AT206746B - Photo capture device - Google Patents

Description

  

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  Photo capture device
 EMI1.1
 fallen anchor is the least.



   The invention relates to a Lichtbildauf- nabmgerät in which the sequence of the shutter, z. B. to regulate the exposure time, the time delay of the flash triggering or the advance for self-recordings, is controlled by an electrically influenceable lock and consists essentially in that the lock is designed as an armature of an electromagnet with a pre-magnetized core, the winding is connected so that Current flow causes a field weakening, so that the armature falls into its non-blocking position.

   Due to this design of the electromagnet, the armature of which can be held in the attracted state against the action of a spring, the field weakening is already achieved by a brief current surge, because a slight detachment from the magnetic core is enough to weaken the magnetic holding force so strongly, that it can be overcome by the spring force.



  The reaction time of the magnet is therefore very short and the electrical power required to trigger the lock is low, which is particularly important in the tight space conditions in closures. The design of the photo-recording devices according to the invention enables electrically operated closures of particularly high precision to be built.



   Further features of the invention are explained in more detail using a few exemplary embodiments. 1 shows the basic arrangement of an electronic escapement mechanism with a lock, FIG. 2 shows a basic circuit diagram of the electronic escapement mechanism, FIG. 3 shows a blocking magnet system used to control the mechanical locking sectors, FIG. 4 shows another embodiment of such an electronic device, FIG .



  5 shows a closure equipped according to the invention in view and partial section, FIG. 6 shows a top view of the closure according to FIG

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 Fig. 5 with the front panel removed, Fig.



  7 shows a detail of FIG. 6, and FIG. 8 shows the circuit diagram of the electronic control device of this closure.



   1 shows schematically, partly in a block diagram, the electronic arrangement according to the invention on a photographic camera with a sector shutter. As the actual mechanical locking elements, locking sectors 10 of the known type are used, which are opened and closed in a known manner by a ring 11 mounted centrally to the lens when the ring is rotated counterclockwise (FIG. 1) via known intermediate elements. In the starting position (clamping position) with the lock closed, the ring is held in place by a pawl 12. For the purpose of receiving, the pawl 12 is moved against the force of the spring 13, thereby releasing the ring 11 previously tensioned by hand.

   The ring 11 now rotates counterclockwise under the action of the spring 14 and actuates the two contacts 17 and 18 one after the other, striking an armature 15 of an electromagnet 16 with a premagnetized core and being stopped. The winding of the electromagnet is switched in such a way that the current flow causes a field weakening. In this position shown in the drawing, the sectors 10 are fully open and release the lens for exposure, while at the same time the contacts 17 and 18 are closed, which set the electronic delay mechanism represented by the block 20 in action. This delay mechanism works in principle in such a way that a pulse occurs at the output after a specific, adjustable period of time after the contact 18 has closed.

   This pulse is given to the electromagnet 16, the armature 15 of which falls into its non-blocking position due to the weakening of the field caused by the flow of current, thereby releasing the sector ring 11, which now closes the sectors under the action of the spring 14. The exposure time, i.e. H. the time between opening and closing the sectors depends on the delay period controlled by the circuit 20, which is now controlled by an adjustable switching element, e.g. B. the dashed line resistor 21 is adjustable. However, it can also be influenced directly by the photocell 1 directed towards the subject.



   An example of the circuit of the delay device 20 is shown in FIG. 2, which represents a so-called semi-stable multivibrator for timing through transistors. As the main elements, it consists of the two transistors 31 and 33. The contact 17 is used to switch on the current source 2. The contact 18 emits the pulse that sets the delay period in motion. This negative pulse is generated by discharging the capacitor 22 and given to the point 35. This makes the transistor 31 conductive. The time constant of the circuit determined by resistor 21 and capacitor 36 determines the tilting back of the stage. By tilting back the step, a current now flows through the coil 34 of the blocking magnet system.

   As a result, the armature 15 of the blocking magnet system and thus the ring 11 are now released. (Flip-flop circuit). The variable resistor 21 provided for influencing the period of time of the tilting circle can also be replaced by a light-sensitive resistor (photocell), the size of which is controlled by the exposure conditions, so that the exposure time is automatically controlled by the exposure measurement.



