F i g. 1 illustrated switching position, the capacitor C briefly during the switching blade of the switch S #., An electrical connection between photo resistor R and moving coil instrument 1 is prepared. With the start of the sector ring 8, whereby the two switching tongues following the pins 8c and 8d come to rest on the further contact assigned to them, the switch S, the photoresistor R is switched into the circuit of the electronic timing device and the switch S 2 of the The short-circuit in the capacitor C is canceled and the timing is initiated. As for the locking pawl 18 provided for locking the spring relay 16, 17 under the influence of a spring 25 , its design and arrangement is such that it is always involved in the movement of the armature lever 19 , including the latter with one of the pawl as Support serving driving pin 27 is provided. A time constant of the above-mentioned mechanical locking compensating device works together with the sector drive ring 8 , which is essentially formed from a brake lever 29 under the action of a spring 28 and a rotatably mounted solid disk 30 connected to it by gear.

As far as the importance of the above-described spring relay consisting of spring 16 and actuating lever 17 in connection with the aforementioned compensation mechanism 28 to 30 is concerned, the purpose of these devices is to achieve a constant time formation even in the shortest exposure time range of the shutter, regardless of whether the sector ring 8 has been locked in the open position or not. The release of the locking bolt 14 is no longer done, as was previously the case, directly by the magnet armature, but by the spring relay 16, 17 arranged between this and the locking bolt 14 acting on the sector ring 8 . in order to achieve that the movement time for this bolt up to the moment of disengagement on the tab 8 b of the sector ring 8 goes almost to zero. The period of time required to move the locking bolt 14 is the same when the lock drive is loaded as that when the bolt is to be moved out of the locking position unloaded. For this purpose, the driving force of the spring relay 16, 17 is expediently dimensioned as large as possible. Apart from a certain maximum tensioning torque, the driving force of the spring relay 16, 17 is indirectly limited by the holding force of the electromagnet 21. This must always be greater than the return force of the return spring 31 acting on the armature lever 19. On the other hand, the return force of this spring must be so great to cancel the locking of the spring relay 16, 17 by the pawl 18 as possible without loss of time.

Assuming that the movement time of the locking bolt 14 is almost uniform both in the loaded and in the unloaded state, as FIG . 4 illustrates that the entire time interval T present between the de-energization of the electromagnet 21 and the disengagement of the locking bolt 14 with the sector ring 8 can be compensated for by the compensation mechanism 28 to 30 . This time interval T is divided into the following time segments: ti = movement time of the armature 20 from leaving the electromagnet 21 until the spring relay 16, 17 is released by the pawl 18; t2 = start-up time of the spring relay 16, 17 until it hits the locking bolt 14; t3 = movement time of the locking bolt 14 until it disengages the tab 8 b of the sector ring 8.

From this illustration it can be seen that the time segments ti and t. are completely independent of whether the locking bolt 14 is loaded or not. They can therefore be fully and unambiguously taken into account for all time formations by means of the compensation mechanism 28 to 30. The only difference between loaded and unloaded locking bolt 14 can only exist with respect to the time segment #. With the spring relay 16, 17, which with the aid of a relatively large actuating force (strong spring 16) allows this period of time to go to zero, significant deviations can be avoided, regardless of whether the locking bolt 14 is to be moved out of the locked position in a loaded or unloaded state. Thus, the time segment t3 can also be taken into account by means of the compensation mechanism 28, 30 , whereby an effective compensation of the entire time interval T consisting of the aforementioned three time segments ti to t 3 can be achieved.

In order to be able to move the spring relay 16 .. 17 as well as the armature lever 19 against the action of the springs 16 or 31 acting on these parts into the corresponding starting position, which must be assumed prior to the operation of the lock, depending on the tensioning process, a is rotatable on an axis 34 mounted clamping arm is provided, which is formed from two levers 35 and 36 mounted on the same axis. These levers are in turn supported in a force-locking manner against one another by means of a connecting spring 37 and a laterally bent tab 35a. For influencing the tension arm 35 to 37 5, the Aniriebsseheibe laterally an operating pin 5 a, which is arranged so that pressure is exerted during the clamping operation of the closure on the free end of the clamp arm via a provided on the lever pin 35 b to both the Operating lever 17 as well as on the armature lever 19 is transmitted.

