DE1042646B - Impulse distributor - Google Patents

Description

GERMAN

The invention relates to incremental distributors of electrical pulses of a given number of stages that are operated one after the other by input pulses. In particular, the invention relates on such pulse distributors, in which the pulses are fed to a collecting line leading to all stages leads. These are connected in cascade in such a way that the actuation of a stage the activation of the following stage is prepared by the next impulse, while the previous one Level is retired. The aim of the invention is the construction of such devices in such a way that they not only work at very high speeds and therefore impulses with high frequencies, but also to those connected to the individual outputs Consumers can deliver currents, which in terms of the current levels required for control, the are supplied by the pulse trains to be distributed, have significant values. The ratio of output currents to the control currents is here z. B. between 100 and 1000 or even more more.

The pulse distribution circuit according to the invention makes a plurality of gas discharge paths for this purpose Use, with each discharge path having a cathode, an anode and a control electrode or auxiliary electrode.

The invention also relates to such a multiple-length gas discharge tube which is practical represents the entire pulse distribution circuit of the type indicated above.

In a known pulse distribution circuit which has a plurality of gas discharge paths with an auxiliary electrode the input pulses of each control electrode are transmitted via a capacitive connection, which is connected to the manifold on which the pulses occur. The anodes get together the anode voltage, while the pick-up terminals for the distributed pulses in the cathode leads lie. The cathode of a gas discharge path is capacitively connected to the cathode of the following discharge path and also via a Resistance connected to the control electrode of the following discharge path.

A gas discharge tube with several gas discharge paths of the same type is known Anode, each of which has an annular cathode and an ignition control electrode, the cathode each Discharge path apart from the last one with the cathode of the following discharge path capacitive and with the control electrode of the following discharge path is coupled via a resistor. Here are wise the individual cathodes each have different distances from the pulse distributor

Applicant:

SEA Societe d'Electronique

et d'Automatisme, Courbevoie, Seine

(France.)

Representative: Dipl.-Ing. E. Prince and Dr. rer. nat. G. Hauser, Patent attorneys, Munich-Pasing, Bodenseestr. 3 a

Claimed priority:
France January 25, 1956

from the anode attached to one end of the tube. The control is done in stages increasing anode voltage. The individual discharge paths do not work by means of separate ones Ignition electrodes one on top of the other. This tube is therefore for the purpose of the invention, namely as a pulse distributor, not suitable.

In contrast, according to the invention, the individual gas discharge paths are stacked on top of one another Cathode rings and intervening insulating washers cut out for the purpose of correlating the gas filling formed, the thickness of which is chosen so that the desired capacitive between the cathodes Coupling occurs that each ring cathode with a per se known feedthrough through the tube wall it is provided that a conductive central rod serves as a common anode for the discharge paths, that an eccentrically arranged, as a collecting line for the application of the impulses coming for distribution Serving conductive rod is present, the cathode with the interposition of a dielectric carries opposite rings, which represent the control electrodes, and that the coupling resistors between each cathode and the conductive ring, which forms the control electrode of the next discharge path, made of a Layers of applied conductive coating.

A main advantage of the invention is the use of similar items that are only in any Need to be assembled to create a fully enclosed pulse distributor of the number

309 67T / 150

to obtain the desired number of stages with completed »wiring«. The extremely simple structure requires a increased reliability in manufacture and operation. The circuit structure becomes extraordinary easy and reliable. After completion of the tube, all elements are protected by the piston, so that it is not exposed to external influences.

Details of the invention emerge from the description with reference to the drawing. Herein shows

1 shows the graphical representation of the momentum distribution in a tube according to the invention,

2 shows a circuit diagram of the pulse distributor according to the invention, selected as an example,

3 shows the structure and the practical implementation of a distributor tube according to the invention.