   Instead of an ordinary holding magnet, a so-called pulse-controlled blocking magnet can advantageously be used, in which the field generated by the breakover current is not directly opposed to the field of a permanent magnet, but only serves to increase the magnetic resistance of the pole shoes of a magnet system made of highly permeable nickel iron sheet. Such a blocking magnet system is shown in FIG. A permanent magnet 37 is located between two pole pieces 38, the field lines of which partially close directly over the pole pieces.



  In the front part of this pole piece is the coil 34 through which the breakover current flows. When this coil is excited, the front part of this pole piece is highly saturated and its magnetic resistance is increased, so that the magnetic lines of force are displaced in the direction of the permanent magnet and the armature 15 is released becomes.



  This arrangement makes it possible to enlarge the circuit in the coil 34 considerably and thus to achieve a shortening of the time constant of the electrical circuit without the permanent magnet being adversely affected by these current surges. The time interval between the opening and closing of the shutter sectors, which is decisive for the exposure time, is controlled by a circuit that works with electronic means, whereby the adjustable delay interval is advantageously possible continuously and without jumps by influencing the circuit elements of the delay circuit, which allows an exact adaptation to the exposure conditions enables.



   Under certain circumstances, the exposure time can also be influenced by a

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 depending on the film used.



   As can be seen from FIG. 4, the diaphragm device can also be used to drive a depth of field display device 127. It is only necessary to set the desired depth of field for a certain exposure and to point the camera at the subject, whereupon the associated exposure time is set in the electronic delay circuit itself, taking into account the aperture set by the selection of the depth of field To direct a look at the scale 124 in order to determine whether, given the prevailing light conditions, it is possible to take a picture within the available exposure time.



   The example discussed above is a photographic camera in which a flip-flop which works with transistors or diodes is used to generate the delay period, which is triggered by the initial movement of a mechanical member that actuates the shutter sectors, and this mechanical member in the open position of the sectors via a magnet system during the delay period controlled by the flip-flop. However, it is easily possible to control other delay time periods by means of such an electronic delay circuit.

   For example, the time span required to take pictures of yourself between the actuation of the shutter release and the opening and closing of the mechanical locking cover members or the time span required between the ignition of the device and the full opening of the sectors when using a flash device can be controlled by such a circuit.



   In the case of a photo capture device, the before. described type. in which the exposure process indirectly through an inhibitor actuated by the shutter, z. B. a flashlight equalizer or a forward mechanism is triggered, according to the invention, this inhibitor can be a switch operated by an electromagnet, the magnet of which - preferably switched as a working resistor of a first toggle switch - after the inhibition time has elapsed, switches on a second toggle switch which is used to open and close the Closure contains a further electric blocking magnet.



   In the embodiment of the invention shown in FIGS. 5 to 8, the spatial accommodation and arrangement of the individual elements of the electronic control device within a self-contained

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 NEN housing of the lens shutter shown. Furthermore, a special type of control of the sector rings that drive the shutter sectors for opening and closing the exposure aperture is shown here by means of holding magnet systems.



   The lens shutter 210 is attached to the front wall of a photographic camera in a known manner. It has a cylindrical shutter housing with a rear lens connector 212. A base plate 214 is fastened inside the shutter housing, which in turn is firmly connected to a connector 216 that supports the front lens tube. An annular space 218 is thus created between the closure housing 210 and the connecting piece 216, in which the closure mechanisms described below are accommodated. The objective or lens formed by the objective socket 212 and 216.

   Exposure aperture 220 is normally held closed by a system of shutter sectors 222, which are reciprocated to permit exposure of the exposure aperture required for exposure, and are journalled on pivot pins 224 which are secured to a sector drive ring 226.



   For the sake of clarity, only a single closure sector 222 is shown in FIG. 6. However, as is known per se, the entire shutter sector system consists of several, for example five shutter sectors, which are all arranged symmetrically around the exposure opening in the same way. As usual, this sector drive system is brought into the clamping position by mechanical means and, after being triggered, runs out of this clamping position under the influence of spring forces in order to open and close the exposure opening for a photograph. The locking sectors 222 have a control slot 228 in which control pins 230 engage, which are fixed on a second sector drive ring 232.

   The sectors 222 themselves are arranged in an annular gap 234 (FIG. 5) between the housing parts 210 and 214, while the sector drive rings 226 and 232 are accommodated between the parts 214 and 216 and are rotatably guided here and coaxially to the optical axis. The bearing or drive pins 224 and 230 reach through correspondingly shaped openings in the base plate 214. The sector drive rings 226 and 232 have radial arms 236 and 238 which reach through the circumferential slots of the part 216 and rest on a clamping cam 240 in the rest position of the closure.

