DE1155009B - Electromagnetic shutter - Google Patents

Description

Electromagnetic shutter The invention relates to a so-called shutter, which makes it possible to take exposures in quick succession to be carried out, without it being necessary, beforehand in the usual manner to cock the lock. As a closure member in the beam path of the optics is here a single slat used by an electromagnetic system - preferably a moving coil relay - is driven and which contains a wedge-shaped slot. Such a diaphragm blade moved by a moving coil system is already known, however, the previously known arrangement only serves to depend on the lens diaphragm of the relatively slowly changing measured variable (namely the object brightness). However, this arrangement cannot be used as a closure.

On the other hand, there is a similar moving-coil operated lamella arrangement known, which is also from the current of a photo element, which is the influence of light measured object is influenced. By moving the slat is intended the lens opening more or less long depending on the object brightness Time to be released for exposure. The actual lens aperture is included to operate in the usual way with the help of another setting member.

Apart from the two known arrangements described here, in which the movable lamella in the objective beam path is controlled by an electromagnetic one System is operated, which is fed directly by the current of a photo element are Other arrangements have also been proposed in which the energy to Drive a shutter or a lamella, which a photo element is only in the extreme to a small extent is able to generate with the help of an external power source powered electrical circuit is obtained. One such suggestion uses a Capacitor-resistor combination as a measuring element for the required exposure time, the arrangement being such that one is exposed to the light of the subject Photo cell charges a measuring capacitor until the ignition voltage of a glow tube is exceeded. This point in time is considered to be the criterion for the extent of the required Exposure. In terms of the circuit, a relay is then actuated, which at the beginning the opening of the measuring process closes again by means of an electromagnet. This facility can also only be used for certain tasks; z. B. is suitable only for longer exposure times, from about half a second upwards to any longer exposures. It is therefore for the solution of the present Task that deals specifically with the achievement of shorter exposure times for dealing with the usual still cameras, not suitable.

The invention shows a new way of automatic exposure control of photographic cameras. It is characterized by the combination of a (or several) known per se, movable by means of an electromagnetic system Shutter blade, which contains a wedge-shaped slot, and an electrical one RC element, the time constant of which is determined by a light-sensitive element, which is subject to the influence of the light emitted by the measured object, wherein the electrical circuit is dimensioned and with the electromagnetic System interacts in such a way that it emits a short current pulse at high illuminance levels or two directly consecutive and oppositely acting short current impulses and with low illuminance a long current pulse or two consecutive ones and counteracting long current impulses, all impulses one have predetermined, approximately the same height.

In another solution that is based on the same principle, have the pulses one predetermined for each illuminance of the photosensitive element Height, which is lower, the longer the pulse in question.

A measuring capacitor charged or to be charged to an approximately constant potential serves as a reference variable for the length of the pulses, the charging or discharging time of which is determined by the variable resistance of a light-sensitive element exposed to the measuring beam path. The resulting from this by means of further electrical switching elements, for. B. Relay, transistors, diodes, etc., the electrical pulse obtained is fed to an electromagnetic system, the movable member of which drives the movable lamella in the lens beam path. The size of the electrical impulse is determined by appropriate dimensioning of the electrical members so that the lamella provided with the wedge-shaped slot is only accelerated briefly and then returned to the closed position of the lens by an oppositely directed torque. At low luminance levels, on the one hand, the clear opening of the lens is completely released and, on the other hand, a long exposure time is achieved. At high luminance levels of the light-sensitive element, the shutter works in the opposite way: The generated electrical impulse causes a relatively strong torque of only a very short duration, so that the lamella only swivels a little into the lens beam path with the narrow part of the aperture slit and then swings through it immediately a correspondingly strong, oppositely directed impulse is fed back into the closed position of the lens.

In order to achieve a favorable opening area for the beam path, can either be fixed or swing-out diaphragms in the lens in a known manner be provided, or there can be several electromagnetic rotary systems, each with one Lamella are arranged, which are subject to the same pulse at the same time. It is also possible from only one electromagnetic system directly or indirectly in known Way to drive several lamellas, for example by means of form-fitting clutches any gear.

