DE2253000A1 - MIRROR REFLEX CAMERA - Google Patents

Description

Single lens reflex camera The invention relates to a single lens reflex camera with adjustment of the aperture by a photoelectric arranged behind the lens Converter.

The purpose of the invention is to provide an arrangement in which the adjustment of the diaphragm takes place so quickly that the control process is practically simultaneous can be initiated with the release of the shutter without any delay in the Beginning of the actual exposure cycle until the end of the aperture control is required by an inhibition.

Another object of the invention is the diaphragm setting process directly from to control the aperture depending on, regardless of the stroke of the shutter drive. This results in the possibility of automatic adjustment with interchangeable lenses to the different starting openings and the different Strokes of the diaphragm adjustment plunger. So it is not an adaptation of the interchangeable lenses required with regard to the basic position and stroke of the lens diaphragm plunger on the camera, as with cameras in which the path of the diaphragm plunger is in the immediate geometical Relationship to the aperture.

According to the invention is a by means of a separate measuring button or by Independent drive for the lens diaphragm that can be released by the shutter release provided, as well as an electronic comparison circuit controlled by the photoelectric converter which stops the diaphragm actuator or a Gives impulse to shut down the shutter drive. Next is the subject of the invention the application of this diaphragm drive to cameras with interchangeable lenses, their Aperture can be adjusted by means of a plunger from the camera.

Further details emerge from the following description and the subclaims.

The aperture setting process is when the measuring button is pressed same as when the shutter release is actuated, only the measuring relationship is established Aperture adjustment process when pressing the measuring button with Aperture setting finished, and when the measuring button is released, the starting position is restored. When the shutter release is pressed, the metering and aperture setting process is activated in carried out in the same way and.

the exposure cycle of the camera triggered. So there is none Storage and it is also not necessary because the aperture setting is at Actuation of the trigger takes place immediately before the closure sequence, independently whether and how often the measuring button was pressed beforehand.

The measuring button is used to assess the depth of field, as in a so-called dark measurement, and to display the aperture to be expected. Here a detachable independent drive for the lens diaphragm is required, which allows any repetition of the measuring and setting process, for example an electromagnetic or electromotive drive.

If a mechanical drive is selected, for example one for the shutter lift or spring tensioned by the film circuit, then the aperture setting according to the invention must be limited to the actuation of the release button, and the measuring button for a light measurement be assigned to the fully open aperture; the expected ones are displayed Diaphragm through a galvanometer.

Error or omission of calibration or adjustment of the instrument display the lens used can lead to incorrect display of the expected Aperture lead; at the exposure-correct automatic aperture setting respectively However, this does not change the aperture setting when the shutter is released.

A very fast working arrangement with a fast switching Photodiode or the silicon photocell works, is in Figure 1 in their essentials Components and is described based on their mode of action. In the Figure 1, 1 denotes the light receiver, i.e. preferably the silicon photocell, 2 a resistor, 3 the variable resistor, which over time and the sensitivity setting is connected, 4 the display instrument, 5 the comparator, 6 the switch, which through the measuring button or the trigger is pressed, 7 the switch, which is only activated by the Trigger is pressed and 8 the battery.

By turning on switch 1, the circuit is connected to the battery 8 connected. Under the influence of the incident light arises in the photoelectric Converter 1 a photocurrent, which causes a voltage drop U1 across resistor 2. The voltage U2 is generated at potentiometer 3.

The voltage U1 corresponds to the measured actual value and U2 represents the Illuminance setpoint. The difference between the two voltages is indicated by the instrument 4. With an appropriate scale, this The expected f-stop value must be used in the instrument. The voltages U1 and U2 go to the inputs of the comparator 5. This measurement takes place with the open Aperture (light measurement); under normal lighting conditions and with the appropriate setting of the potentiometer 3, the voltage U1 is greater than the voltage U2.