   This clamping cam 240 is designed as an eccentric and sits on a clamping shaft 242 (FIG. 5) mounted in the lock housing 210, which protrudes through the rear wall of the lock housing 210 and is equipped with actuators on the camera side, e.g. B. with the film transport gear of the camera, is engaged, u. zw. In such a way that the clamping cam 240 executes a full turn in the clockwise direction (FIG. 6) during film transport. The sector drive rings 226, 232 are thereby brought together from their rest position into a clamping position and are held in this clamping position.

   Since the clockwise movement of the sector drive rings 226, 232 takes place simultaneously during the clamping movement, the locking sectors 222 do not move back and forth with respect to the optical axis, but the entire sector drive system is only moved by an angular amount corresponding to the stroke of the clamping cam 240 adjusted optical axis around. There is therefore no opening of the exposure opening 220 by the shutter sectors 222 during the clamping movement.

   Only when, after the triggering of the sector drive ring 232 serving to open, moves counterclockwise from the clamping position into the rest position under the action of its drive spring 244, the sectors 222 - since the sector drive ring 226 is still at rest - are pivoted about the bearing pins 224 via the control pins 230 and the sealing opening 220 released. The sectors 222 remain in the open position shown in FIG. 6, used for exposure, until the sector drive ring 226 used for closing is also released and, under the action of its drive spring 246, returns to its rest position counterclockwise and the sectors through the now stationary control pins 230 can be closed again by the adjustment movement of the bearing pins 224.



   Deviating from the previously known type of lock, the sector drive rings 226, 232 of the lock elements 222 are held in the tensioned position by holding magnet systems, the electronic means provided controlling the holding magnet systems with the time delay necessary for exposure to release these rings after triggering. According to the invention, both sector drive rings 226, 232 are held in the tensioned position by locking magnets of the same type.



   On the base plate 214 of the closure 210, two holding magnet systems 248 and 250 (FIG. 6) are fastened in the annular space 218, which are identical, which is why only one of the magnet systems is described in detail below. The holding magnet 248 is screwed firmly to the base plate 214 and has two iron cores 248b 'and 248b "

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 EMI5.1
 of the electronic device. The pole shoes 248b are designed such that they are brought together closely behind the coils so that a magnetic shunt is achieved for the permanent magnet 248a. The pole shoes act as holding magnets when at rest, so that an armature moved towards them is attracted and held in place.

   However, as soon as the electric current flows through the coils 248c in a suitable polarity, the pole shoes are counter-excited and the armature is released again from the holding magnet. The pole shoes 248b of the holding magnet 248 now work as an armature with a radial arm 252 of the metallic sector drive ring 226, while an arm 254 of the sector drive ring 232 cooperates with the pole shoes 250b 'and 250b ″ of the holding magnet 250. If now during the clamping by the clamping eccentric 240 the rings 226 and 232 are moved in the clamping position, then towards the end of the clamping movement the arms 252 and 254 of these rings come into the area of action of the magnets and are attracted by the respective pole pieces and held in the clamping position.

   The holding force of the magnets 248, 250 is greater than the force of the springs 244, 246, so that the sector drive rings 226, 232 are only released from the clamping position under the action of their springs 244b and 246b when the magnet spuds 248c ', 248c "or 250 ', 250c "and the holding magnets 248, 250 are thus counter-excited.



   The holding magnets are switched on in an electronic control circuit, the circuit diagram of which can be seen in FIG. These electronics are fed by a power source, for example a battery 256, which is either in the lock housing 2.? 0 itself or in the camera, which will be explained in more detail later. One pole of the battery is connected to the ground of the shutter or the camera, while the other pole is connected to the electronic circuit via a switch 258.

   The switch 258 is actuated by a manual release 260, indicated schematically in FIG. 8, which has a conical head 260a made of insulating material (FIG. 6) which, when the release button 260 is depressed, presses the two contact springs of the contact 258 together and thus closes the circuit. The spring 260b resting on a stationary abutment strives to always press the button 260 radially outwards and thus to keep the contact 258 open, that is to say separated. On the arm 252 of the sector drive ring 226, an angularly bent, resilient tab 262 is attached, which falls behind the collar 260c of the same when the trigger 260 is depressed and the-
 EMI5.2
 ssstellung248 is held.

