DE2307058A1 - MULTI-SLIT THYRATRONE - Google Patents

Description

Multi-Slit Thyratron The invention relates to thyratron designs and especially idehrspalt thyratrons. Multi-gap thyratrons have between the cathode and the anode has at least one pair of adjacent electrodes that have two voltages 5 maintenance column separates. Each pair of adjacent electrodes will normally referred to as a gradient grid. A common type of multi-slit thyratron has three voltage withstanding gaps between the anode and the cathode, where the gap closest to the cathode from the middle gap through a gradient grating is separated, which is formed by two adjacent electrodes, and the middle one In turn, gap from the gap closest to the anode through a second one Gradient grid is separated by two more adjacent electrodes educated will. The gas filling is often made of hydrogen or deuterium, a typical example one of the Hehrspalt thyratron currently known types is shown in Fig. 1 as being enclosed Drawings shown.

The thyratron shown in Fig. 1 has a ceramic piston 1, within which there is a cathode 2, a control grid 3, two adjacent electrodes 4 and 5, which form a gradient grid, and an anode 6 are located. When the thyratron has a gradient grating, it is of the type with two columns, with the first voltage withstand gap 7 between the control grid 3 and the electrode 4 is located, while the second voltage withstand gap 8 between the electrode 5 and the anode 6 is provided. The electrodes of the thyratron are fed from a voltage divider connected in parallel to the thyratron. This voltage divider consists of resistors 9 and 10. One end of the voltage divider is with the Cathode connected and grounded, the other end of the voltage divider is connected to the Connected anode, while the intermediate point 11 with the two the gradient lattice forming electrodes 4 and 5 is connected. A resistor 12 is between the electrodes 4 and 5 and the feed path between the electrode 4 and the intermediate point 11 switched to isolate the electrodes 4 and 5 from each other.

Though a voltage is shown steeper and in most cases is used to feed the electrodes 4 and 5, it is also known, a To provide independent feed for these two electrodes by having the equivalent of point 11 is connected to a fixed voltage point via a resistor.

In operation, the two electrodes forming the gradient grid are 4 and 5 held at the same potential before the conduction state. When inserting of the line condition, a tension occurs between them, which ensures that the main relaxation is via the tension holding column and the gradient grid runs in succession. In the case of a thyratron with more than two voltage withstand gaps and correspondingly more than one gradient grid, each gradient grid operates in a similar manner Way, however, from an ignition voltage that progresses for gradient grating closer to the anode is higher.

In the known arrangements of multi-gap thyratrones described above it was found that the performance sometimes inexplicably fails Meets expectations and damages one or more of the gradient grids in occur in an inexplicable manner.

The object of the invention is to create improved multi-gap thyratrons, in which the risk of the aforementioned difficulty occurring is at least reduced is.

A multi-slit thyratron according to the invention has an erection provided, which serves to form that electrode of a gradient grating Electrode pair that is furthest away from the cathode, from the capacitance 'to isolate the associated power supply associated with this gradient grid is.

As can be seen from the foregoing, the invention is presumptive assumed that the aforementioned difficulty, as with known multi-gap thyratron occurs, the consequence of the capacitance is that of the gradient grating associated power supply. Regardless of whether this assumption applies or not, it was found that the use of a device for isolation that electrode of an electrode pair that is furthest away from the cathode is, against such a capacity, of essential use in combating the aforementioned Difficulty is. In Fig. 1, such a capacitance is at 13 with a dashed line Lines shown.

In the case of a multi-slit thyratron with more than one gradient grating, usually means for isolating that electrode, each a gradient grating forming electrode pair, which is furthest away from the cathode, from the capacitance provided, which is assigned to the power supplies of the gradient grid.

The effect to be obtained by the insulation is there in minimizing the risk of having such a capacity the potential of those Electrode of the pair of electrodes forming a gradient lattice that is furthest from the cathode is remote, directly affected, reducing the risk of being an excessive voltage builds up between the electrodes on the gradient grid.

The insulation can take a number of different forms.

In one embodiment of the invention in which the feed for that electrode of a gradient grid that is closer to the cathode above one a voltage difference-maintaining resistance is derived, the with a point in the feed line for that electrode of the gradient grid that is furthest from the cathode is another resistor connected between the mentioned point and the supply for the gradient grid, so that the current that would otherwise flow due to the capacity is that of the supply assigned for the gradient grid is limited.

In a further embodiment of the invention, the feed for that electrode of a gradient grid that is furthest away from the cathode is derived from a resistor that maintains a voltage difference, the one with a point in the feed line for that electrode of the gradient grid is connected, which is closer to the cathode. Between the last mentioned point and A further resistor can be connected to the power supply for the gradient grid. In operation of the embodiment described above, a capacity which is assigned to the supply for the gradient grid, now through the line status between the cathode and that electrode of the pair of electrodes forming the gradient grid, which is closer to the cathode, discharged.

