DE4007468A1 - Control circuit for pulsed magnets - avoids high peak current loading of battery - Google Patents

Abstract

A control circuit is used with the pulsed magnet (1) of a photographic camera and has a pair of transistors (2,9), diodes (5,8), capacitor (3), battery (6) and switch (7). The capacitor is charged when the switch is closed. The charge current rate is controlled by the externally controlled transistor (9) and achieves a maximum after a specified period. Discharge occurs when the second transistor (2) is switched to the conducting state. USE/ADVANTAGE - For photographic camera. Controls loading of pulsed magnet circuit.

Description

The invention relates to a circuit arrangement for control of pulse magnets for battery powered photo graphic cameras.

To control mechanical camera functions known to use pulse magnets, the permanent magnet field at a given time by a counter magnetic field is compensated so that the magnet armature fall off and release a camera element, for example, to expire can. To keep the pulse current load of the battery low to hold, the counter magnetic field is generated by means of of a current resulting from the discharge of a condenser sator over a winding of the pulse magnet (z. B. DE-OS 14 72 679, DE-OS 33 45 026). These well-known Circuits require charging the capacitor a too high peak current or circuitry to limit the current, which takes too long charging times condition.

The object of the invention is a circuit arrangement for Control of pulse magnets with a condenser gate discharge via a magnet development sometimes com to create a pensable permanent magnetic field, which in Effort is low and can be integrated at a reasonable price Load one in the electronics system of the camera as loading drive voltage source used the Aufla the condensate connected to the pulse magnet effect in a short time and the functional reliability of the magnet increased.

According to the invention, this object is achieved in that the winding of the pulse magnet at the same time in a tran  sistor-controlled charging circuit of the capacitor and as a limiter for strengthening the permanent magnetic field kenden charging current is formed.

The invention is illustrated below with the aid of the following illustration explained. It shows

Fig. 1 circuit arrangement according to prior art,

Figure 2 circuitry. According to the invention

Fig. 3 capacitor charging current diagram.

To the known circuit arrangement for the control of a permanent pulse magnet 1 include a switching transistor 2 , a series connection of two parallel-connected capacitor 3 , a resistor 4 and a diode 5 to protect the switching transistor 2 against induction peaks caused by the pulse. A battery 6 as the operating voltage source and a switch 7 complete the circuit.

All of these switching elements, with the exception of the charging resistor 4 , are also used in the circuit arrangement according to the invention according to FIG. 2 again and therefore bear the same reference numerals. A diode 8 and a switching transistor 9 have been added .

The modes of action are as follows:

In the circuit of Fig. 1 of the switch 3 is charged with non-conductive switching transistor 2, the capacitor 3 via the charging resistor 4 after closing. The charging current follows the course shown in dashed lines in FIG. 3. At the moment (t = 0) when the battery is switched on, it is loaded with an impermissibly high peak current, which, however, then, as is known, decays after an e function. After charging the capacitor, the switching transistor 2 can be turned on at a given time from the further electrical system of the camera, not shown, so that the capacitor 3 can be discharged via the winding of the pulse magnet and the switching transistor 2 . When the capacitor 3 is subsequently recharged, the high current load of the battery 6 already described is repeated.

The circuit arrangement according to the invention avoids this obvious disadvantage. After switching on the battery 6 , the switching transistor 9 is turned on in the non-conductive switching transistor 2 from the white direct camera electronics, so that the capacitor 3 can be charged via the winding of the pulse magnet 1 which is also effective as a current limiter. The flowing through said winding charging current is directed so that it strengthens the magnetic field of the permanent pulse magnet in the Im and thus to increase its holding force and the functional reliability of the magnetically controlled ge functional sequence of the camera leads. According to the current curve drawn in FIG. 3, the peak current load of the battery 6 is completely eliminated at the moment of switching on. Starting from zero, the charging current increases until time t 1 , but the maximum value thus achieved is however below the previously described peak value. The current load on the battery can be reduced even further if the switching transistor 9 is pulse-controlled in the initial phase of capacitor charging.

With the capacitor 3 charged in this way in a short time, the camera is now ready for operation. At the intended time, e.g. B. when triggering the camera, the switching transistor 2 is turned on so that the capacitor 3 can discharge. The current flowing through the winding of the pulse magnet causes the build-up of a magnetic field which is opposite to that of the permanent magnet. As a result, the spring-loaded armature of the pulse magnet can fall off and trigger the camera.

Claims (2)

1. Circuit arrangement for the control of Impulsmagne th for photographic cameras with a battery as an operating voltage source for an electronic system of the camera and a capacitor, which is connected in parallel with the series circuit of a winding of the pulse magnet with a switching transistor and can be discharged via this series circuit for temporary compensation of a permanent magnetic field of the pulse magnet , characterized in that the winding of the pulse magnet ( 1 ) is located in a transistor controlled charging circuit of the capacitor ( 3 ) and is designed as a limiter for the charging current strengthening the permanent magnetic field. 2. Circuit arrangement according to claim 1, characterized in that the arranged in the charging circuit between bat terie ( 6 ) and capacitor Schalttransi stor ( 9 ) from the electronic system of the camera is preferably intermittently controlled.