DE2264905C3 - Arrangement for an electrically controlled camera shutter - Google Patents

Description

The invention relates to an arrangement for an electrically controlled camera shutter of the generic term of claim 1 described type.

Electrically controlled camera shutters have in connection with circuit arrangements for automatic Exposure time control found widespread use. With these, the opening time of the camera shutter automatically depending on the, preferably in the image-side beam path of the camera lens measured object brightness controlled. In addition, electrical camera shutters are also general known, in which the exposure time setting is not automatic, but manual, z. B. over a with the Exposure time knob coupled potentiometer takes place. There are also camera shutters known at which these two types of control are combined so that the exposure time is optional controlled either automatically or manually.

From US-PS 33 03 776 a camera shutter is known in which the automatic exposure time control takes place in a purely electrical way, while the manual exposure time setting is exclusively is controlled by mechanical components. The operating handle for setting the exposure times is connected to a cam disk, by means of which a switch for activating the circuit arrangement can be operated for automatic exposure time control. This switch is open when one of the manually adjustable mechanically controlled exposure

'5 service times is selected

It has been found that with camera shutters, which are electrically controlled both with automatic regulation and with manual setting, Exposure times that exceed a predetermined limit

fall below μ, cannot be realized with sufficient accuracy permit. This has its cause, among other things, in the finite drop-out delay of the electromagnet Control of the closing movement of the camera shutter.

The invention is based on the object of eliminating this disadvantage, that is to say of creating an arrangement with which even very short exposure times can be precisely set. This task is carried out by the im characterizing part of claim 1 mentioned

^M features solved.

This extremely simple circuit intervention ensures that the mechanically controlled exposure times cannot be influenced by the electromagnet.

Thus an influence on the mechanically controlled Exposure time is actually excluded with certainty by the said electromagnet, its anchor must of course drop within a period of time that is shorter than the shortest intended exposure time. If this is not the case due to the design, appropriate measures must be taken be taken to accelerate the armature drop of the electromagnet. A corresponding Further development of the invention is characterized in that an alternating voltage component that one DC voltage converter for feeding the remaining circuit stages is taken from the DC voltage is superimposed on the excitation circuit of the electromagnet to control the closing movement of the Camera shutter feeds. In this way, a particularly rapid drop in the electromagnet can be brought about which not only increases the accuracy of the electrical exposure time control, but also ensures that the mechanical control of the very short exposure time of the Electromagnet is not obstructed.

The control circuit mentioned in claim 1 for influencing the closing movement of the The electromagnet that triggers the camera shutter contains a threshold switch (e.g. a Schmitt trigger or a thyristor), which in turn is a located in the excitation circuit of the electromagnet controllable switching element (z. B. a transistor) controls. To de-excite the electromagnet

^{hi the} latter can be controlled in its non-conductive state. This is done by lowering the potential at its control electrode accordingly. This potential is - as mentioned - from one

Threshold switch, e.g. B. a thyristor supplied The output potential occurring at the controlled electrode of an electronic switch can as a result the finite resistance of the controlled path (e.g. the cathode-anode path of the thyristor) naturally does not drop to the value of the reference potential. To prevent the im Characteristic part of claim 1 described measures caused the control circuit to respond a finite, i.e. non-zero control voltage reduces the de-excitation of the electromagnet delayed, it is proposed according to a development of the invention that in the control circuit of the in the excitation circuit of the electromagnet inserted controllable switching element a threshold value diode is inserted, the threshold voltage is chosen so that this control circuit when the upstream circuit stage completely de-energized and the said controllable switching element with it completely blocked.

In the following, the invention will be explained in more detail with reference to the exemplary embodiment shown in the drawing explained:

The circuit has one of a photoresistor 3, the z. B. in the image-side beam path of the Camera lens is arranged, and a logarithmic diode connected in series with this photoresistor 4 existing light measurement level. The connection point of this series connection leads to a resistor network 5 for the electrical simulation of the remaining exposure parameters, d. H. the film sensitivity and the work panel. The resistor network 5 is powered by a DC voltage converter 1 fed, which can be connected to the battery 17 via a supply voltage switch 16.

A voltage stabilization circuit 6 is used to feed the said light measuring stage and one Control circuit 12, the structure of which will be described below. Via another voltage stabilization circuit 7 a circuit stage 8 is fed for delogarithmization. This circuit stage 8 is connected in the idle state via a switch 10 to the reference potential (ground), which is synchronous with opening the camera shutter. A storage capacitor 9, which is connected between the output of the Resistance network 5 and the switch 1Ü is switched, one stores the object brightness and the others Signal voltage containing exposure parameters (aperture and film sensitivity). In the connection A storage switch 11 is located between the storage capacitor 9 and the resistor network 5 inserted, which is mechanically coupled to the operating mechanism of the camera shutter. The connection point between the storage switch II and the storage capacitor 9 leads via a resistor 9a to said control circuit 12. The control circuit 12 has two outputs. The first exit is connected to a display stage 13. The second output leads via a zener diode 26a to the base of a Switching transistor 14, in the collector circuit of which the control coil of an electromagnet 2 for triggering the Closing movement of the camera shutter is arranged. There is also a switch in this collector circuit 15 inserted, which is coupled to the locking mechanism that it only opens immediately before the camera shutter is closed.

