DE1597365B1 - Photographic camera with electronically controlled devices for self-timer recordings and exposure time - Google Patents

Description

In a further embodiment of the invention it is proposed that the one in the collector circuit 5 signal lamp lying on the transistor in the non-conductive state of the transistor flashing periodically Light signals and emits a continuous light signal in the conductive state of this transistor.

A functionally and spatially important

As is known, the functional sequence takes place in a particularly advantageous embodiment of the circuit Such cameras, both during the delay, can be achieved by providing a transit time period between the trigger actuation and sistor, which includes one of the exposure times Beginning of the closure sequence as well as transistor belonging to the control circuit in hand actual exposure process completely noisy from the switching state of the delay device, so that the photographer can be controlled in such a way that the former a self-timer recording no certainty about transistor during the course of the delay time The current state of the functional sequence device remains blocked and thereby the delivery Has. To help the photographer deal with periodic light signals from the lamp Electronic camera of the above type clearly works, whereas this transistor after termination recognizable clues about the functional sequence 20 of the function of the delay device and Zuzu it has already been suggested that a light circuit of the resistor becomes conductive and thus to provide a control that causes both the start and the lamp to emit a continuous light, also the end of the functional sequence of the delay. The invention is illustrated below on the basis of a with indicating device clearly recognizable. In the case of the electronic timing device and electroser Although camera is a display during the 25 ramshackle advance control circuit equipped camera lead time given, but not with the post-closure and two circuit diagrams that take place in more detail Exposure process. When carried out purifies and shown in the drawing. It shows a recording with light-dependent time control under relatively low illuminance, for example self-timer shots prepared shutter in wise a night shot, the photograph has a 3 ° top view with the cover plate removed, does not provide any clue for the duration of the Fig. 2 the circuits of the electronic timing

the closure so that there is a risk of that the camera moves away from the point of view of the picture before the end of the exposure process will.

This deficiency in an electronic camera of the type mentioned at the beginning with the least possible The object of the invention is to eliminate structural complexity. It consists in the arrangement of an

educational device, the delay device and the additional switching device including a signal lamp for flashing light and continuous light,
35 Fig. 3 a further possibility for the formation of the additional switching device with the same structure of exposure time and pre-time control. According to JFig. 1 of the drawing carries a base plate 2 arranged in a lock housing 1

additional electronic switching device, which 40 drive mechanism for the not shown seconds the functional sequence of the delay gates. In the exemplary embodiment, this is the crank direction a different switching state than in the subsequent functional sequence of the time-forming device

and the signal lamp during the ever

Drive formed and essentially comprises a rotatably mounted disc 3, a hinged thereon Thrust pawl 4 and a switching state that is in engagement with this for the delivery of different 45 standing sector ring 5. A driving spring 7 transmits light signals caused. This means that the photographic part of the disc 3 has a clock face after it has been exposed Clues for the functional sequence clockwise rotating movement, whereby the Sekwohl during the lead time as well as in the case of the rotor ring 5, a back and forth movement is excluded Exposure process, whereby the under- leads. In the tensioned position according to FIG. 1 is the Different light signals unambiguous information about the 50 disk 3 by a two-armed release lever 8 give over whether the delay device is still locked by means of an actuating lever 10 from is effective or the exposure process can already be moved out before the blocking position. has to indulge. The shutter drive mechanism is an elec-

A preferred embodiment can be achieved by means of a time-generating device controlled by the electronic switching device, which includes an electromagnetic-mechanical opening, complementary transistors and RC elements. This has a catch lever, which for the purpose of bringing about another 12, which at the end of the opening movement of the switching state, which differs from the previous one, slides a sector ring 5 under the action of a spring from its arm resistance by means of a at the end of the function Sa and is at the front in front of these represents where the delay device actuated 60 is blocked by the shutter drive. Can be switched on after a switch. at a certain time interval, the catch lever 12

In an advantageous development of the invention, the lifting arm; 14 a of an armature lever 14 is also provided that the resistor moves out of the blocking position, so that the sector-emitter-collector path of a transistor is located, ring 5 continue its movement and the sectors' which during the functional sequence of the delay 65 can close again. The armature lever 14 is supported by a non-conductive pin 15 and carries an armature 16. The latter is located and at the end of the functional sequence, a return spring 17 is inevitably connected to a return spring 17 when the lock is tensioned against the load

Electromagnet 18 brought into contact, for which purpose a contact lever 20 is provided, which during the tensioning process is taken along by a pin 3 a of the drive pulley 3 and here the armature lever pivots against the electromagnet.

