DES0041837MA - - Google Patents

Description

S 41837 VIIIc / 21 f

In the known ignition devices for high-pressure gas discharge lamps, for example xenon lamps, ... becomes the, great internal resistance of one Capacitor, a spark gap and an ignition 5; coil existing Tesla circle through the very load small resistance of the lamp. The ignition device therefore works with underfitting. To at To achieve a suitable ignition voltage for the lamp, the ignition device must be proportionate high energies are supplied. With these ignition devices, therefore, the use of an extinguishing spark generator necessary.

The invention has the task of adapting ignition devices for high-pressure gas discharge lamps to improve and both the. Efficiency as well as the structure of the ignition device simplify. According to the invention, a capacitance is connected in the high-frequency ignition circuit arranged with an auxiliary discharge path in such a way that the load resistance of the Tesla transformer is increased.

The invention will be explained with ^{reference to the embodiment 1} shown in FIGS. 1 and 2 of the drawings.

The surge capacitor ι is with high voltage 2. fed. It discharges in an oscillating manner via the spark gap 3 and the primary winding 4 of the Tesla transformer 5. To the secondary winding 6 of the transformer is the. High-frequency circuit 7 connected to the lamp 8. The high ' frequency circuit is both by a switching capacitance 9 and by one in series with a bypass capacitor 10 lying auxiliary discharge path 11 bridged. The switching capacity 9 must, as shown in Fig. 2, to be understood as a chain ladder, which consists of series L-links 12 and Par- • allele C-members 13.

When the ignition device is switched on, they charge in the secondary winding 6 of the transformer 5 high-frequency pulse groups generated the switching capacity 9 over the lamp 8. The Tesla transformer is thus initially with the lamp and the switching capacity connected in series. This will reduce the load resistance of the Tesla transformer increased and a favorable voltage adjustment achieved. As soon as the voltage at the switching capacitance, the ignition voltage of the auxiliary discharge path 11, it responds and the high-frequency current flows through the bypass capacitor 10. The auxiliary discharge path 11 is set so that the on the lead High-frequency pulse voltage peaks that occur do not exceed 250 V, for example and therefore cannot lead to flashovers or flashovers.

To determine the spark sequence, the Impact capacitor 1 can be fed via a direct or transformed resistor.

The invention offers the following advantages: The energy requirement of the ignition device is compared to the known ignition devices greatly reduced by about 80%. The lamp will also be special without Ignition aid ignited properly. The ignition starts so briefly and constantly that the lamp can be used for Morse code purposes, for example for about 500 keystrokes per minute. Another advantage is the possibility of reducing the feed voltage of the surge capacitor and to use a simple peak radio link instead of the quenching spark gap.

Claims (4)

Patent claims: 1. Ignitor for high pressure gas discharge lamps, for example xenon lamps, characterized in that the high-frequency ignition circuit a capacity in conjunction with a. Auxiliary discharge path is arranged such that the load resistance of the Tesla transformer is increased. . . 8t 2. Ignition device according to claim 1, characterized in that that a spark gap is used to excite the Tesla circle. 3. Ignition device according to claim 1 and 2, characterized in that for determining the A direct or transformed spark sequence feeding the surge capacitor of the Tesla circle Resistance serves. 4. Ignition device according to claim 1 to 3, characterized by the use for a lamp for sending Morse code signals at high speed. For this purpose ι sheet of drawings