   Only when the ring 226 runs counterclockwise back into the rest position does the angled tab 262 also come out of the constriction
260c moved out so that the trigger 260 can return to its rest position and the contact 258 opens.



   In the circuit diagram of the electronic
In the partial image to the right of the battery 256, the control device according to FIG. 8 is the one for controlling the exposure time, ie. H. for controlling the time delay between the excitation of the holding magnets 248 and 250 necessary equipment indicated. These are the already mentioned coils 248c and 250c, furthermore the transistors 264 and 266, the delay capacitor 268, then the feedback capacitor 270 and the voltage dividers 272, 274. The controllable electrical resistor 276 has an adjustable actuator 276a (potentiometer), which can be adjusted using a scale 278, for example, and is used to set a specific time delay between the time at which the holding magnet 248 and 250 are excited.



  A specific exposure time can thereby be set so that the scale 278 is expediently calibrated in exposure time values.



   The coils 248c ', 248c ", 250c' and 250c" and the contact switch 258 are housed separately from one another in the closure housing 210 from this electronic control device, as FIG. 6 shows. The rest of the equipment for this electronics, on the other hand, is combined in a structural unit 280, which is fastened to the base plate 214 of the lock with the inclusion of insulating means and is conductively connected to the rest of the electronics by means of lines.

   The battery 256 is connected to the electronic control device in the lock 210 by means of a contact bush 282 (FIGS. 5 and 6) which is attached to the rear of the lock housing 210 and whose one pole 282a is connected to the ground of the lock parts, while the other pole 282b is inserted into the assembly 280 in which the battery is housed. The current connection between the battery and the lock takes place via the aforementioned contact bush 282 when the lock 210 is attached to the camera (not shown) during assembly.



   It has already been explained that the

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 The exposure time is set with the aid of a time scale 278, on the basis of which a potentiometer which changes the resistance 276 is adjusted by means of the adjuster 276a.



  In Fig. 7 details of such a time setting device are shown. A rotatable time setting ring 284 is rotatably mounted on the front side of the closure 210 and provided with handle notches. A mark 284a (FIG. 5) of the rotatable setting ring now works together with the time scale 278 on the circumference of the closure housing 210. This time scale contains the exposure values from 1 sec to V <oM sec, for example. The time setting ring 284 has a toothing 284b on its inner circumference, in which a pinion 286 engages, the shaft 286a of which is mounted in the assembly 280 and adjusts a potentiometer (not shown) housed in the assembly, whereby the resistance 276 in the electrical circuit is changed.



  The details of such a resistance control by means of a potentiometer adjustable over several revolutions are known per se and should therefore not be mentioned in more detail.



   The electronic control circuit in the shutter housing 210 includes not only the equipment already mentioned and used to control the exposure time, but also a flashing light contact device and a feed or flashing light. Self-release device. This part of the electronic equipment is shown in the left partial image of FIG. 8 in the circuit diagram.



  The spatial accommodation of the individual parts, on the other hand, is best shown in FIG.



   A three-pole changeover switch 288 is provided, which is fastened in an insulated manner on the base plate 214 of the closure 210. This changeover switch has a switching arm 288a which protrudes from the lock housing and is mounted pivotably about an axis 288b. The switching arm 288a is held in one of its three switching positions by locking means (not shown), for example spring catches. These switching positions are identified by the characters M ", X" and "V" on the circumference of the lock housing 210. The shift arm 288a is also connected to two contact arms 288c and 288d, which slide over three contact plates 288e and 288f, which are isolated from the lock housing.

   In addition, a holding magnet 300 is provided in the lock housing 210, which is similar to the holding magnets 248 and 250, so that it is not described in more detail. The holding magnet 300 works together with a switching spring 302, which from
Metal and acts on a switch 306 via an insulating intermediate layer 304. The switching spring 302 is carried along by the clamping eccentric 240 when the closure is tensioned and applied to the magnet system 300b ', 300b "and held there by the action of the permanent magnet 300a and the contact 306 opened. In the positions
 EMI6.1
 drive set, the switching spring 302 released by the magnet system 300 and the contact 306 closed.

   In the Z "position, however, the transistor system 310, 312 is not energized and the switching spring remains in the tightened position and thus the contact 306 remains open in the" X "position.