The above-described shutter arrangement is equipped for the purpose of taking self-timer exposures with a switchable device which also works on an electronic basis and which temporarily delays the movement of the shutter immediately after it has been released. According to the embodiment shown, this device has a three-armed locking lever 22 which, by means of its arm 22 a, can be transferred into the position shown in FIG. 1 against the action of a relay spring 23. In this position there is a locking edge 22 of the locking lever 22 against a flap 5 b of the sector the ring 5. The arm 22 c of the Sperhebels 22, having a d by curved bottom flap 22, a lever mechanism is associated which consists of the two-armed support lever 24 and the coaxially mounted armature lever 26. The levers 24 and 26 are non-positively connected to one another and act as a spring switch. At one end the lever 24 is provided with a tab 24 α on which the locking lever 22 is supported in the locking position. At the other, preferably resiliently formed end of the support lever 24 is a downwardly bent tabs 24 b is provided, which places during the transfer of the lock lever 22 in the locking position shown in Fig. 1 before the flap 5 of the sector ring 5. Furthermore, the armature lever 26 with its armature 27 comes to rest against the action of a return spring 28 on an electromagnet 29.

As already indicated, the switchable delay device works on an electronic basis. For this purpose, the electromagnet 29 of this device is shown in FIG. 2 and 3 included in a transistor flip-flop. This essentially comprises the transistors T ₁ , T ₂ and T ₃ and the .RC element formed from resistor R ₁ and capacitor C _1. Further components of this circuit are the resistors R ₂ to R ₅ , the circuit arrangement of which is shown in FIG. 2 and 3 can be seen.

To control the exposure time, as shown in FIG. 2 and 3 show that a transistor flip-flop is also provided. This comprises the transistors T ₁ , T ₅ and T ₆ , a vRC element formed from photoresistor F and capacitor C ₂ , and a plurality of resistors R ₆ to R ₁₀ . The coil of the electromagnet 18 is located in the collector circuit of the transistor T ₆ .

In the switching circuit of the exposure time control circuit, another transistor T _{1 is} provided, which, in addition to the electromagnet 18, performs the function of a switch. According to the schematic representation in Fig. 2, the switching transistor T _{7 is} connected with its collector-emitter path parallel to the base-emitter path of the transistor Γ _α and connected to the base via a resistor R ₁₁ to the emitter of the output transistor T _{2 of} the lead time control circuit .

The circuits described above are connected to an energy source E by means of a switch S ₁ , which is closed when the lever 10 is actuated. A changeover switch S _{2 shorts the capacitor C 1} in the contact position shown in FIGS. 1 and 2, whereas in the other contact position it produces a parallel connection with respect to the switch S ₁ for the lead time control circuit during the so-called lead time. The actuation of the switch S ₂ takes place by means of a tab 3 b of the drive disk 3. The arrangement is made so that immediately after the disk 3 has started, but before the drive mechanism is locked again by the locking lever 22, the switch S ₂ in the Not shown contact position is turned over and held in this position for the duration of the lead or delay time. The switch S ₃ has the same function with respect to the exposure time control circuit and is actuated by the sector ring 5, for example. The switching of the switch S ₃ from the short-circuit position into the contact position producing the parallel circuit takes place immediately after the sector ring 5 is unlocked by the locking lever 22, but before the switch S ₂ returns to the short-circuit position. By means of a further switch S ₄ , one side of the lead time control circuit can be connected to the energy source E when the shutter is being prepared for taking a self-timer exposure. For this purpose, the one in the arrangement according to FIG. 1 and in the associated circuit according to FIG. 2 designed as a changeover switch S _{4 arranged} in the area of an arm of the locking lever 22 which, in its basic position (not shown) intended for recordings without a lead time, switches this switch in the position shown in FIG. 2 with the dashed line indicated contact position inevitably holds. When the locking lever 22 is moved into the locking position, the contact switch S ₄ automatically changes to the contact position according to FIG. 1 and 2 over.