When the shutter is released, the switch 7 is closed, whereby the electromagnet 9 is connected to the battery 8. As long as the voltage U1 the Voltage exceeds U2, this magnet remains de-energized; the one released at the same time Diaphragm drive, which is described below in exemplary embodiments; closes the aperture, whereby the photocurrent and thus the voltage U1 drops. At this moment, where the voltages U1 and U2 become equal, sharp; the comparator 5 tet the magnet M a, who then stops the diaphragm drive by either turning the diaphragm drive interrupts, or stops directly by locking.

A modified form of the circuit is shown in FIG. the Function of the display instrument 14 and the comparator 15 is the same as to Figure 1 described. The photocurrent of the photo element 11 is through the Operational amplifier 20, which is connected to the resistor 21 in a known manner as a current voltage amplifier is converted into a voltage level at the output of the operational amplifier 20. The resistors 22 and 23 form the reference level for the positive input of the operational amplifier 20. The potentiometer 13 is again used to introduce the exposure time and film speed into the circuit.

The switches 16, 17 as well as the magnet 19 and the battery 18 are in switched on with the same mode of operation. The advantage over the embodiment According to FIG. 1, the main thing is that the photoelectric converter 11 is operated almost exactly in short circuit, and that the current through the display instrument does not burden the photo current.

Both examples are based on diaphragm drives that, when actuated of the trigger are released, then run automatically and when the Orifice setpoint stopped by an electromagnetically actuated lock or brake will.

The electric drive of the aperture setting can be based on the same principle can be switched on and off and additionally by an electromagnetically actuated Lock or brake are stopped.

If the diaphragm actuator is not mechanical, for example by a drive spring tensioned when the shutter is tensioned or by the film circuit takes place, but is effected electromagnetically or by an electric motor, -can also the switch 7, 17 can be operated by the measurement button, so that also with the correct aperture is set during the measurement, so-called dark measurement, the allows a direct assessment of the depth of field.

Finally, the arrangement can also be made so that when you press the measuring button only the switch 6 or 16 is closed, so that a Brightness measurement takes place while the shutter release is equipped with a pressure point, so that when pressing the shutter release button to the pressure point of switches 7 or 17 is closed, from which a dark measurement results. If the trigger is via the If the pressure point is actuated, the aperture setting takes place immediately the actual shutter release and exposure of the film.

Figures 3 and 4 are block diagrams of two embodiments shown, which work on the principle mentioned that when reaching the setpoint the shutter the drive is switched off. The photocell 21 is with the bridge 22 connected to the zero voltage discriminator 23, which switches the clock generator 24 on and switches off when balancing the bridge. The clock activates the stepper motor 25, which actuates the rack 27 by means of the pawl 26, which in turn drives the plunger the aperture causes.

In Figure 4, a variant is shown in which the linear motor 25 'by means of the pawl 26' actuates a gearwheel 27 ', of which the actual Plunger drive, for example via a spiral curve, is derived.

In Figure 4, a further detail of the rack drive is shown. The rack 37, which is indexed by the stepping pawl 36, has an inclined surface 38 which moves the diaphragm adjustment plunger 39.

The return spring 40 is tensioned in the process. The system is powered by the Latch 41 held in the respective switching position. When you let go of the measuring or Release button, the drive motor or solenoid 42 is de-energized, so that the spring 14 pulls the rod 37 back into the rest position after the return pawl 41 excavated st. It is evident that the straight Schiltstange 37 and the straight In the case of a rotary system, the approach curve 38 is designed as a circumferential curve, for example as shown in FIG are.

Claims (2)

Claims 1. Single-lens reflex camera with adjustment of the aperture through a rear the lens arranged fötoelectric transducer, characterized by a means a separate measuring button or by the shutter release releasable independent Drive for the lens diaphragm, as well as one controlled by the photoelectric converter electronic comparison circuit that drives the diaphragm when the diaphragm setpoint is reached stops or gives an impulse to stop the shutter drive. 2. SLR camera according to claim 1, gekennzeichhet by the Use on cameras with interchangeable lenses, the aperture of which is controlled by a plunger can be set from the camera.