   An installation unit 308 is provided between the holding magnet 300 and the switch 288.
 EMI6.2
 first the transistors 310 and 312, the delay capacitor 314, the feedback capacitor 316, fixed, i.e. non-adjustable resistors 318 and 320 and also the voltage dividers 322 and 324. The details of the connection between the individual points of the electronic circuit can be found in the circuit diagram according to FIG. 8 clearly. The changeover switch 288 with its arms 288c and 288d is also indicated schematically in this circuit diagram.



   Finally, it should also be mentioned that in the lock housing 210, in addition to the already explained and "TJ" control device no. a contact 326 (Fig. 6) is provided which is normally open but is closed by the arm 238 of the sector drive ring 232 when this ring is in its rest position. This contact 326, the so-called "X" contact, is used when the switch 288 is set appropriately to close a flash lamp circuit, which is also entered in the circuit diagram according to FIG.



  The flash lamp 328 is fed by the current source 256 and for this purpose is connected to the circuit via a two-pole socket 330, which is shown schematically in FIG. Such connection means for a flash lamp are known per se, so that they should not be mentioned in more detail here. The socket 330 has one pole connected to the ground of the device, while the other pole is isolated and is in communication with the electronic device. A contact plug with a cable that can be pushed onto the socket connects the flash lamp with the contact device in the lock.



   In relation to the circuit diagram according to FIG. 8, it should also be mentioned that the elements shown there with the usual diagram symbols are the electronic control circuit per se

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 have known designs and perform corresponding functions. It should therefore be superfluous to go into details in this regard. The transistors 264, 266 and 310, 312 are operated as controlled switches, while the feedback capacitors 270 and 316 return the control pulses beginning at the coils 248c, 300e to the transistors 264 and 310, respectively. The voltage dividers 272, 274 or 322, 324 lay the base of the transistors 266 and



  312 fixed. As the circuit diagram of FIG. 8 shows, the individual elements of the electronics are connected to one another. The corresponding connecting lines are also shown in the exemplary embodiment according to FIG. 6, at least schematically, as insulated cable conductors. It should be superfluous to describe the individual connecting conductors in more detail. It should be mentioned, however, that the capacitor 268, which is switched on in the control circuit of the timing control system, is unloaded in the circuit when the transistor 264 blocks. The set exposure time depends proportionally on the product between resistor 276 and capacitor 268. In this way, exposure times of up to 30 seconds can be achieved with a very small capacitor.

   It should also be mentioned that the demagnetization surge for the holding magnets is essentially only taken from the capacitor.



  The battery is thus relieved of current surges, especially with longer exposure times.



   The mode of operation of the circuit shown in FIG. 8 is explained using the timing device shown to the right of the battery, since the left part is almost identical and has the same mode of operation.



  In position "X" of the switch 288, as can be seen, the arm 288c is connected to the middle contact, so that when the button 260 is pressed via the contact 258 the current source is applied to the right-hand part of the circuit.



   When switching on, current immediately flows through the coil 250c because the base of the transistor 266 is due to the voltage divider 272 and 274 at a higher potential than the emitter. The magnetic field generated in the coil 250c weakens the permanent magnetic field of the magnet 250a, so that the spring 244 can set the sector ring 232 in motion and thus the closure is opened. Since the base of the transistor 266 is held in potential by the voltage divider 272/274, a constant current flows through the coil 250c. According to Ohm's law, this creates a voltage drop in this which determines the base voltage of transistor 264.

   When switching on, the capacitor 268 is also empty and a charging current therefore flows through the resistor 276 which, according to Ohm's law, is initially proportional to the battery voltage and inversely proportional to the value of the resistor 276. As a result, the emitter of transistor 264 is at the battery potential at the moment of switching on and thus higher than the associated base, so that no current flow is possible in accordance with the characteristics of the transistor.



   The voltage at the capacitor 268, which rises according to an exponential function, now causes the emitter potential of the transistor 264 to drop; the speed of this process can be adjusted by changing the resistor 276 (actuator 276a and scale 278). After a certain charging time, the emitter potential of transistor 264 must reach the value of its base potential, which, as explained above, is determined by transistor 266. The control voltage effective at transistor 264. the difference between the emitter and base voltage is referred to as such, i.e. changes in such a way that the previously blocked transistor 264 begins to conduct. As a result, a voltage drop occurs at coil 248c which, via capacitor 270, shifts the base voltage of transistor 266 in such a way that a current decrease occurs in the latter.