The tube according to the invention contains a plurality of gas discharge paths I, II, III, IV etc. Each discharge path contains a cathode 2, an anode 3 and a control electrode 4 in a gas 1. Each cathode has an output 11 and feeds a consumer at a given time, which represents a resistor 9 here. The loads are preferably connected at the other end to ground or to the negative pole of the anode voltage source + HT , specifically via a common resistor 12 in the example shown.

An input bus 10 receives the pulse trains as they are recorded in the first line of the illustration of FIG. The distribution cycle takes place in a time interval T.

In each sequence of η pulses, the first pulse causes an output pulse to appear at the cathode terminal 11 of the discharge path I. This output pulse remains until the second input pulse arrives at 10, which ignites the second discharge path II, and so on.

The collecting line 10 ″ is coupled to the control electrodes 4 of the discharge paths by means of the capacitors 6. All discharge paths have one anode rod 5 in common, to which the voltage + HT is applied. In the circuit shown, the voltage divider 13-14, which supplies the bias voltage for the control electrode of the first discharge path of the circuit via a resistor 8, leads from this collecting rod to ground. The size of this bias voltage is chosen so that, in conjunction with the amplitude of the input signal E, the ionization voltage of the gas 1 between the control electrode 4 and the cathode 2 of the first discharge path is achieved. Then when the first pulse of the sequence under consideration arrives, the discharge path I and only it becomes conductive. The auxiliary discharge causes the ionization of the gas, and the discharge path carries such a high current that the discharge is sustained even when the introductory impulse has disappeared. The internal resistance of the ignited discharge path is very low, which is why the gas discharge creates a strong voltage drop in the consumer connected to the cathode.

Since the cathodes are connected to one another by the capacitors 7, the first discharge path the coupling capacitance between this cathode and that of the second Discharge path charged to the cathode voltage. This positive tension is also shared by the Resistance 8 assumed that the cathode 2 of the discharge path I with the control electrode 4 of the Discharge path II connects.

When the second pulse occurs at 10, path II is triggered as a result. Your anode voltage suddenly increases, which means that a positive pulse is transmitted to the cathode of path I via 7 whose amplitude is sufficient to delete this distance I.

This process repeats itself from stage to stage, so that the circuit acts like a step-by-step working pulse distributor with amplification and pulse lengthening behaves.

According to the invention there is a \ '"ielkathodenröhre, which embodies this whole circuit, each cathode 2 from a ring, the z. B. with two diametrically opposite extensions is provided (Fig. 3 a). An extension 16 is massive while the other extension 17 is slotted and forms a bracket. In at least two other places recesses 26 are provided in the circumference. In the inner cutout of the ring is opposite the tongue 16 has a recess which is centered in the axis of this tongue. The cathodes exist for example made of sheet nickel, 1 mm thick. These cathodes are stacked on top of one another as shown in FIG. 3e, wherein their mutual distances are maintained by two spacers 18 (Fig. 3 b) and 23 (Fig. 3 c) will.

The first spacer 18 (Fig. 3 b) consists of insulating material (mica or ceramic) of, for example 7 to 8 microns thick. For the sake of clarity, the proportions are not taken into account. The disk 18 also has two extensions or extensions, one of which is extension 19 massive and the other extension 20 is incised. The disc is in its center at 21 pierced. From Fig. 3 e and 3 f it can be seen that a single cylindrical anode, for example a Nickel rod, is provided, the diameter of which is 4.5 mm in the embodiment, while the inner diameter of the ring cathode is 17 mm. The anode rod is used to center the Spacers 18 and the spacers 23. The latter are made of the same material as the Spacers 18, for example, have the same thickness and also have the same bores 21 in the middle and 22 in an eccentric position. Each spacer 23 also has a massive extension 24 and a slotted extension 25. The eccentric bores 22, which are in the assembled state align with the depressions in the cathodes, serve to center the auxiliary electrode.