In addition to the above-described electronic devices for lead time and exposure time, the camera is provided with an additional electronic switching device which includes a signal lamp L. According to the schematic representation in Fig. 2, the switching device comprises a flashing circuit which is formed from two complementary transistors T ₈ and T ₉ , a capacitor C ₃ and a plurality of resistors R ₁₂ to R _u . The filament of the signal lamp L forms the working resistance of the transistor T ₉ . The switching device also contains a circuit which is connected to the input of the flasher circuit and, in the schematic representation according to FIG. 2, includes a resistor R _1S and the aforementioned switch S _4. The electronic switching device is connected to the energy source E via points A, B and C of the lead time or exposure time control circuit.

In order to carry out a recording with a lead time, the locking lever 22 is in the position according to FIG. 1 transferred, the armature 27 being applied to the electromagnet 29 and the changeover switch S _{4 being moved} into the position indicated by a solid line in FIG. 2. When the actuating lever 10 is depressed, the drive pulley 3 is released and at the same time the on-switch S _{1 is} closed, so that the electronic delay device is connected to voltage. The exempt sector ring S runs with its lobes Sb after a short distance s at the locking edge 22 b of the lock lever 22 to the drive pulley 3 flips the switch S ₉ so that on the one hand, the short circuit across the capacitor C ₁ lifted, on the other hand the function

5 6

ability of the circuit even after releasing the With the application of voltage to C after radio

Actuating lever 10 or opening the switch 1S ₁ tion sequence of the delay device receives which _{is guaranteed via the switch S 2.} The condensate base of the transistor T ₈ via the resistor R _1S SaXOrC ₁ is now on the positive potential via the resistor R _1. This resistance is charged off the response value of the transistor T ₁ . If this 5 sets that the transistor T ₈ happened completely over it, the circuit flips over, which in turn is turned on, which has the consequence that the electromagnet 29 also turns on transistor T ₉ when de-energized. This goes, whereby the armature 27 falls off. The locking lever that during the operational sequence of the pre-timing control 22 loses its support on the lever 24 circuit intermittently lighting up the signal and releases the sector ring 5, which lights up continuously when iq lamp L is reached, the open position through the catch lever 12 blocks that lasts as long as the shutter is opened. · remain. With the return of the sector ring 5 in the

With the closing of the power switch S ₁ and the output location is the contact switch S will have been connected to the point B to the power source E _3, short-circuit position of FIG. 2 converted, so so that the flashing circuit on A and B of chip 15 that point B is de-energized and as a result there is voltage, whereas point C is initially still de-energized, the lamp L goes out.

is. The transistors T ₈ and T ₉ are initially in the schematic representation according to FIG. 3 includes

locked. _{The capacitor C 3} is stabilized via the filament of the lamp L and the circuit by means of which the flashing circuit resistor R ₁₂ on the one hand and the resistance A ₁₄ on the other hand, after the function sequence of the delay device, the capacitor C 3 is stabilized, a transistor T ₁₀ , which with its loaded. If the threshold voltage of the Tran base is reached via point D to the collector circuit of the transistor T ₈ , this current begins to draw. Exposure time control circuit belonging to Tran-This means that the potential is connected to the base of the transistor T ₆ . The other circuit transistor T ₉ negative. This now also begins to draw current-moderate arrangement of the transistor T ₁₀ as well as one, which has the consequence that the collector 25 additional resistor A ₁₆ goes from the schematic voltage of the transistor T ₉ drops. Because of the illustration in FIG. 3 emerges. The circuits for the feedback of the collector of T ₉ via the delay device, the exposure time formation resistor R ₁₂ and the capacitor C ₃ on the device and the flashing circuit agree with the base of the transistor T ₈ , the current in these above and in Fig. 2 increases shown in an avalanche-like manner on both transistors until they match. Notwithstanding this, borrowed is fully controlled. The switch, by means of which the delay device L in the collector _{circuit of the transistor T 9,} lights up. device is applied to voltage, as a simple contact-This state is now maintained until the switch is formed and designated in Fig. 3 with S ₅ . Capacitor C ₃ is charged so far that its This switch is no longer sufficient with the transfer of the blocking _ charging current, the transistor T ₈ 35 up to 22 in the blocking position in the inFig. 3 to steer through it. Since the resistor R _{u is} expediently placed contact position, it is selected so large that it is used for a control. 3 ge