   This reduces the voltage drop across coil 250c and the potential of the base of transistor 264 rises again and causes the collector current in transistor 264 to rise again. The capacitor 270 thus causes feedback and causes an avalanche-like increase in the collector current from transistor 264; The initially hesitant start of the current turns into a sudden use, so that the transistor 264 acts as a switch.



   The magnetic field of the coil 248c weakens the magnet 248a, so that the spring 246 can rotate the second sector ring 226 counterclockwise and thereby the shutter is closed.



   The described locking arrangement is handled as follows:
If a picture is to be taken, the film must first be transported by actuating a film transport button or the quick transport lever. In the process, the clamping cam 240 accommodated in the lock J O is also rotated clockwise and the sector rings 226, 232 are brought into the clamping position. In this clamping position, they remain stopped by the holding magnets 248 and 250 via their arms 252 and 254. After this clamping process, the operator only has one of the options to be carried out by actuating the time setting ring 284.

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 leading exposure to set the appropriate exposure time using the scale 278 and the mark 284a.



   The release process of the shutter is initiated by depressing the trigger 260. The conical head 260a of the trigger initially closes the contact 258 and remains held in this contact closure position by the tab 262 of the arm 252. The head 260a of the trigger 260 initially pushes the tab 262 away to the side, ie perpendicular to the plane of the drawing according to FIG. 6, until it finally falls into the constriction 260c of the trigger 260. The release thus remains stopped in the release position. As soon as contact 258 is closed, only the time control device is connected to voltage via switch 288, which is normally set to ", Y".

   As already mentioned, the holding magnet 250 is initially counter-excited via the coils 250c ', 250c ", since the transistor 266 is conductive through its base voltage divider 272, 274. The field weakening of the holding magnet 250 makes the pole shoes 250b', 250b" non-magnetic, so that the arm 254 of the sector drive ring 232 released to drain and the locking sectors 222 opened. At the same time, the capacitor 268 is charged via the resistor 276 until the emitter potential of the transistor 264 falls below the base potential given by the transistor 266. At this moment the current begins to flow through the transistor 264 and the feedback via the capacitor 270 to the base of the transistor 266 accelerates the process, so that a sudden current change now takes place.

   The coils 248c ', 248c "now generate a magnetic pulse on the holding magnet 248, which now also allows the sector ring arm 252 to be released. The closing process of the closing sectors 222 can thus take place and a recording can thus be carried out, for example, in daylight The time constant of resistor 276 and capacitor 268 set in the time setting determines the time interval between the release of the sector rings 226 and 232 which actuate the opening and closing movement of sectors 222 and thus also the opening duration or exposure time of shutter 210.

   As soon as the arm 252 of the sector ring 226 has started to return, its tab 262 also releases the trigger 260, so that it moves back to its rest position under the action of its return spring 260b. The contact 258 is opened in the process, thus preventing further power consumption from the battery 256.



   In the above-mentioned X position of the switch 288, its arm 288c also provides the current-conducting connection of the switch 258 with the pair of Tl anistors 264, 266 and also the current-conducting connection with the socket 330 via the contact 326 for the purpose of receiving a flash. The switching arm 2'jod rests on an empty contact and has no influence.



  If now, as explained above, the contact 258 is closed by actuating the trigger 260, current also flows from the battery 256 via contact 258 and contact 288c to the transistor arrangement 264, 266. After the first sector ring 232 has returned to the rest position, the arm closes 238 of the same then the contact 326 (X contact) and ignites the X flash lamp 328 connected via socket 330 precisely at the time of the full opening of the closure sectors 222.



   If, in contrast to the case explained above, an Al flash lamp with a longer lighting delay (e.g. 16 ms) is used for another flash exposure, the operator must set the arm 288a of the switch 288 to the "Al" position. The arm 288e of the switch 288 touches the one double contact and thus connects the holding magnet system 300 and the transistors 310 and 312 via the contact 258 to the power source 256. At the same time, the flashlight 325 'is also switched on via the socket connection 330. The arm 288d of the changeover switch 288 switches the resistor 320 in parallel with the resistor 318, so that the time constant from the capacitor 314 and the parallel connection of the resistors 318 and 320 is approximately 16 ms. d. H. corresponds to the above-mentioned lighting delay time of the M flash lamp.

