DE841546C - Electric discharge tubes - Google Patents

Description

Electric discharge tube The invention relates to an electric discharge tube Discharge tube for generating flashes of light of short duration and sufficient Brightness for photographic purposes.

There are already known electrical discharge tubes, so-called electrical ones Flashlight lamps with an associated electrical circuit in which a Capacitor a high potential up to a sufficient value arises to the Let the discharge tube work. After a single action of such a tube it is necessary to wait until the capacitor has been recharged before the tube can work again. This disadvantage makes such an arrangement completely unsuitable if several pictures are taken in quick succession have to.

It is known to use a number of discharge tubes of this type, each tube of which delivers a single flash of light and the one of which turns into an electrical one Circle are included so that each tube is ignited separately, with appropriateä'ttel are provided to cause a delay after each rounding so that the tubes together deliver successive flashes of light.

However, this arrangement has the disadvantage that several tubes are required delay circuits must be used and if there are a large number of tubes the whole cannot easily be accommodated in a single reflector.

The invention provides an electric discharge tube and one with a device provided with such a tube for generating a series of flashes of light for photographic purposes, where the flashes of light follow one another quickly.

According to the invention has an electric discharge tube for generation a number of flashes of light in quick succession a cathode, an anode and a number of intermediate electrodes interposed along the discharge path of the tube the cathode and the anode are arranged, the electrodes like that are connected to an external electrical circuit that causes a discharge is, in which first the anode or the cathode and the next to it Intermediate electrode and then the other electrodes are used one after the other.

According to one embodiment of the invention, the electrodes are of this type connected to an external electrical circuit that initially a discharge between the anode or the cathode and the adjacent intermediate electrode, then between the anode or cathode and the subsequent intermediate electrode and so on one after the other is brought about along the tube.

According to another embodiment of the invention, the electrodes are so connected to an external electrical circuit that initially a discharge between the anode or the cathode and the first intermediate electrode located next to it, then between the first intermediate electrode and the second intermediate electrode and so on one after the other along the tube.

For this purpose, the anode is in the first-mentioned embodiment connected to the positive terminal of a high voltage source and connected to the cathode the negative terminal of this source is applied to either the anode or the cathode a resistor is connected upstream, and each of the intermediate electrodes is via a Resistor connected to a terminal of the high voltage source, with one capacitor each between the anode and the cathode as well as between the directly with a clamp the high voltage source connected electrode and each of the intermediate electrodes switched is, and finally means are provided to the gas in the discharge tube between the electrode directly connected to one terminal of the high-voltage source and ionize the adjacent intermediate electrode.

In the latter embodiment of the invention is one of the External electrodes with one terminal of a high voltage source and the other external electrode connected via a resistor to the other terminal of the source and each one Capacitor between one outer electrode and the adjacent intermediate electrode, between two successive intermediate electrodes and between the last one Intermediate electrode and the other outer electrode connected, also means are provided to the gas in the discharge tube between the one outer electrode and ionize the adjacent intermediate electrode.

The invention is based on the drawing, in which some embodiments the same are shown, for example explained in more detail.

Fig. I is a longitudinal section of an embodiment of the discharge tube; Figure 2 is a cross-section of the tube of Figure i; Fig.3 is a section of one the intermediate electrodes; Fig. 4 is a top plan view of the intermediate electrode shown in Fig. 3; .

FIG. 5 schematically shows the circuit of a discharge tube of the in Fig. I illustrated training, with the first a discharge between the cathode and the intermediate electrode lying next to the cathode, then between the first Intermediate electrode and the second intermediate electrode and finally between the second intermediate electrode and the anode is brought about; Fig. 6 shows schematically Another circuit of a discharge tube according to FIG. i, with which a discharge is first carried out between the cathode and the adjacent intermediate electrode, then between the cathode and the second intermediate electrode and finally between the cathode and the anode is produced; Fig. 7 shows schematically a further embodiment of the discharge tube, in which the casing of the tube consists of a hollow ring and the electrodes are circular are arranged in the tube.

In Fig. I, a tubular sheath i contains a cathode 2, which in the shell is melted at one end thereof, as well as an anode 3, which is on opposite end is fused into the shell, with two intermediate electrodes 4 and 5 arranged between the cathode 2 and the anode 3 in the longitudinal direction of the tube are.

The intermediate electrodes are of the same type and one of the same is shown in Figs. 3 and 4 on an enlarged scale. Each intermediate electrode is T-shaped and provided with a lead wire 6 made of tungsten the inner end of which a transverse wire 7 is welded, which extends parallel to the tube axis extends. The transverse wire 7 extends in the direction of the cathode over a larger one Length than in the direction of the anode. Over the end of the wire 7 opposite the anode a hollow nickel tube 8 is pushed and attached to it. A barium trap pill 9 is mounted in the tube 8, and the latter is sufficiently pinched at its end, to hold the pill 9 in the tube during manufacture.

