DE1060045B - Tube flash unit with stroboscopic setting lighting - Google Patents

Description

The invention relates to a tube flash device for photographic purposes with stroboscopic adjustment lighting.

Particularly when taking pictures in the studio with several devices, it is desirable to use the one to be expected with each device Estimate the light distribution before taking the picture and, if necessary, adjust the devices afterwards and to be able to arrange. For this purpose it is known, in addition to the flash tube in the lamp to provide a continuously burning incandescent lamp as a setting lamp. Such an arrangement with additional However, modeling lamps have the disadvantage that, as a rule, the light distribution of the modeling lighting does not exactly match the light distribution of the flash.

It is also known an arrangement in which in the same tube in which the strong Lightning discharge is generated for the recording, optionally also periodic weaker auxiliary discharges for a stroboscopic modeling lighting can be generated. With this arrangement it is connected to the primary winding of the ignition transformer, a breakover circuit with a glow lamp can be switched on, in which a Capacitor periodically discharges via the glow lamp and the ignition transformer and thereby the tube ignites.

It is also known in such a tube flash device with stroboscopic setting lighting the tube for generating the auxiliary discharges with a correspondingly stepped-up AC mains voltage to operate or to apply the mains AC voltage to the ignition transformer.

In the first-mentioned arrangement, the sweep frequency changes with the applied operating voltage. As a result, mains voltage fluctuations or local mains voltage differences are not only expressed in a change in the intensity of the auxiliary discharges, but also in a change in their frequency, so that the ratio of the intensities of modeling lighting and flash is not constant. One must therefore seek to operate the modeling lighting with a frequency and energy that is as precisely defined as possible. The latter arrangements, which use the alternating current to operate the modeling lighting trying to take advantage of them are, however, not useful in practice.

In the case of the strobe device according to the invention, the auxiliary discharges are ignited for this purpose the ignition capacitor is discharged via a grid-controlled gas discharge tube, on whose grid a pulsating negative DC voltage is present. This can preferably be a rectified AC mains voltage be.

At a mains frequency of 50 Hz and a two-tube flash unit with stroboscopic
Setting lighting

Applicant:

Society for Multiblitz Devices
Dr.-Ing. DA Mannesmann mbH,
Westhoven via Porz, Oberstr. 65

Wolfgang Ludloff, Wahn-Heide,
has been named as the inventor

The modeling lighting then works at 100 Hz to rectify the path. This frequency is particularly favorable in that it is on the one hand with the now the usual tube operating voltage of around 500 V and the resulting flash duration Eye just appear as continuous lighting. On the other hand, an overload of the Avoid tubes due to too fast a flash sequence.

For normal flash operation, it is advisable to use a pulsating DC voltage that can be switched on Smoothing capacitor smoothable, so that they then the grid-controlled gas discharge tube continuously blocks and the auxiliary discharges are prevented.

In a further embodiment of the flash device according to the invention, the grid-controlled gas discharge tube can advantageously be used used in a manner known per se at the same time to ignite the main flash and thereby the camera contact can be relieved of the ignition voltage surge. This is done expediently in that through a contact to the smoothing capacitor. second capacitor in parallel can be switched and that the smoothing capacitor is charged slowly via a resistor is that by the parallel connection for a short time a sufficient to ignite the Tyratron The negative grid bias is lowered. The parallel connection of the second capacitor can then take place by means of the camera contact, with only the relatively small ones via the camera contact Currents flow that occur when the capacitors are recharged.

The dimensioning of the switching elements is advantageously made so that after each discharge the recharging of the ignition capacitor is so slow -

909 558/207

Claims (1)