   (However, other resistance and capacitor values could also be freely selected and set if different delay times are desired for igniting other types of flash lamp). If the trigger 260 is now depressed with this setting, the current source 256 is connected to the switch arm 288c via the contact 258 and the flashlamp 328 is ignited, and at the same time the transistor 312 is traversed by the current. Furthermore, the capacitor 314 begins to charge via the resistors 318, 320. This continues until the emitter voltage of transistor 310 exceeds the value of the base voltage.

   At this moment, the current begins to flow through the transistor 310, and the feedback through the capacitor 324 to the base of the transistor 312 accelerates the process, so that a sudden current change occurs again. The coils 310c ', 310c "now produce a magnetic pulse that causes the fall

 <Desc / Clms Page number 9>

 the switching spring 302 and thus the closing of the contact 306 causes. This contact now switches on the timing control system described above, the transistors 264 and 266 controlling the sequence of the two sector drive rings 226 and 232 in the manner already explained.

   In the open position of the sectors 222, the lighting delay of the flash lamp 328 is after the fence already made at the beginning. Application has just passed, so that in this open position of the shutter 210 the flash light reaches its peak value and illuminates the scene. At the end of the locking sequence, the trigger 260 locked by the arm 262 is released again and the flow of current is interrupted.



   As already mentioned, the electronic control circuit can also be used to carry out self-recordings. In such cases, a longer period of time, for example about 12 seconds, is switched on between the time the trigger is actuated and the time the shutter is closed, which enables the operator to switch to the recording. In such a case, the arm 288a of the switch 288 is to be set to the "V" position (forward drive).



  In this position of the switch, the same circuit is used as it is explained above in connection with an M flash exposure, but with the difference that the arm 288d of the switch is now empty. It is thereby achieved that only the resistor 318 and the capacitor 314 influence the breakover duration of the transistor system 310, 312. In this setting, which is only intended for front-end recordings, the time constant is selected so that it results in a delay time between actuation of the shutter release and the shutter cycle of about 12 seconds.

   In principle, however, an arbitrarily adjustable lead time can also be selected through any optional variability of the resistor 318 if this is desired in certain operating cases, that is to say with certain cameras.



   With the "V" setting of the switch 288, the flash lamp circuit is only switched via the X contact 326, which is closed by the arm 238 of the sector ring 232 in the open position, so that in this case, i.e. with forward recordings, only flash photos with X. -Lamps can be made.



   In the electronic control system for controlling delay times of the shutter, according to a special feature of the present invention, each of the sector actuators is held in the clamping position by a holding magnet system and only released one after the other after being triggered by the electronics, so that the time delay necessary for exposure is achieved . Furthermore, all elements of the electronic control device are accommodated within a self-contained locking housing. The power source is preferably housed in the camera housing and is connected to the electronics in the lock via detachable connection parts.



  This training initially has the fundamental advantage that the electronic means can be used to regulate the time spans continuously, that is to say steplessly, within the required large setting ranges. Furthermore, the setting, adjustment and calibration of these circuits is extremely simple.



  In addition, the control according to the invention achieves a noiseless and vibration-free operation of the closure. The electronic means allow not only a space-saving design of the lock, but also the control of time pulses in the size range up to about 1/40,000 sec. With regard to the mechanical drive system of the lock, however, these very short time delays cannot be fully exploited one can practically shortest exposure times up to about; reach oo sec.



  Another advantage of the invention is that the individual locking operating elements, i.e. the time setting element and the MXV changeover switch, can not only be operated by hand, as is indicated in the present example, but the electronic control circuit systems can also be used for this purpose by known ones Remote controls can be set. It should also be mentioned that the shutter control system and the associated electronics can be housed not only in the shutter housing, but also without their own housing in a favorable location inside the camera itself and thus combined with the other camera devices. Retaining magnets of the same type are advantageously used for all time delay systems of the lock.

   As a result, the remaining intrinsic delay times (approximately 3 to 4 ms) of these systems can be canceled out against each other in a simple manner, so that a control system is achieved with maximum accuracy.



   When using a manually rotatable time setting ring of the type shown, it is expedient to design the exposure time scale assigned to this setting member by appropriate selection and dimensioning of the electronic control elements so that it has a linear graduation.