The moving part of the measuring mechanism is required for the present application In principle there is no mechanical restoring torque because the lamella is already in the rest position is held at the stop by an electromagnetic torque. However it is expedient to provide a low leveling force anyway, since to restrict the Power consumption when the camera is not in use, the power supply is switched off.

Furthermore, an auxiliary lock can be provided with the trigger is coupled and the lens beam path just before the actual electrical Triggering the exposure opens. The opening time of this auxiliary shutter is expediently chosen so that all with the electromagnetic shutter adjustable exposure times are certainly shorter. So one seems The opening time of the auxiliary shutter is appropriate between 1 / 2s and 1/2 of a second.

The invention is based on the drawing and some exemplary embodiments explained in more detail. In Fig. 1 is the basic circuit diagram using a relay shown as a switch; Fig. 2 and 3 show further circuit options below Use of transistors as switches.

According to FIG. 1, the winding is in the working circuit of relay 1 2 of an electromagnetic system, for example a moving coil relay, on its movable member attached with the wedge-shaped slit lamella 3 is. In the rest position shown, the lamella 3 is in the direction of the Arrow 4a flowing current held in the closed position, so that the lens opening 5 is closed, the control winding of the relay 1 being energized at the same time. If the trigger 6 is pressed, the control winding of the relay is activated of the capacitor 7 initially de-energized, so that the contact 1 a of the relay 1 is the dashed drawn position assumes. This changes the direction of the current in winding 2 in The polarity is reversed in the direction of arrow 4 b, so that the lamella 3 accelerates in the opening direction will. With the increase in the voltage across the capacitor 7, the Zener voltage is now exceeded again at the diode 8, so that the winding of the relay is again energized is, whereby the contact 1 a of the relay 1 returns to the initial rest position. In this contact position, the polarity of the feed current of the measuring mechanism winding is reversed, so that the lamella 3 is returned to the rest position shown. Parallel to the capacitor 7 is the high-resistance resistor 28, via which the charge is carried out after Lock actuation can flow. The height of the impulse, which the measuring mechanism to Swing out caused is given by the level of voltage of the battery 9 while the length of the pulse is determined by the time behavior of the RC element, the is formed by the photoresistor 10 and the capacitor 7. Here is the beginning of the pulse clearly by pressing the trigger 6, d. H. by closing of his contact. The end of the impulse, however, is when it is exceeded the relatively precisely defined Zener voltage of the diode 8 is determined.

At low illuminance levels, the photo resistor 10 has a high resistance, so that the length of the pulse is great. This behavior is used when switching according to FIG. 1 to achieve a large aperture in combination with a long shutter speed. A given pulse height is a certain acceleration of the measuring mechanism 2 assigned. Since now the length of the lamella 3 described Path at a given acceleration depends quadratically on the time in which the acceleration is effective, are with a certain construction of the measuring mechanism (maximum deflection angle) and constant pulse height the exposure time and the The size of the aperture is only a function of the intensity of the photo resistor striking light.

The circuit according to FIG. 2 is so constructed and equipped that relays of the usual type, which the known disadvantageous properties, in particular the delaying effect can be avoided. In the circuit there are two Transistors 21 and 22 are used, through which the exposure time by simultaneous Control of the pulse height is influenced in relation to the pulse length, so that opposite the circuit of FIG. 1 a more favorable distribution of the effective aperture and Shutter speed factors is achieved.

