DE1904901A1 - Circuit arrangement for a photo flash unit - Google Patents

Description

Circuit arrangement for a photo flash unit Photo flash units included generally a flashlamp, usually a gas discharge tube, which after their Ignition sends out a photo flash, the strength and strength of which for the photo flash unit are typical and are marked with a so-called guide number. With help This guide number can be used to set the aperture and distance settings according to a formula be made. Recordings from different distances are required every time a calculation and readjustment of the distance and the aperture.

This inconvenient handling is caused by photo flash units with automatic exposure, as they have been developed recently, avoided. Such an automatic exposure lets the flash unit adjust the light dosage itself, so that on the camera once the aperture has been set, only the distance setting has to be varied got to. The light is dosed by precisely setting the flash duration. Allows this is done by an extinguishing device, which after sufficient illumination of the object the flash lamp goes out.

The invention relates to a circuit arrangement for a Fotoblitzgerht, that is, a power source, a flash lamp, an ignition device and an extinguishing device for the flash lamp contains.

Such a circuit arrangement is known and for example in "Electronics 1968, No. 5, page 139 described.

In this circuit arrangement, the extinguishing device consists of a Extinguishing tube and from an extinguishing circuit, with the help of a photo resistor controls the extinguisher. The cathode-anode section of the extinguishing tube is parallel to the Eatode-Anode-section of the flash lamp. The flash lamp is fed by one Charging capacitor, ignited via an ignition transformer and via a synchronous contact. If the object is sufficiently illuminated after igniting the flash lamp, leave it the extinguishing circuit ignites the extinguishing tube, which then only has a fraction of the internal resistance the flashlight and consequently the energy still in the charging capacitor destroyed. The photo flash from the lightning bolt is ended abruptly.

This method of influencing the duration of the photo flash has two functions Disadvantage. On the one hand, up to 99 ffi the charging capacitor energy is destroyed. On the other hand, the charging capacitor learns A very heavy load due to the high charging current surges.

Avoiding these disadvantages is the task of the present Invention is based.

To solve this problem, in a circuit arrangement for a Photo flash unit that includes a power source, a flash lamp, an igniter and contains an extinguishing device for the flash lamp, proposed according to the invention, that in series with the cathode-anode section of the flashlamp a disconnectable thyristor via which the flash can be extinguished in a defined manner after ignition.

Illit can use such a circuit arrangement according to the invention the heavy use of the charging capacitor or another used Avoid the power source and the destruction of energy that is not currently required.

On the basis of an exemplary embodiment shown in the drawing Circuit arrangement according to the invention, wherein as a turn-off thyristor advantageous a thyristor tetrode is used, the invention will be explained in more detail.

Senses serving as a flashlight gas discharge tube 1 lies with her Eatode-anode section in series with the cathode-anode section of a thyristor tetrode 2 and to a charging capacitor 3. The charging capacitor 3 is connected to that of the cathode the thyristor tetrode 2 facing side on the reference potential. With sciner andoren It is on the side of the anode of the gas discharge tube 1 and via an ohmic resistor 4 to a DC power source, i.e.

at the Pcl, which carries voltage against the reference potential.

The anode of the hyristortc-trode 2 is connected to the cathode of the gas discharge tube 1 connected. Between the anode of the gas discharge tube 1 and the reference potential is the series connection of an ohmic resistor 5, an ear resistor 6 and a potentiometer 7. The pre-binding point of the two ohmic resistors 5 and 6 are connected to the reference potential and to the cathode via a capacitor 8 of the gas discharge tube 1 via the primary side of an ignition transformer 9. The secondary side of the ignition transistor 9 lies between the cathode and the ignition electrode of the gas discharge tube 1. The connection point of the ohmic resistor 6 and the Potentiometer 7 is via a capacitor 10 with the reference potential and above an ohmic resistor 11 connected to one side of a synchronous contact 12, the other side of which is on the ignition electrode of the thyristor tetrode 2.

An erase circuit, symbolically denoted by 13, is connected to the erase electrode the thyristor tetrode 2 connected.

The capacitors 3, 8 are in the idle state of the circuit arrangement and 10 each charged to a voltage that is supplied by the Gloichspsnnungsquelle, is determined by the ohmic resistors 4, 5, 6 and the potentiometer 7. When the synchronous contact 12 closes, the one described below takes place Process. The capacitor 10, the voltage of which is set by the potentiometer 7 can be discharged through the ohmic resistor 11 and through the ignition gap the thyristor tetrode 2. This ignites the Uhyristor tetrode 2, i.e. the cathode-anode line Xce through-t. The capacitor 8 can now be on the primary side of the ignition transformer 9 and discharged through the hyristortetrode 2 and generated in the secondary side of the ignition transformer 9 shows a voltage surge which ignites the gas discharge tube 1. This starts the charging capacitor 3 to discharge via the gas discharge tube 1 and the thyristor tetrode 2. The gas discharge tube 1 emits a photo flash that lasts until the erasing circuit 13 caused by the detected via a photo resistor sufficiently strong illumination of the object, a pulse to the erasing electrode of the Dhyristortetrode 2 is there, which clears the Thyristortetrode 2 and the discharge process of the charging capacitor 3 interrupts. The ohmic resistor 5 has the task of already ignited thyristor tetrode 2 discharges the charging capacitor 3 via the To prevent primary side of the ignition transformer 9.

Those still in the charging capacitor after the forced termination of the photo flash 3 existing energy is not destroyed as in the known version, but remains in the charging capacitor 3. This not only brings the advantage of the lower Energy consumption, but also the advantage that the charging capacitor 3 again can be flashed up faster and thus the photo flash unit a much lower one Has flash recycle time than is the case when the charging capacitor 3 is used for each photo flash except for the low erasing voltage of an erasing tube connected in parallel is almost completely discharged.

2 claims 1 figure

Claims (2)

Claims 1. Circuit arrangement for a photo flash unit that a power source, a flash lamp, an ignition device and an extinguishing device for the flashlamp contains that in series A thyristor which can be switched off is connected to the cathode-anode section of the flash lamp (1) which can be used to extinguish the flash in a defined manner after ignition. 2. Circuit arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the disconnectable thyristor consists of a thyristor tetrode (2) with a cathode electrode, an anode electrode, an ignition electrode and an extinguishing electrode consists.