In yet another embodiment of the invention, the contain Separate feed lines for both electrodes forming a gradient grid Resistance, which resistances to one another at their ends facing away from the electrodes and are connected to a supply source for the gradient grating mentioned. In this In the case of operation, each resistance limits the current that would otherwise be generated as a result of the Supply for the gradient grid associated capacity would flow.

In another embodiment of the invention, at which supplies the various electrodes of the thyratron by means of a derived from this voltage divider connected in parallel, contain the Separate feed lines for both electrodes forming a gradient grid Resistance, which resistors at their ends facing away from the electrodes with the opposite ends of a resistor included in the mentioned voltage divider are connected.

The term "resistance" used here is intended to include any Combination of resistance elements which is equivalent to a single resistance, can be understood.

Although, as previously described, the isolation of ohmic Can be kind, it is also possible to use inductive or capacitive elements alone or to be used in combination with one another and / or ohmic elements. At a Example of the use of capacitive elements is a capacitor between the two electrodes forming a gradient grid are connected so that in operation the voltages of the two electrodes tend to change together. This aid can be used in addition to one of the substitute arrangements described above can be used for resistance elements. Instead of switched in this way Capacitors can use nonlinear elements, such as voltage dependent resistors will.

In one embodiment using inductive elements is that electrode of an electrode pair forming a gradient lattice that of the cathode continues with the supply source for the gradient grid connected via a delay line. If the delay line is a coaxial cable is, there is preferably a balancing resistor between this and the supply source switched for the gradient grid. The part of the path which the electrode of the pair of electrodes forming the gradient grid, that of the cathode closer, with the feed for this connects, through the outer conductor of the mentioned Coaxial cable formed.

The invention is described below in conjunction with the accompanying Figures 2 - 9, which show examples of basic forms of thyratron according to the invention, described in more detail.

The multi-slit thyratron shown in FIG. 2 is that shown in FIG identical to the voltage divider supply connected in parallel. According to the invention however, means for isolating that electrode of the gradient grating, i. the electrode 5, which is closer to the Ahode 6, from that of the voltage divider 9, 10 assigned capacity 13. In the present case, these resources consist of a resistor 14 which is in the path between the point in the feed to the electrode 5, to which the resistor 12 is connected, and the point 11 on the voltage divider 9, 10 is switched. In operation, the resistor 12 is used again dazya, the required Voltage difference between dr1; n electrodes 4 and 5 to be maintained. The resistance 14 causes a limitation of the current which otherwise flows to the electrodes 4 and 5 as a result the capacitance 13 assigned to the voltage divider 9, 10 would flow.

The arrangement shown in FIG. 3 is that in FIG. 2 shown similar except that it is the feed line to electrode 5 instead of the electrode 4 which includes the voltage difference maintaining resistor -12 '. The insulation resistance is between the point in the feed line to the electrode 4, to which resistor 12 is connected, and point 11 on the voltage divider 9, 10 switched, although the resistor 14 is omitted in this design can. In this case, the voltage divider 9, 10 is assigned during operation Capacity 13 due to the conduction state between the cathode '2 and the electrode 4 unloaded. The stray capacitance now connected to the electrode 5 is largely that of the thyratron itself, which is much smaller than that of the voltage divider 9, 10 is assigned. There is a voltage dividing effect within the thyratron (as a result of the distribution of capacitances between the electrodes) instead of what leads to The effect is that the voltage between the electrodes 4 and 5 is reduced.

In the arrangement of FIG. 4, the feed lines contain both Electrodes 4 and 5 insulating resistors 16 and 15, which both serve these two To 'isolate electrodes from one another in order to achieve a desired voltage difference between to maintain them and of the capacitance assigned in the voltage divider 9, 10 13, so that the current is limited, which otherwise initially in the two electrodes would flow.

The arrangement shown in FIG. 5 is that shown in FIG. 4 in this respect similar as the feed lines to both electrodes 4 and 5 are insulating resistors 16 and 15 included. In this case, however, the electrodes 4 and 5 are remote Ends of resistors 15 and 16 do not with each other and one thing in common Point (11 in Fig. 4) connected to the voltage divider 9, 10, but with the opposite Ends of a resistor connected between resistors 9 and 10 in the voltage divider 17th

The resistor 17 causes an initial voltage difference to arise between the electrodes 4 and 5, while as in the arrangement of 'Fig. 4 the Resistors 16 and 15 limit the current that would otherwise initially go to the electrodes 4 and 5 flow as a result of the capacitance 13 assigned to the voltage divider 9, 10 would.

In the embodiment according to FIG. 6, the supply for the electrodes 4 and 5 are not derived from a voltage divider connected in parallel to the thyratron, as in the previously described embodiments, but from a separate one Voltage source 18 via a resistor 19. Otherwise, the arrangement of the in 4 shown similarly.