After the production of the tube, the catch substance pill 9 is in the usual Way atomized.

A certain amount of a mixture can also enter the cavity of the tube 8 of barium and strontium carbonates or a certain amount of one of the usual cathode pastes introduced for use in the manufacture of indirectly heated electrodes come. After the tube is made, the mixture is heated to produce the carbonates to be converted into the corresponding oxides.

In both cases, the part of the intermediate electrode opposite the Anode in the finished tube will serve as an intermediate cathode in this way, be it with the anode of the tube, be it with the adjacent intermediate electrode, while the other part of the intermediate electrode opposite the cathode acts as an anode, be it with the cathode of the tube, be it with the cathode part of the adjacent intermediate electrode.

It is evident that a greater number of intermediate electrodes than that two in Fig. i labeled 4 and 5 can be used and even for the most practical applications of the tube will be required.

In FIG. 5, the cathode 2 of a discharge tube according to the one shown in FIG. i embodiment shown with the negative terminal io of a high voltage source tied together, while the anode 3 via a resistor 12 to the positive terminal ii of the high voltage source connected is. A capacitor 13 is between the cathode 2 and the first intermediate electrode 4, a capacitor 14 between the intermediate electrode 4 and the intermediate electrode 5 and a capacitor 15 are connected between the electrode 5 and the anode 3. One Ignition coil 16 is on the outside around tube i between electrodes 2 and 4 wound and with a known per se and not shown in the drawing Ignition circuit connected.

The capacitors 13, 14 and 15 can have the same capacitance and are applied across resistor 12 to between terminals io and i1 charged high potential. There are thus a number of stress gradients along it separate parts of the tube i.

During operation, there is first a discharge between the cathode 2 and the first intermediate electrode 4 is generated by means of the ignition coil 16.

This first discharge extends beyond the electrode 4, so that the gas in the tube part between the electrodes 4 and 5 is ionized and thereafter a discharge takes place in this part of the tube. This discharge conducts similarly a discharge in the tube part between the electrode 5 and the Anode 3 a.

If the capacitors 13, 14 and 15 have the same capacitance, the emitted light is made up of three light flashes of the same brightness with the same There are intervals in between. The interval between the flashes of light is determined by Potential across the capacitors is determined by the effect of each discharge on the adjacent part of the tube depends on the speed with which ionized atoms move around during discharge. If the potential is between the terminals io and ii becomes too high, the flashes of light will overlap each other.

In a practical embodiment of the circuit according to FIG. 5, the data are as follows: interval Total flash duration between Relative I <a- , tension from the light apex pacific on (lcr l / ', up to 1% flashing (v;) n intensity ity cut vertex value vertex to vertex) the light- kt 'I p sec. y sec. flashes I y F 3.0 62 65 50 / 5.0 / 5.0 2, <I 62 70 5.0 / 5.0 / 5.0 33 2.8 62 83 4.5 / 5.0 / 5.0 33 2.7 62 ioo 4.5 / 5.0 / 5.0 33 2.6 62 113 4.5 / 5.0 / 5.0 33 2.4 62 i8o 4.0 / 4.3 / 4.5 33 2.3 62 200 3.5 / 4.0 / 4.0 33 2.2 62 220 3.5 / 35 / 3.5 33 The duration of each light flash and the intervals between the light flashes can be changed within wide limits by the dimensioning of the tube, by the choice of the gas filling of the tube and its pressure, by the capacitance of the capacitors used and by the potential applied between the terminals io and i1 will. In a similar circuit, the effect of which is very similar to that of the circuit according to FIG. 5, the cathode 2 is connected via the resistor 12 to the negative terminal io of the high-voltage source, and the anode 3 is connected directly to the positive terminal ii. In this circuit, the ignition coil is arranged between the anode 3 and the intermediate electrode 5 located next. The first discharge takes place between the anode 3 and the electrode 5, the second between the electrodes 5 and 4 and the last between the electrode 4 and the cathode 2.

The discharge tube can also be made using the circuit according to Fig. 6 operated in which the cathode 2 of the tube i with the negative terminal io the high voltage source and the intermediate electrodes 4. 5 and the anode 3 over Resistors 17, 18 and i9 are connected to the positive terminal ii of the high voltage source are. Capacitors 20, 21 and 22 are between the cathode 2 and the electrodes 4, 5 or 3 switched. The ignition coil 16 is according to the circuit of Fig. 5 arranged between the electrodes 2 and 4.

In this circuit the capacitors 2o, 21 and 22 are connected to the Resistors 17, 18 or ig. charged to the full voltage of the high voltage source, so that the electrodes 4, 5 and 3 are kept at the same potential and a voltage gradient initially only in the tube part between electrodes 2 and 4 consists.