tion of the transistor T ₈ can not take place, circuits shown, it behaves so that with the .die circuit back to its starting position, whereby depression of the operating lever 10 of the lamp L goes out again. Now the 40 switch S _{1 is} closed, so that the lamp L in capacitor C ₃ via the resistor A ₁₄ to flash slowly in the same manner described above, and the process described above begins and at the same time the delay repeats itself again. In this way direction in turn becomes effective. During the are with the in F i g. 2 additional switching function sequence of the lead time control _{circuit device as long as intermittent light signals remain 45 due to the effect of the transistor T 6} targetable until the pre-timing control is _{blocked, switching transistor T 7} , whereby the base of the has ended. If this is the case, the locking lever 22 transistor T ₁₀ returns positively to its starting position via the magnetic coil 18, whereby on the one hand the potential is _{retained so that T 10 is} also locked and sector ring 5 is released, on the other hand the reverse thus remains without any influence on the flashing circuit , switch S ₄ to the position shown in FIG. 2 with dashed line 5p After the lead time has ended, the indicated contact position is turned over, in which sistor T _{6 is switched on} and the contact _{switch S 5 is} now also connected to voltage. opened by the locking lever 22. The closure-

The sector drive released by the locking lever 22 now runs in the known manner, with the ring 5 starting up again in order to finally start the sector ring 5 in the open position via a beam catch lever 12. During this specific time it is blocked again. With the movement process, the switch S _{3 is thrown, which by switching the transistor T 6} , the potential on the one hand, the charging of the capacitor C ₂ at the base of the transistor T _{10 is} negative, so that it works, on the other hand, the further application of the water is also controlled. The base of the transistor Punktet and B and the exposure time control T ₈ is therefore ensured via the collector-emitter path circuit with current. This now exercises 60 of the transistor T ₁₀ and the resistor R _le on poihre function, such that after a determinative potential, whereby T ₈ opens and its time interval, the magnetic field in the electromagnet on the part of the transistor T ₉ controls. This state is canceled. This in turn has the consequence that it is retained as long as the lock is opened by the armature lever 14 under the influence of it. This ensures that the intermittent spring 17 rotates and the catch lever 12 inevitably moves the lamp L during the radio out of the blocked position. The sector ring 5 of the delay device then continues its sequence movement and brings the opening of the shutter to a steady light over sectors back into the closed position. goes.

Claims (5)

Patent claims: 1. Camera with an electronic, an electromagnetic-mechanical Open time lock for the shutter drive including, lighting-dependently controllable timing device, a switchable, the movement sequence of the shutter temporarily after it has been triggered blocking, also working on an electronic basis delay device and a signal lamp, characterized by the arrangement of an additional electronic switching device, which during the functional sequence of the delay device has a different switching state than the the following functional sequence of the time-setting device assumes and the signal lamp (L) causes different light signals to be emitted during the respective switching state. 2. Camera according to claim 1, characterized in that the electronic switching device has complementary transistors (T ₈ and T ₉ ) and i? C elements, which, in order to bring about a different switching state that differs from the previous one, a resistor (R ₁ . R ₁₆ ) can _{be switched on by means of a switch (S 4} or 5.) actuated at the end of the functional sequence of the delay device. 3. Camera according to claim 1 and 2, characterized in that the resistor (R _1S or i? _{1 (} .) Is in the emitter-collector path of a transistor (T ₈ ) which is in during the functional sequence of the delay device is in a non-conductive state and changes to a conductive state at the end of the functional sequence by connecting the resistor (R _1. or R ₁₆ ) in parallel to the charging resistor (R _u ) of the i? C elements. 4. A camera according to claim 1 to 3, characterized in that the signal lamp (L) located in the collector circuit of a transistor (T ₉ ) emits light signals that light up periodically in the non-conductive state of the transistor (T ₈ ) and emits a continuous light signal in the conductive state of this transistor. 5. Camera according to one of the preceding claims, characterized in that the electronic switching device includes a transistor (T ₁₀ ) which is controllable by one of the exposure time control circuit transistor (T ₆ ) depending on the switching state of the delay device in such a way that the former The transistor remains blocked while the delay device is running, thereby causing periodic light signals to be emitted by the lamp (L), whereas this transistor becomes conductive after the delay device has stopped working and the resistor (R ₁₆ ) is switched on, and thus the lamp to emit a continuous light caused. 1 sheet of drawings COPY 009 539/325