DE2509497C3 - Photographic or cinematographic camera - Google Patents

Description

The invention relates to a photographic or cinematographic camera with a supply voltage source and having an exposure control device operating between an upper and a lower supply voltage.

Increasingly, mechanical Steuerbzw. Control devices by electronic circuits such as exposure control devices, etc. Such exposure control devices work correct in a voltage range between the full battery voltage and a lower battery voltage value. This voltage range depends on the batteries to be used, the voltage of which decreases slowly with use. But batteries that are as good as new also lose capacity at low temperatures, so that their voltage drops sharply compared to its open circuit voltage. Since now electronic exposure control devices below a given lower supply voltage no longer work properly, which is particularly If MOS circuits are used, this should be the case with photographic or cinematographic Camera of the type mentioned, the task of taking measures to ensure that an otherwise Exposure control circuit operating between a lower and an upper battery voltage, even with voltage values, which are lower than the lower battery voltage, is still working properly.

The object is achieved in that the supply voltage source is a battery and comprises a known DC voltage converter, in the supply circuit of which a control stage is provided with a one from the battery voltage or from the converter output voltage dependent control voltage generating actual value stage is connected, which has a threshold value stage, which is controlled through when the battery voltage can be controlled through the converter output-side supply voltage Threshold level side lower supply voltage reaches that when switching through the Threshold level of the DC voltage converter is blocked that the battery-side converter input is connected to the converter output via a current path containing a blocking agent and that the Locking means is activated when the battery voltage is greater than the converter output side lower Supply voltage value. This has the advantage that with battery voltage values that are lower are than the lower supply voltage value at which the exposure control circuit is still working properly it is possible to amplify this low level by means of the DC voltage converter Voltage values. The voltage converter is only switched on when the battery voltage has dropped to a pin value that is smaller than that lower value of the supply voltage. At battery voltage values that are lower than the lower When the battery voltage drops, the supply voltage drops from the lower supply voltage value the DC / DC converter is increasingly turned on towards low values, and thus the Boosting effect increases with the effect that the supply voltage does not decrease. This is up to a lower battery voltage value possible at which the DC-DC converter is still used to generate the The lower supply voltage on the converter output side is working properly.

The use of DC voltage converters in supply voltage devices is already in place known. However, the DC-DC converters in such known devices are used to reduce a

Ncnn battery voltage to a desired value amplify, as is the case, for example, with electronic flash units to generate a high ignition and Burning voltage is the case. In known control devices, DC voltage converters are also used to in order to generate an almost constant output voltage, which as a result of the voltage fluctuations the battery and as a result of the load fluctuations without the use of a DC voltage converter is not achievable.

The photographic or cinematographic camera according to the invention is now designed so that their electronic exposure control device or exposure control device basically no voltage amplification makes necessary because the circuit arrangement is matched to conventional batteries is. Furthermore, the circuit arrangements for electronic exposure control or Regulation in photographic or cinematographic cameras usually does not have any fluctuations in performance subject.

Further advantages of the photographic or cinematographic camera according to the invention are included therein see that the risk of failure at low temperatures is greatly reduced.

In this way, a film can be filmed through to the end without having to change the batteries in between Need to become. When using integrated modules in connection with storage elements there is also the advantage that there is no need to replace the batteries The memory is erased. Another advantage is that the output voltage of the DC-DC converter within the voltage range between the upper and lower supply voltage remains.

This also means there is a risk of a possible overload due to excessive supply voltage avoided. With the help of the control stage, the supply voltage of the voltage converter is advantageously regulated. Between the battery voltage zero and the lower battery voltage limit V'crt the control stage is controlled so that the supply voltage of the DC voltage converter is equal to the battery voltage.

According to a further embodiment, the supply voltage is above the lower battery voltage limit value of the DC / DC converter kept constant with the help of the control stage and the actual value stage, wherein the voltage converter is switched off when the battery voltage exceeds the converter output voltage exceeds and at the same time an otherwise blocked current path between converter input and converter output is controlled. This has the advantage that on the one hand the power consumption of the DC voltage converter is kept low and that, on the other hand, by keeping the converter output voltage constant this is independent of the battery voltage. By keeping the supply voltage constant of the voltage converter, its current consumption is constant and therefore independent of the battery voltage. Another advantage can be seen that when the battery voltage is the lower Supply voltage exceeds, the voltage converter through the control stage and the actual value stage is turned off. The battery then takes over the supply for the electronic exposure control device.