The operation of the vorbesehriebenen closure arrangement is described in detail as follows: Pressing the shutter release 12, the release lever 11 and actuated by this movable locking lever 10 are, as a result, that the main switch S, sailed - Swiss cooperative and the closure drive is released to the drain. While the electromagnet 21 on the battery is connected to voltage by closing the switch S, the sectors 9 are moved into the open position by delaying the opening movement of the sector ring 8 by the compensation mechanism 28 to 30 and simultaneously actuating the switches S2 and S. When the open position is reached, the locking bolt 14 lies down, as in FIG . 2 illustrates, in front of the tabs 8 b of the sector ring 8 and thus blocks the entire drive system. This continues until the timing device cancels the magnetic field existing in the electromagnet 21 and, as a result, the armature 20 is released. The armature lever 19 is now set in motion under the influence of the spring 31 and, by engaging the pin 27, disengages the pawl 18 on the spring relay 16, 17 . The thus released operating lever 17 now under the influence of the relatively strong spring 16 on its bearing pin 13 rotates in a clockwise direction, strikes with the arm 17 b on the pin 14 b arranged on the locking bolt 14, which has the consequence that the locking bolt is immediately moved out of the locked position. As a result, as shown in FIG. 3 illustrates how the drive system can be set in motion again and the sectors 9 can be brought into the closed position.

The above-described spring relay 16, 17 arranged between magnet armature 20 and locking bolt 14, in combination with compensation mechanism 28 to 30, is not limited to the special use in electronic locks with locking blade systems formed from several sectors. This combination can be used wherever a shutter blade system is provided, the drive part of which makes a reciprocating movement to open and close the lens passage. The spring relay 16, 17 could also be installed in such an electronic shutter, the shutter blade system of which only consists of a single sector. It is only important that its drive part executes an oscillating movement to open and close the lens passage.

Claims (2)

Claims: 1. A photographic shutter with a reciprocating drive part acting on the sectors and an electronic timing device which has a magnet armature under the action of a return spring and a locking bolt which can be influenced by this and which blocks the drive part for the duration of the timing controls, wherein the sector drive, a the opening motion retarding, the compensation time constants of the mechanical lock is associated with serving #Einrichtung, d a d u rch g e k hen - characterized in that between the armature (20) and the sector drive part (8) blocking lock bolt (14) a spring relay (16, 17) acting on the latter is arranged, which can be released by the magnet armature and is designed for actuating the locking bolt in such a way that the time interval from the start of actuation of the locking bolt until it disengages on the sector drive part is zero approaching. 2. Photographic shutter according to claim 1, characterized in that the spring relay (16, 17) is formed from a rotatably mounted, under the action of a relatively strong spring (16) standing two-armed actuating lever (17) . one lever arm (17a) of which can be blocked by means of a pawl (18) which can be moved out of the blocking position by the armature lever (19) and the other lever arm (17b) of which cooperates with the locking bolt (14). 3. Photographic shutter according to claim 2, characterized in that the two-armed actuating lever (17) is mounted coaxially with the armature lever (19) . 4. Photographic shutter according to claim 1 to 3, characterized in that a clamping arm (35 to 37) which is inevitably moved along during the clamping process of the shutter is provided, by means of which the actuating lever (17) in the clamping position and the magnet armature (20) on the magnet assigned to it (21) is brought to the facility. 5. A photographic shutter according to spoke 4, characterized in that the tensioning arm is formed from two coaxially mounted levers (35 and 36) supported against one another in a non-positive manner by means of a cover spring (37) , one of which with a movable part (5) of the shutter drive mechanism and the other cooperates with the actuating lever (17) of the spring relay (16, 17) and the armature lever (19) .