The first discharge between electrodes 2 and 4 is from a Voltage wave initiated in the ignition coil. As a result of this first discharge will the capacitor 2o is discharged, so that the potential of the electrode 4 drops rapidly. The voltage gradient is created by the capacitor 21 between the electrodes 2 and 5, and this change, along with that along the discharge path of the tube between the electrodes 2 and 5 existing ionization, leads to a discharge between these two electrodes. Another is done in a similar manner Discharge between the cathode 2 and the anode 3 of the tube as a result of the over the Capacitor 22 occurring voltage.

In a practical circuit of this type, a flash duration from 2o, uSec. obtained at intervals of 25 y sec. when using capacitors each with a capacity of 33 uF, which are charged up to a potential of 1.5 kV became.

A similar circuit for operating the tube is that the Anode 3 is connected directly to the positive terminal ii of the high voltage source and the electrodes 2, 4 and g via resistors to the negative terminal io of Source. The capacitors are then placed between the anode and each of the other electrodes connected and the ignition coil between the anode 3 and the Electrode 5 arranged. The first discharge then takes place between the anode 3 and of the electrode 5, and the further discharges take place between the anode 3 and the Electrode 4 and the anode 3 and the cathode 2 instead: In Figs. 5 and 6 is the Ignition coil 16 on the Outside around the tube between the cathode 2 and the adjacent intermediate electrode 4 wound. This training is preferred but other forms of training can also be used. Any suitable one can be Use an ignition device, and this can be on either end of the tube between the cathode 2 and the intermediate electrode 4, as shown, or be it be arranged between the anode 3 and the intermediate electrode 5. The first training but is preferable because the electrons over the part during the first discharge will fly out where the discharge takes place, leaving the gas in the ionize neighboring section, which works better than the positive ions at of the latter training.

7 shows a further design of the discharge tube 23, which has a hollow ring-shaped gas-filled envelope, a cathode 24, electrodes 25, 26, 27, 28 and 29, which are arranged in a circle at a distance from one another in the tube, and with a second cathode 30 is provided. An ignition coil 31 is arranged between the cathode 24 and the electrode 25, and the first discharge takes place between these electrodes. The second cathode 30 is used to prevent the ionization in the tube part between the electrodes 24 and 25 from ionizing the gas in the part between the electrodes 24 and 29 and that discharges arise in a direction opposite to the clockwise direction. The second discharge uses electrode 26, etc. in the tube, using electrodes 27, 28 and 29 in sequence. The discharge tube can also be designed differently, for. Like a linear tube bent in the shape of a flat grid or around a cylindrical surface.

Claims (7)

PATENT CLAIMS: i. An electric discharge tube for generating a number of flashes of light in rapid succession with a cathode and an anode, characterized by a number of intermediate electrodes which are arranged along the discharge path of the tube between the cathode and the anode, the electrodes being connected to an external electrical circuit in such a way that one Discharge is generated, in which first the anode or the cathode and the adjacent intermediate electrode and then the other electrodes are used one after the other. 2. Electric Discharge tube according to claim i, characterized in that the electrodes are of such are connected to an external electrical circuit that initially a discharge between the anode or the cathode and the intermediate electrode lying next to it and then between the anode or cathode and the following intermediate electrode, etc. of Is generated in sequence. 3. Electric discharge tube according to claim i, characterized characterized in that initially a discharge between the anode or the cathode and the intermediate electrode lying next to it, then between the first intermediate electrode and the second intermediate electrode, etc. are generated in order. 4. Device with a discharge tube according to claim 2, characterized in that the anode is connected to the positive terminal of a high voltage source and the cathode and each intermediate electrode to the negative terminal of the source via resistors are connected, each with a capacitor between the anode and the cathode and connected between the anode and each intermediate electrode, and means for Ionizing the gas in the discharge tube between the cathode or the anode and the intermediate electrode lying next to it are arranged. 5. Device with a discharge tube according to Claim 2, characterized in that the cathode to the negative terminal of a high voltage source and the anode and each of the intermediate electrodes are connected via resistors to the positive terminal of the source and that respectively a capacitor between the cathode and the anode and between the cathode and each of the intermediate electrodes is connected and means for ionizing the gas in the discharge tube between the cathode or the anode and its first lying intermediate electrode are arranged. 6. Device with a discharge tube according to claim 3, characterized in that the cathode is connected to the negative terminal a high voltage source and the anode via a resistor with the positive Terminal of the source is connected, with a capacitor between each cathode and the first intermediate electrode lying next to the cathode, between two successive ones Intermediate electrodes and connected between the last intermediate electrode and the anode and means for ionizing the gas in the discharge tube between the cathode or the anode and the adjacent intermediate electrode are provided. 7. Device with a discharge tube according to claim 3, characterized in that the anode to the positive terminal of a high voltage source and the cathode via a resistor connected to the negative terminal of this source, each with a capacitor between the anode and the first intermediate electrode next to the anode, between each pair of the successive intermediate electrodes and between the last intermediate electrode and the cathode is connected, and means for ionizing of the gas in the discharge tube between the cathode or the anode and that of the latter initially lying intermediate electrode are provided.