  In this case, you can then use the exposure time setting member; possibly with

 <Desc / Clms Page number 10>

 a diaphragm setting member of a diaphragm device, which also has a linear scale division, can be coupled without difficulty, as is already known per se.



   Finally, it should also be mentioned that the features of the subject matter of the invention can also be used in locking systems of a type other than that shown. Also, the embodiment of the invention is not limited solely to the circuit diagram shown and the structural shape and spatial accommodation shown, e.g. B. a relay arrangement could be used instead of the transistors. The invention can also be carried out with features differing therefrom and the respective closure or



  Adjust camera needs.



   PATENT CLAIMS:
1. Photo recording device in which the expiration of the shutter, e.g. B. to regulate the exposure time, to delay the triggering of the flash or the advance for self-recordings, is controlled by an electrically influenceable lock, characterized in that the lock is designed as an armature of an electromagnet with a pre-magnetized core, the winding is connected so that current flow Field weakening causes the armature to drop into its non-blocking position.

 

Claims (1)

1. Photo recording device according to claim 1, characterized in that the electromagnet is designed as a pulse-controlled blocking magnet (Fig. 3). 3. Photo recording device according to claim 1 or 2, characterized in that the electromagnet is connected as a working resistor in the part of a transistor flip-flop circuit (flip-flop circuit) which receives current after the flip-flop process (Fig. 2). 4. Photo recording device according to claim 1 or 2, characterized in that the electromagnet is connected as a working resistor in the part of a double-base diode toggle circuit which receives current after the tipping process. 5. Photo recording device according to claim 3 or 4, characterized in that at least one of the switching elements (resistor (21), capacitor (36)) controlling the switching point (resistor (21), capacitor (36)) is adjustable in the trigger circuit. 6. Photo recording device according to claim 5, characterized in that an adjustable Switching element as more sensitive to light Resistance (photocell) is formed. 7. Photo recording device according to claim 5 or 6 with a sector ring, the sequence of which after triggering causes an opening and closing of the locking sectors, characterized in that the locking anchor is arranged so that it blocks the sequence of the sector ring when the sectors are fully open and in the tightened position in the dropped position releases the further process for closing the sectors, and that a switch actuated by the sector ring is provided to ignite the toggle switch at the latest when the sectors are fully open. 8. Photo recording device according to one of claims 5 to 8, characterized in that one of the adjustable switching elements interacts with a display device, preferably with a parallel-connected voltmeter, by which the size of the delay time controlled by the flip-flop is displayed. 9. Photo recording device according to one of claims 5 to 7, characterized in that the adjustable switching element is designed as a resistor scanned by the pointer of a photoelectric exposure meter (Fig. EMI10.1 10. Photo recording device according to claim 8 or 9, characterized in that the display device or the measuring mechanism of the exposure meter is connected to an aperture plate (Fig. 4). 11. Photo recording device according to one of claims 8 to 10, characterized in that the display device is connected to a film sensitivity plate. 12. Photo recording device according to one of claims 5 to 9, characterized in that an adjustable switching element of the toggle switch is connected to an aperture plate. 13. Photo recording device according to one of claims 5 to 9 or 12, characterized in that an adjustable switching element of the toggle circuit is connected to an adjustable film sensitivity scale. 14. Photo recording device according to one of claims 3 to 13, in which the exposure process is indirectly carried out by an inhibitor actuated by the trigger, for. B. a flashlight equalizer or a forward mechanism is triggered, characterized in that this inhibitor is a switch operated by an electromagnet, the magnet - preferably switched as a working resistor of a first toggle switch - after the inhibition time, a second toggle switch switches on, which for opening and closing of the lock contains a further electric blocking magnet. 15. Photo recording device according to claim 14, with a sector shutter which is equipped with two sector drive rings running out of the clamping position and controlling the shutter sectors for opening and closing the exposure aperture, characterized in that <Desc / Clms Page number 11> shows that both sector drive rings (226, 232) are held in the tensioned position by locking magnets (248 and 250) of the same type (Fig. 6). 16. Photo recording device according to one of the preceding claims, characterized in that all electronic devices (280, 288, 308) are housed within a self-contained closure housing (210) (Fig. 6). 17. Photo recording device according to one of the preceding claims, characterized in that the power source for the electronic control circuit is housed in the camera and is electrically connected to the electronic devices (280, 288, 308) in the closure (210) via detachable connecting parts (282) ( 6 and 7).