it follows that the next half-wave of the grid voltage blocks the grid-controlled gas discharge tube again before the anode voltage required for re-ignition is reached. An embodiment of the tube flash device according to the invention is shown schematically in the drawing and described below: A transformer 1 has two secondary windings 2, 3, one of which, 2, supplies the operating voltage for the flash tube 4, the other, 3, a voltage for controlling the ignition circuit. The voltage of the winding 2 is fed to a tube rectifier arrangement 5, which charges a capacitor 6 of, for example, 16 μΕ, the function of which is described below. The storage capacitor 9 for the main lightning discharge is charged via a stabilizer 7 and a charging resistor 8 (250 ohms) and is designed as an electrolytic capacitor with a capacity of approximately 200O μΕ. The capacitor 9 is connected to the tube 4 via a switch 10. In front of the stabilizer 7, a further smaller capacitor 12 (about 10 μΩ) is connected to the operating voltage via a charging resistor 11 (250 ohms) and is applied to the second contact of the switch 10. The ignition capacitor 16 is charged via a voltage divider 13, to which a capacitor 14 of approximately 4 μΕ is applied, and a charging resistor 15. The ignition capacitor is in series with the primary winding of the ignition coil 17, the secondary winding of which is connected to an ignition electrode 18 in the usual manner. A grid-controlled gas discharge tube 19 is located parallel to the ignition capacitor (2 μΕ) and the ignition coil 17. A negative pulsating DC voltage is applied to the grid of the grid-controlled gas discharge tube 19 during setting mode. This is generated by a two-way rectifier from the 50 Hz AC voltage tapped at the winding 3 of the transformer 1 and fed via a voltage divider 21. A smoothing capacitor 23 can be switched between the grid and cathode of the grid-controlled gas discharge tube 19 by means of a switch 22. The switch 22 is coupled to the changeover switch 10. Appropriately, the switch 22 and the changeover switch 10 form different contacts of a relay. A second capacitor 24, which is bridged by a high-value resistor 25, can be switched in parallel with the capacitor 23. The parallel connection of the capacitor 24 takes place by means of the contact 26, which is preferably formed by the camera contact. The mode of operation of the described arrangement is as follows: Setting lighting For the setting lighting, the changeover switch 10 is on the lower contact, the switch 22 is open. The flash tube is then connected to the capacitor 12. A negative direct voltage pulsing at 100 Hz is applied to the grid of the grid-controlled gas discharge tube 19. As soon as this negative bias voltage falls below a certain value, the grid-controlled gas discharge tube 19 ignites, thereby discharging the ignition capacitor and a current surge flows through the primary winding of the ignition coil 17, which has induced a high voltage pulse on the ignition electrode 18, causing tube 4 to ignite. A relatively weak discharge then takes place in this, through which the capacitor 12 discharges. The discharge of the ignition capacitor 16 initially causes the anode voltage of the grid-controlled gas discharge tube 19 to collapse, so that the grid-controlled gas discharge tube is extinguished. While the anode voltage is slowly being built up again via the resistor 15, the negative grid bias voltage has again reached such a value that it blocks the grid-controlled gas discharge tube. Only towards the end of the next half-wave is the grid-controlled gas discharge tube ignited again, and the process described is repeated. In this way, stroboscopic discharges arise which have a precisely defined frequency and - through the capacitor 12 - defined energy, so that perfect measurements of the illumination of the image are possible even before the recording. Flash mode After the setting has been made, switches 10 and 22 are set to the position shown. The tube 4 now rests on the storage capacitor 9 in the usual manner. The smoothing capacitor 23 converts the pulsating negative DC voltage into a constant negative grid bias voltage, which is sufficient to continuously block the grid-controlled gas discharge tube. As soon as the camera contact 26 is closed, the capacitor 23 is partially recharged into the capacitor 24, whereby, since the recharge takes place via the resistor 21 with a large time constant, the negative grid bias of the grid-controlled gas discharge tube 19 is briefly reduced and it ignites. As a result, the flash is triggered once in the manner described above, and the large storage capacitor 9 is now discharged. After the discharge, the grid-controlled gas discharge tube 19 extinguishes, as described, and while the ignition capacitor 16 is charging again, the capacitor 23 is already over Resistor 21 is charged to its full voltage and again blocks the grid-controlled gas discharge tube 19. The high-resistance resistor 25 is intended to cause the capacitor 24 to discharge again after the contact 26 has opened and is ready for a new trigger. The capacitor 6 has the function of compensating for the strong fluctuations in load, such as those caused by the setting lighting, and thereby relieving the load on the rectifier 5. This only requires a capacitor of around 16 μΕ. The voltage for the setting lighting can then be tapped in front of the tube stabilizer 7 serving to stabilize the lightning voltage - instead of after the storage capacitor 9 as in the known arrangement - and the latter only needs to be designed for flash operation. Patent claims: 1. Strobe for photographic purposes, in which in a flash tube optionally one strong main discharge for recording or periodic weaker auxiliary discharges for one Stroboscopic setting lighting are generated, characterized in that the ignition