It can already be seen that the arrangement of the cathodes and their intermediate layers there is a capacity between two ring cathodes. The value of this capacity depends on the Size of the opposing cathode surfaces and the thickness of the insulating jacket between them off. These sizes can be chosen so that the coupling capacitances 7 (Fig. 2) between successive cathodes can be reached directly. In the practical embodiment has each capacitance so obtained has a value of about 800 picofarads.

The two insulating liners are, therefore provided so that one of them (here the part 18) can be provided with an imprint that denotes the Coupling resistance 8 between the cathode of a discharge path and the control electrode of the following Route represents. In the example under consideration, this resistance should have a value of approximately 300,000 ohms. However, this value is not critical, but can have tolerances of around .20

exhibit. Each resistor 8 can as a result:

be produced approximately as follows: On both sides of the tongue 19 is approximately up to the height shown a mixture of 7 parts by weight of a silicone resin and 1 part of colloidal charcoal is applied. on On one side, a strip is also coated with this mixture up to over the bore 22. Even the edge of the tongue 19 is painted. The so coated liner is for three hours at Treated in the oven at 220 ° C to stabilize the resistance formed.

When the cathodes and the intermediate layers are stacked on top of each other, the short side of the Resistor 8 in contact with a cathode (Fig. 3e). The longer side comes in contact with the control electrode of the following discharge path, since this electrode through the bore 22 with relatively strong friction goes through it.

All control electrodes are carried by a rod 10 which, in electrical terms, is the collecting line of Fig. 2 represents. This rod consists for example of aluminum and has in the embodiment a diameter of 3 mm including a coating 32 of aluminum oxide on it Surface. At regular intervals (Fig. 3 d) electrodes 4 made of silver, platinum or are on the rod Charcoal applied, which serve as control electrodes. At the same time they form an assignment of the capacitor 6, the other assignment of which is represented by the part of the rod 10 which they surround. Every Electrode 4 has a width of 1 mm, for example. In the finished stack, each electrode 4 is through Friction when passing through the hole 22 is electrically connected to the corresponding resistor 8. As a result, the cathodes are connected to the following control electrodes as shown in FIG. 2 via resistors.

In order to produce the arrangement according to FIG. 3 d, a rod made of pure aluminum can be anodically oxidized. If the electrodes 4 are to consist of carbon, for example with the help of colloidal Carbon dissolved in isopropyl alcohol precipitated the charcoal. When the electrodes are off Platinum is supposed to consist of platinum chloride. With silver electrodes you can use a mixture of metallic silver with fusible glass powder in a solvent and then that Heat the whole thing. In this way, individual capacities can be achieved, which in the exemplary embodiment are approximately 400 picofarads.

In all cases, when assembling the individual elements so formed, by insulating Bars 30 (Fig. 3f) are laterally guided, formed separate discharge paths, the Thickness is the same as that of the cathode. The control electrode has the same thickness. The latter is automatically held in the vicinity of the cathode, while the axially arranged anode, for example is at least five times further away.

The assembly can be carried out as follows: The rods 10 (already prepared) and 3 are melted into a tube base made of glass or ceramic and an insulating spacer 33 is threaded onto these rods to create a corresponding stop surface for the assembly that now follows to build. For the moment a bushing 15, which is isolated in the foot, is housed is not taken into account. Now a first intermediate piece according to FIG. 3 b, then an intermediate piece according to Fig. 3 c and then a cathode according to Fig. 3 a threaded. This is the order in which the assembly is carried out continued and the same ended either with a cathode if the circuit is not fed back is to be, or completed with an intermediate layer according to FIG. 3 b in the opposite case. The latter intermediate layer is not in electrical contact with a control electrode 4, but its resistance 8 is connected to a bushing through the tubular piston in known Way through. This piston 28 is preferably placed on the assembled electrodes, being guided by rods 3 and 10 and rods 30. The latter are insulating and naturally melted into the foot 27. The tube 28 is then connected in a known manner by an annular seam fused with the foot.