In the rest position, the base of the transistor 21 is at negative potential, so that a certain emitter-collector current flows. As a result, the collector lies of transistor 21 at a higher potential than the collector of the transistor 22. As a result, the transistor 22 is blocked. As a result of this potential difference flows through the measuring mechanism winding 2, a current in the direction of arrow 4b, so that the Lamella 3 in the rest position, for example on one Stop is present. If the switch 6 is now closed by means of the trigger, as a result of the instantaneous occurring high voltage drop at the photoresistor 10 the base of the transistor 21 brought to positive potential so that transistor 21 blocks. This lies the base of the transistor 22 via the photoresistor 25 at negative potential, whereby this transistor is turned on. The direction of the current in the measuring mechanism is reversed move in the direction of arrow 4 a. The lamella is accelerated in the opening direction. If the voltage on the Zener diode exceeds the charging process of the Capacitor the Zener voltage, then the Zener diode becomes conductive again, and the base of transistor 21 carries current. As a result, collector current flows in transistor 21 again. Transistor 22 is blocked and the current in the measuring mechanism winding is reversed the direction of arrow 4 b around. The slat is in the opposite direction accelerated to the rest position. This process is due to the pronounced Zener knee leaps and bounds in front of you, resulting in a pronounced square pulse.

The length of the opening pulse is also in this circuit (as in the one shown in Fig. 1) determined by the time behavior of the RC element that consists of the photoresistor 10 and the capacitor 7 is formed. The photo resistor 10 and the further photoresistor 25 are in the base circuit of the transistors 21 or 22, so that the base currents are dependent on the size of these resistors and thus also the height of the impulse. A large resistance value of the photo resistors, the way it is at low illuminance is not just a big one Pulse duration, but also at the same time a small pulse height, i. H. low acceleration assigned to the lamella. This measure ensures that the effective on the measuring mechanism Acceleration decreases with increasing pulse time, increasing the range of possible Exposure times compared to the embodiment of FIG. 1 is increased.

3 shows a monostable multivibrator, the pulse duration of which and pulse height can be changed by changing two photo resistors at the same time are. In this form, it is in comparison with the bridge circuit shown in FIG an improvement, as now the two partial windings of the measuring mechanism directly as Collector resistances are connected. This eliminates the formation of voltage differences that have been common up to now avoided at the collector resistors, whereby the efficiency is about the Increased six times.

In the idle state, transistor 21 is blocked because it has a resistor 26 is at positive potential. Transistor 22 receives over the base and the photo resistor 25 negative potential and is therefore fully controlled. As a result, overflows the emitter-collector path of this transistor and the partial winding 2a of the electromagnetic System a stream which is directed so that the lamella 3 in the closed position a stop is held. If the release button 6 is now pressed, the Base of transistor 21 due to the effect of capacitor 27 briefly negative Potential, which causes the transistor 21 to conduct collector current, whereby at the Part winding 2 b a voltage drop occurs. This potential increase is over the capacitor 7 transferred to the base of the transistor 22, so that this is closed will. This reduces the voltage drop across the partial winding 2a, and the base of the Transistor 21 receives negative potential via the photoresistor, causing this The transistor is also turned on after the trigger pulse has ended. It flows now current in the partial winding 2 b, which the locking lamella in the opening direction accelerated. However, the switched state is only of limited duration. It's loading namely, the capacitor 7 via the photoresistor 25, so that the base of the transistor 22 again receives negative potential.

The transistor 22 is turned on, the partial winding 2a is again current flows through it, and the lamella is moved into the closed position. The return switching to the rest position takes place again in the form of a tilting process. Included the time that passes between the two switching processes is only determined by the time constant of the RC element, consisting of capacitor 7 and photo resistor 25. From the operation of the circuit it can be seen that the shutter speed depends on the resistance value of the photoresistor 25 and thus depends on the illuminance.

If instead of the previously assumed photoresistors, for example or photocells for special applications, photo elements are to be used, that is, light-sensitive elements that are able to supply electricity themselves the circuit is made so that the current supplied by the photo element is used as the base current is used to control a transistor, which in turn discharges or charges of the measuring capacitor controls.

To take other exposure factors into account - for example the film speed - is provided, the photoresistor (s) behind a Arrange aperture or a continuously variable filter by adjusting it the desired attenuation of the light falling on the light-sensitive elements is achieved.