The control circuit 12 consists of two field effect transistors 22 and 26 with their gate and Drain electrodes are connected in parallel to one another. In A variable resistor 23 is inserted into the source circuit of the field effect transistor 22. Of the The wiper 24 of this variable resistor 23 is connected to the control electrode of a transistor 25. The control circuit 12 forms a threshold switch. The response threshold is through adjustment of the grinder 24 can be changed. This grinder 24 is equipped with an adjusting element for manually adjustable exposure times mechanically coupled in such a way that the response threshold by actuating this setting element is lowered so that the thyristor 25 immediately after opening the camera shutter is ignited and thus the transistor 14 comes into its non-conductive state

The circuit also has a potentiometer 32 for manual setting of electrically controlled exposure times. With the help of this potentiometer 31 is off A partial voltage derived from a battery 30. This partial voltage is generated by actuating the switch 11 instead of the exposure parameters (object brightness, working aperture and film speed) Output voltage of the resistor network 5 connected to the storage capacitor.

The mode of operation of the circuit shown is explained below:

After closing the switch 16 occurs at the connection point between the photoresistor 3 and the logarithmic diode 4 has a signal voltage which is indicative of the object brightness. By doing Resistance network 5, this signal voltage is superimposed on a further signal voltage that is used for the other exposure parameters (aperture and film speed) is characteristic. All signal voltages characterize the respective exposure parameters on a logarithmic scale. The storage capacitor 9 is charged to the corresponding total voltage.

The switch 10 is opened synchronously with the opening of the camera shutter. This starts the discharge of the time-determining capacitor in the circuit stage 8, which was previously charged to the output voltage of the stabilization circuit 7. Since the discharge electronics circuit of the time-determining capacitor runs over the diode connected in parallel with it with a logarithmic characteristic, the time profile of the capacitor voltage is logarithmic. As the capacitor discharges, the potential at the right-hand assignment of the storage capacitor 8 rises.

This potential forms the control signal for a field effect transistor 22, which serves as an impedance converter. The output voltage occurring at the tap 24 of the potentiometer 23 forms the control signal for the Thyristor 25. As soon as this thyristor 25 with progressive discharge of the time-determining capacitor ignites, the switching transistor 14 is blocked immediately and the control coil 2 in its collector circuit becomes currentless. The in the connection between the anode of the thyristor 25 and the base of the

Zener diode 26a inserted in the switching transistor 14 ensures that the latter is actually completely blocked and is not further influenced by the finite value of the anode potential of the thyristor 25. By blocking the switching transistor 14 \ v ^; rd the electro ^h > magnet 2 switched off, so that its armature falls off and releases the expiration of the closure member, through which the film window is closed again.

The DC voltage converter 1 is designed so that

it superimposes an alternating voltage component on the direct voltage of the battery 17 that feeds it. This alternating voltage component causes the electromagnet ?. when the switching transistor 14 becomes de-energized, it drops more rapidly, since it accelerates the reduction of the magnetic field.

The circuit arrangement described controls exposure times that are longer than 1/500 s, for example with very great accuracy. The accuracy with shorter exposure times, for example 1/1000 s, te would be affected, particularly by the inevitable delay time of the electromagnet 2. That's why these very short shutter speeds are controlled mechanically. It must be ensured that the electrical control circuit cannot exert a delaying influence. This is achieved through this that the sliding contact 24 is coupled to the setting member for the mechanically controllable shutter times in such a way that the response threshold of the control circuit 12 is lowered in such a way that it is already immediately is actuated by the output signal of the resistor network 5.

1 sheet of drawings

Claims (3)

Patent claims: 1. Arrangement for an electrically controlled camera shutter, in particular for a one-eyed one Single lens reflex camera, with a control circuit for influencing the closing movement of the Camera shutter triggering electromagnet, by means of which the exposure time either through the output signal of a photoelectronic component for measuring the brightness of the object or manually by means of a signal voltage that can be set by means of a corresponding operating handle is controllable, characterized in that that a switching element (23) is provided with the operating handle for the manual adjustable exposure times is mechanically coupled and when they are set to exposure times, which has a specified limit value (1 / 50Os) fall below, a reduction of the response threshold of said control circuit (12) to Influencing the electromagnet (2) causes such that the excitation circuit of this electromagnet (2) at the latest immediately after opening the camera shutter in its non-conductive State reaches, and that the closing movement of the camera shutter in the said Exposure times below the limit value is controlled mechanically. 2. Arrangement according to claim 1, characterized in that a DC voltage converter (1) for Supply of the control circuits (3, 4; 8, 9) provided for automatic exposure time control and that an alternating voltage component which can be removed from this direct voltage converter (1) the excitation circuit of the electromagnet (2) to trigger the closing movement of the camera shutter feeding DC voltage (voltage of the supply battery 17) is superimposed. 3. Arrangement according to claim 1 or 2, characterized in that in the control circuit one in the Excitation circuit of the electromagnet (2) inserted controllable switching element (14) a Threshold value diode (26a) is inserted, the threshold voltage is chosen so that this control circuit when the upstream switching stage (25) becomes effective, it is completely de-energized and that said controllable switching element (14) is thus completely blocked.