After attaching the first intermediate layer, the resistance layer was the same (Fig. 3 b) with the implementation 15 has been soldered. When the circuit with respect to the control electrode of the first discharge path should correspond to Fig. 2, this first intermediate layer could be specially shaped for this purpose, i.e. the voltage divider 13-14 could be formed directly on it and the wire 15 through a Tap to be replaced, which is used to connect the printed voltage divider to ground, such as it is described for the individual resistors 8.

The tubular piston 27 is slit longitudinally and so

arranged that the slot is in front of the notches of the parts 17, 20 and 25, which of course are aligned.

Then pieces of wire 11 are inserted through this slot that one wire each in the slot of a cathode 2 comes, the output of which he represents. Then an ethoxylin resin is poured into the slot, whereby a seal results that withstands the vacuum of a few millimeters of mercury, which is the gas pressure prevails in the finished arrangement. Helium is preferably used as the gas filling. The evacuation the tube and its gas filling happens through the pump nozzle 31. A small proportion of Hydrogen (about 2 to 5%) can be added to the helium.

After completion of the assembly and after the pump nozzle has melted, the The circuit according to FIG. 2 emerged in a very compact and robust form, apart from the supply voltage sources and the consumers of the impulses distributed over the individual channels. Besides these advantages it can be stated that the small dimensions and thicknesses of the cathodes make the use of a Material with a high work function, such as nickel, allow, d. H. of a material that is affected by the deionizing Components of the gas filling cannot be destroyed and practically neither photoelectric Properties still showing secondary emission.

On the other hand, the volume of the individual discharge paths is practically very small, so that the Ions can only travel short distances after the discharge paths have been extinguished. As a result occurs nor the advantage that the arrangement is particularly suitable for the distribution of very rapid pulses.

Claims (5)

Patent claims: 1. Pulse distributor, consisting of a gas discharge tube with several similar gas discharge paths with a common anode, each with an annular cathode and an ignition control electrode with the cathode of each discharge path except the last one with the cathode of the following charging path capacitive and with the control electrode of the following discharge path is coupled via a resistor, characterized in that the individual gas discharge paths, by stacked cathode rings (2) and between them are cut out for the purpose of connecting the gas filling Insulating washers (18) are formed, the thickness of which is chosen so that the desired between the cathodes capacitive coupling occurs that each ring cathode with a known per se. execution (11) verseben through the tube wall is that a conductive central rod (3) as common Anode for the discharge paths that an eccentrically arranged serves as a collecting line for the application of the incoming impulses serving, conductive rod (10) available is, the rings (4) opposite the cathodes with the interposition of a dielectric (32) which represent the control electrodes, and that the coupling resistors (8) between each Cathode and the conductive ring, which forms the control electrode of the next discharge path, consist of a conductive coating (8) applied to the insulating intermediate layers. 2. Pulse distributor according to claim 1, characterized in that that each cathode ring is cut out so that it is in this recess without direct contact picks up the conductive ring, which the control electrode (4) of the relevant Discharge distance represents while each Insulating washer (18) has a hole (22) which serves as a bearing for the rings (4) and an electrical one Contact between this ring and the conductive coating (8) established with his the other end rests against the cathode ring of the preceding discharge path. 3. Pulse distributor according to claim 1, characterized in that that each cathode ring has a slotted extension (17), the one produces resilient contact between the cathode and a lead-through rod (11), which in the tubular piston is inserted. 4. pulse distributor according to claim 1, characterized in that the collecting line (10) from Consists of aluminum, is covered with buckets of aluminum oxide and carries the conductive rings, formed by precipitation on the aluminum coating. 5. Pulse distributor according to claim 1, characterized in that as coupling resistors Serving coatings (8) consist of colloidal charcoal, which is applied in a strip that goes from one side of the insulating disk over the edge to the other string, in particular over the edge of a radial extension of the disc. Considered publications:
German Patent No. 918 452;
U.S. Patent No. 2,375,890. 1 sheet of drawings © 309 677/150 10.5 &