In Fig. 7, one way of using an inductive element, in this case a coaxial line 20, shown to isolate the grating 5 to be achieved by the capacitance 13 assigned to the voltage divider 9, 10. In the illustrated embodiment is the coaxial line 20 with the feed line from Voltage divider 9, 10 connected to electrode 5. A balancing resistor was 21 connected in series with the coaxial line 20. The feed path for the electrode 4 runs directly in this particular case, although the outer conductor of the Coaxial line 20 is used as part of this path.

Fig. 8 shows an embodiment of the invention in use a multi-slit thyratron with more than two Columns (in the present Case of three columns) and more than one gradient grid (in the present case of two gradient grids). The additional gap is denoted by 22, while the additional gradient grating is formed by two electrodes 23 and 24. The feeding for each gradient grid is similar to that for the single gradient grid the arrangement of FIG. 4 is provided. The resistances in each of the feed lines the additional electrodes 23 and 24 are denoted by 25 and 26. Operational resistors 15 and 16 as well as resistors 25 and 26 are exactly the same Effect like the corresponding resistors 15 and 16 in Fig. 4.

As with the known arrangements is the nominal voltage of the gradient grating 4, 5 provided so that they are higher than the nominal voltage of the gradient grating 25, 24 is what is achieved by installing another resistor 27 in the voltage divider will.

In the embodiment of FIG. 9, the insulation is between the electrode 5 and the capacitance 13 assigned to the voltage divider 9, 10 are full capacitive. This arrangement is in fact that of Fig. 1 with the additional one Use of a capacitor 27 between electrodes 4 and 5. The use this capacitor has the effect during operation that the voltages of electrodes 4 and 5 change together, reducing the risk of flashover is decreased between the electrodes.

It should be mentioned here that the embodiments described above are only examples of basic forms according to the invention. These basic forms can in many cases can be combined if desired. For example, all according to the embodiments Fig. 2 - 8 capacitors between the two electrodes of a gradient grid are switched, as shown in FIG. Furthermore, in the embodiments according to FIGS. 2-6 and 8, the insulating resistors in many cases by means of inductive isolating elements, for example by means of delay lines or cables can be replaced or combined with them.

Patent claims:

Claims (11)

Claims: 1.) Multi-gap thyratron, characterized by means (14) for isolating that electrode 5 of an electrode pair forming a gradient grid (4, 5), which is furthest away from the cathode (2), from the capacitance (13), which is assigned to the feed (9, 10) connected to the gradient grid, 2. Thyratron according to claim 1, with more than one gradient grating, characterized in that Means for isolating that electrode of each electrode pair forming a gradient grid, that is furthest from the cathode are provided by the capacitance that are assigned to the supply of the gradient grids, 3. Thyratron after opening 1 or 2, in which the feeding of that electrode of a gradient grating that the Closer to the cathode, via a resistor that maintains a voltage difference is derived, the line with a point in the feed line for that electrode of the gradient lattice, which is further removed from the cathode characterized in that a further resistor 614) between the mentioned point and the supply (11) for the gradient grating is switched to thereby Qen current, Bei otherwise as a result of assigned to the feed for the gradient grating Capacity would flow is limited. 4. thyratron according to claim 1 or 2, wherein the feed for that electrode of a gradient grid that is furthest away from the cathode is derived from a voltage difference maintaining resistor with a point in the feed line for that electrode of the gradient grid is connected, which is closer to the cathode, characterized in that another Resistance (14) between the last-mentioned point and the feed for the gradient grid is switched. 5. thyratron according to claim 1 or 2, characterized in that the Feed lines for both electrodes (5, 4), which form a gradient grid, each contain a separate resistor (15, 16), which resistors at their the Electrodes remote ends together and with a supply source (11) for the mentioned gradient grids are connected. 6. Thyratron according to claim 1 or 2, wherein the feeds for the different electrodes of the thyratron from one connected in parallel to them Voltage dividers are derived, characterized in that the feed lines a separate resistor each for both electrodes (5, 4) forming a gradient grid (15, 16) contain resistors at their ends remote from the electrodes with the opposite Ends of a resistor (17) connected contained in the voltage divider (9, 10). 7. Thyratron according to the preceding claims, characterized in that that a capacitor (27) between the two electrodes forming a gradient grid (4, 5) is connected, so that the potentials of the two electrodes during operation change together. 8. thyratron according to claims 1-6, characterized in that a non-linear element, for example a voltage-dependent resistor between the two electrodes forming a gradient grid is connected, so that in operation the voltages of the two electrodes tend to change together. 9. thyratron according to claim 1 or 2, characterized in that that electrode (5) of an electrode pair (4, 5), which is furthest away from the cathode (2), with the supply source (9, 10) for the gradient grating is connected via a delay line (20). 10. thyratron according to claim 9, characterized in that the delay line (20) is a coaxial cable and a balancing resistor (21) between this and the Food source (9, 10) is switched for the gradient grating mentioned. 11. thyratron according to claim 10, characterized in that a part the path that takes that electrode of the pair of electrodes forming the gradient grating mentioned, which is closer to the cathode, connects to the supply for this, through the outer conductor of the coaxial cable is connected.