Claims (7)

PATENT CLAIMS: 1. Electromagnetic shutter, featured by combining one (or more) known per se, by means of an electromagnetic System movable shutter blade, which contains a wedge-shaped slot, and an electrical RC element., whose time constant is determined by a light-sensitive Element is determined which has the influence of the radiated from the measured object Subject to light, the electrical circuit being dimensioned and with the electromagnetic system interacts in such a way that this is at high illuminance a short current pulse or two directly consecutive and opposite Acting short current impulses and with low illuminance a long current impulse or two directly consecutive and oppositely acting long current pulses receives, with all pulses having a predetermined, approximately the same height. 2. Electromagnetic Shutter, characterized by the combination of one (or more) known shutter blade movable by means of an electromagnetic system, which contains a wedge-shaped slot, and an electrical RC element, whose time constant is determined by a photosensitive element, which is subject to the influence of the light emitted by the measured object, the electrical circuit is dimensioned and with the electromagnetic system cooperates in such a way that it generates a short current pulse at high illuminance levels or two directly consecutive and oppositely acting short current impulses and with low illuminance a long current pulse or two consecutive ones and receives oppositely acting long current pulses, the pulses for each Illuminance of the photosensitive element have a predetermined level, which is the smaller, the longer the impulse in question is. 3. Electromagnetic Shutter according to Claim 1, characterized in that the capacitor of the RC element to an approximately constant before triggering the exposure process Voltage is charged. Its charge after triggering via a. photosensitive element, preferably a photoresistor, drains, whereby the electromagnetic by means of a relay System receives a current pulse that is opposite to the closed circuit Causes torque, the pulse lasts until the capacitor is charged has dropped to a predetermined value. 4. Electromagnetic shutter according to claim 2, characterized in that the electromagnetic system influencing impulse (or the oppositely directed impulses) by means of a Transistor flip-flop is generated (or are), where in, each base circuit of the A light-sensitive element is connected to transistors. 5. Electromagnetic Aperture shutter according to Claim 4, characterized in that in the base circle at least one transistor in series with the light-sensitive element, a diode is switched with a pronounced zener knee. 6. Electromagnetic shutter according to claim 5, characterized in that in series with the one in the base circle Transistor lying photoresistor on: switch and a capacitor connected are, so that at. Closing the switch changes the base bias of the transistor takes place, the capacitor being replaced by a high-value resistor is bridged. 7. Electromagnetic shutter according to claim 1 or 2, characterized in that a moving coil relay or galvanometer is used as the electromagnetic system, on whose moving coil the lamella provided with the wedge-shaped slot is attached. B. Electromagnetic shutter according to claim 1 or 2, characterized in that a shutter release with the camera. Cooperates switch, which only applies voltage to the electrical circuit when it is actuated. 9. Electromagnetic shutter according to claim 8, characterized in that an auxiliary shutter cooperates with the trigger, which releases the lens beam path before initiating the actual shutter actuation and closes it again after completion of the same. 10. Electromagnetic shutter behind. Claim 9, characterized in that the auxiliary closure has a constant which can be between 1 / 2s and 1 / z of a second. 11. Electromagnetic shutter according to claim 1 or 2, characterized in that with the movable, the wedge-shaped slot containing a blade in the. Objective beam path fixed or movably arranged aperture interacts. 12. Electromagnetic shutter according to claim 1 or 2, characterized in that two or more mutually engaging lamellae are moved by the electromagnetic system. 13. Electromagnetic shutter according to claim 1 or 2, characterized in that two or more electromagnetic systems, each with a lamella, are influenced by the electrical pulse at the same time. 14. Electromagnetic shutter according to claim 1 or 2, characterized in that an electromagnetic system drives several slats directly or indirectly by means of form-fitting clutches or a transmission. 15. Electromagnetic shutter according to claim 2, characterized in that the winding of the electromagnetic system is provided with a center tap, wherein the two partial windings (2 a and 2 b ) are alternately traversed by the collector current of the transistors (21) or (22) and so dimensioned are that they also represent the collector resistance. 16. Electromagnetic shutter according to one of the preceding claims, characterized in that the current supplied by a photo element is used to control a transistor which controls the discharging or charging of the measuring capacitor. Documents considered: German Patent No. 711644.