According to a further embodiment, the actual value stage comprises a transistor connected to the converter output and a voltage divider containing a zener diode, the zener diode in the base-collector side Divider branch is arranged and wherein the control stage has a transistor whose base with the Collector of the actual value transistor is connected. This has the advantage that the actual value transistor and the control transistor is only effectively controlled after the threshold voltage of the Zener diode has been exceeded will. The knee voltage of the Zener diode (its threshold value) determines the lower battery limit voltage. The fact that the actual value transistor is connected to the converter output continues to result the advantage that the output side load fluctuations in the exposure control device on the Have a regulatory effect on the tax level.

A diode is advantageously arranged between the converter input and the converter output. When the battery voltage exceeds the converter output voltage, the diode becomes conductive, so that the battery voltage acts directly on the exposure control device and automatically the converter is switched off. '

According to a further embodiment, the DC / DC converter is a chopper, the transistor of which with the Control transistor is connected in series.

The battery is advantageously connected to the by means of a switch which can be actuated by a release relay DC-DC converter can be connected, the switch simultaneously in the circuit of a film drive motor located.

In the following the invention is based on one in the Figure illustrated embodiment; described.

The figure shows a DC voltage converter in connection with an exposure control circuit. According to In the figure, 1 is a drive device for the film transport of a cinematographic camera, and 2 a DC-DC converter and 3 denotes an exposure control circuit.

The drive circuit 1 has an electronic trigger switch that can be switched on by a trigger switch 4 5 through which a relay 6 can be actuated. A contact 7 of the relay 6 is in the circuit of a Film drive motor 8, in the circuit of which a speed controller 9 is also arranged.

A power switch is at 10 and a battery at 11 designated.

The DC voltage converter 2 can be connected to the battery II through the relay contact 7. the DC voltage converter 2 has a transistor 12, in whose collector circuit the primary winding 13 a converter 14 is arranged. A first secondary winding 15 of the converter 14 is located in the Base circuit of the transistor 12. The winding 15 is connected in series with a resistor 16. A Capacitor is denoted by 17. A second secondary winding 18 is connected to a diode 19, which serves to rectify the alternating voltage. The AC voltage on the converter output side is smoothed by a smoothing capacitor 20. A direct voltage is thus applied to the capacitor 20.

In parallel with the capacitor 20 is the series connection of a Zener diode 21, a resistor 22 and one further resistor 23 switched. A tap between the two resistors 22 and 23 is with the Base of a transistor 24 connected, in the collector circuit of which a resistor 25 is provided and

whose collector is connected to the base of a control transistor 25, the collector-emitter path in the Emitter circuit of the converter transistor 12 is provided.

Via a diode 26, the battery 11 is directly connected to the Converter output on the DC voltage side can be connected.

The exposure control circuit 3 connected to the output of the DC voltage converter 2 has a light-sensitive voltage divider 27 and 28 and a fixed voltage divider 29 and 30. Both Voltage dividers are connected to a differential amplifier 31, which is a voltage discriminator circuit 32 is connected downstream. From the output of the discriminator circuit 32 leads a first, the run signal defining Connection to a pulse generator 33 and a second line which determines the direction signal a stepper motor control circuit 34. The output of the pulse generator 33 is also connected to the stepper motor circuit 34 connected. From this stepper motor control circuit 34 four connections go to corresponding ones Windings 35, 36, 3, 7 and 38 of a stepping motor 39. By means of the armature 40 of the stepping motor 39 is a diaphragm 41 adjustable in front of the photoresistor 27.

By means of a timer circuit 42, which is also connected to the converter output, the electronic Trigger 5 controllable. A selector switch 43 can be used in a manner not shown various time programs, such as B. Self-timer recordings, single picture recordings, automatic title recordings and perform time-lapse recordings.

As long as the engine is not running, the battery voltage is hardly loaded by the electronics, so that the Battery voltage is significantly higher than in the case of load. The electronics for triggering the The motor is fully functional even without a converter.

The way it works is now as follows:

It is assumed that the voltage of the battery has decreased to low levels. It is also assumed that the relay 6 and the motor 8 can still be actuated at this low battery voltage. Accordingly, after the switch 10 is closed, the battery 11 is connected to the DC voltage converter via the relay contact 7. This oscillates at its own frequency and, depending on the converter size, generates a DC voltage that is higher than the battery voltage. Since the Zener diode 21 is blocked when the battery voltage is low and the converter output voltage is consequently too low, the transistor 24 is also blocked. As a result, the control transistor 25 is turned on, so that d ^; e supply voltage for the flyback converter is equal to the battery voltage less the collector input throughput voltage.

If the battery 11 now has a voltage which is equal to the lower battery voltage limit value, then so the voltage at the output of the DC / DC converter is equal to the lower supply voltage for the exposure control circuit 3, at which voltage the exposure control circuit still works properly. With this supply voltage at the converter output, the Zener diode 21 begins to be current-permeable so that a voltage drops across resistor 23,

which after the base-emitter threshold voltage of the transistor 24 is exceeded, this begins to open. The result is that the control transistor 25 begins to be blocked. Takes off the battery voltage higher values, the voltage drop across the resistor 23 increases, whereby the transistor 24 increases Dimensions is controlled. The individual elements are designed so that the collector-emitter voltage of the transistor 25 is equal to the incremental voltage of the battery 11, so that the supply voltage of the Flyback converter remains almost constant. This has the consequence that the output voltage of the flyback converter remains constant.

If the voltage of the battery 11 now exceeds the constant converter output voltage, which is equal to the is lower supply voltage, the transistor 24 is completely turned on and consequently the Transistor 25 completely blocked. The forward converter is thus de-energized. The diode 26 is now in the forward direction operated so that the battery U is directly connected to the exposure control circuit 3. Thus isl The DC / DC converter is only switched on when the battery voltage is switched to one below the supply voltage wcrtcs of the treatment control balance. current value decreases.

1 sheet of drawings

Claims (6)

Patent claims: 1. Photographic or cinematographic camera with a supply voltage source and with a s between an upper and a lower supply voltage operating exposure control device, characterized in that the supply voltage source is a battery (11) and a per se known DC voltage converter (2), in the supply circuit of a Control stage (25 ') is provided, which is connected to one of the battery voltage or the converter output voltage dependent control voltage generating actual value stage (21 to 24) is connected to the a threshold stage (21) which is switched through when the battery voltage the The lower supply voltage on the converter output side reaches that when the threshold value stage is switched through (21) the DC / DC converter is blocked that the battery-side converter input via a current path containing a blocking agent (26) is connected to the converter output, that the Locking means (26) is activated when the battery voltage is greater than the converter output side lower supply voltage value and that the converter output voltage in the switch-on phase of the DC / DC converter is less than the upper supply voltage. 2. Photographic or cinematographic camera according to claim 1, characterized in that the Transformer output-side supply voltage during the switch-on phase of the DC-DC converter above a lower battery limit value with the aid of the control stage (25) and the with the Actual value stage (21 to 24) connected to the converter output is kept constant. 3. Photographic or cinematographic camera according to claim 2, characterized in that the Actual value stage (21 to 24) a transistor (24) connected to the converter output and a one Zener diode (21) containing base voltage divider comprises, wherein the Zener diode (22) in the base coil-side Divider branch is arranged and that the control stage has a transistor (25) whose Base is connected to the collector of the actual value transistor (24). 4. Photographic or cinematographic camera according to one of the preceding claims, characterized characterized in that the blocking means is a diode (26). 5. Photographic or cinematographic camera according to one of the preceding claims, characterized characterized in that the DC / DC converter designed as a chopper with the Control transistor (25) is connected in series. 6. Photographic or cinematographic camera according to one of the preceding claims, characterized characterized in that the battery (11) can be actuated by means of a trigger relay (6) Switch (7) can be connected to the DC voltage converter (2), which switch (7) is simultaneously in the Circuit of a film drive motor (8) is located.