DE974934C - Gas-filled electric glow discharge tubes with cold cathode and at least three discharge paths - Google Patents

Description

(WiGBl. P. 175)

ISSUED JUNE 8, 1961

I 3591 VIII c12ig

The invention relates to gas-filled electrical discharge tubes with cold cathode and a plurality of discharge paths in the same bulb so that the discharge paths are sequential can be ignited by the discharge of a certain distance depending on the ignition conditions influenced by another. The invention particularly relates to the construction and operation of Trigger tubes, whereby by the discharge of a triggering auxiliary path with lower ignition voltage as the main line, the ignition voltage of a main discharge line into a corresponding one Condition is brought about, and the invention also relates to the question of the operation of such arrangements at high speed. In its general aspect, however, is the application of the invention is not limited to trigger tubes. The nature of the present invention can be best understand, and the terms used in the description are best defined, if one considers the phenomena involved in the initiation and maintenance of glow discharges apply in the sections of a tube with several discharge sections. If between

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a glow discharge is maintained at the electrodes of a discharge path, so lies the voltage between anode and cathode is generally below that for initiating the discharge required value. In the permanent state, a cloud of positive ions is preserved in the Near the cathode. An ion that flies towards the cathode along the potential gradient therefore makes Electrons are released, which tend to move along the lines of force between the cathode and anode to accelerate. After exiting the cathode, these electrons ionize through collision Gas molecules on their way so that equilibrium is maintained between the Number of ions that fly to the cathode or to other parts of the cathode in a given time To dissipate towards the tube, and those numbers which are at the same time as a result of collisions which forms new electrons emerging from the cathode surface. Part of the from the cathode surface escaping electrons or electrons released by collisions en route reaches the Anode and causes a current in the external circuit. In the area of the aforementioned ion cloud light energy is also emitted so that glowing light covers part of the cathode surface, but in reality it is separate from it. The usual textbooks count, although in a discharge column several glow zones, but the aforementioned applies to tubes of the type considered here Cathode glow before. As long as the cathode glow does not cover the entire cathode surface covered, the discharge is called "normal". That of a normal glow discharge corresponding potential distribution between anode and cathode is such that the greatest change in potential lies between the cathode and the cathode glow zone and has a value that from Material of the cathode surface and the ionized gas depends. The potential fall in this zone, which in future will be referred to as "cathode drop" is a few volts below the minimum ignition voltage the Paschen curve, which shows the ignition voltage with the product of the length of the ignition gap and gas pressure for the gas and electrode material in question. The geometric Length between the cathode and that point of the discharge path where the potential rises to a maximum value for the first time is the same as that of the minimum ignition voltage corresponds to the aforementioned Paschen's curve when the gas pressure is kept constant. In the In the present description, this length shall be referred to as the length of the cathode fall. Between the cathode glow and the anode, the potential first drops a little and then rises uniformly to that of the anode, with the size of the potential rise behind the cathode drop Is a function of the route length, the type of gas and the gas pressure.

Within certain limits for the discharge current, which define the current range for normal glow discharges, the voltage between anode and cathode has the tendency to be independent to be from the stream; it is referred to as the continuous voltage of the discharge of the line. The continuous voltage (= burning voltage of the discharge) is therefore one for each route Function of the route length, and the curve that links the continuous voltage with the route length, All other things being equal, it is of a similar form to the above-mentioned Paschenschein Curve, but lies below it and is not that steep. The minimum value of the continuous voltage is the cathode fall - a few volts below the minimum ignition voltage.

The cathode area covered with glow light during a normal discharge is proportional to the discharge current. If the existing cathode area is completely covered with glow light, the tension rises on the track and one designates the discharge then as "abnormal". In order to maintain the space charge conditions in the route, a minimum current is required, otherwise more ions disappear from the path than re-emerge from collisions. Therefore, if the current is reduced in one section, so the voltage required to maintain the discharge increases very rapidly.

If you apply a voltage above the ignition voltage, as indicated by the corresponding Paschen's curve is given for the respective gas mixture and the electrode materials present becomes, this in itself is not sufficient to achieve a Initiate discharge. It is found that there are no ionization or incidence on the cathode Radiation no discharge can occur. If a voltage sufficient to ignite a path is applied, it goes away initially only a certain time before the discharge actually begins, since at least one is charged Particles in the field must be present within the distance.

In the present description, a discharge path will then be referred to as “ignited” if a discharge of such strength has set in that when you apply a Voltage equal to the continuous voltage of the route can continue to exist. The time between the application of a voltage required to ignite the path and the actual ignition elapses can be divided into three sections, namely into the statistical delay duration, the formation delay duration and the "5 Construction time. Before the space charge ratios in the route build up, as stated above can begin, at least one charged particle must be present in the field of the path. This Charged particles can be brought about by various means, e.g. B. by altitude rays, Irradiation of the cathode by ultraviolet light, emanation of in the tube bulb introduced radioactive substances, etc. The period of time between the application of the ignition voltage and the arrival of the first loaded partial

chens in the route usually depends on events occurring in irregular sequences and is therefore referred to as the statistical delay duration. It then becomes another Period of time taken during which there is the necessary to maintain the discharge Space charge builds up around the cathode. This is called the education delay duration. she depends on the applied voltage and the size ίο and distribution approximately already present in the route Ionization. So that the desired current finally comes about, which is the space charge ratio is maintained in the route, an additional period of time known as the setup time becomes needed. The construction time depends on the time constants of the external circuit.

Once a certain distance is ignited in a tube with several discharge paths has, then the discharge of the remaining ao sections is generally carried out by that of the first Route influenced in a certain way. Charged particles or photons from the original Discharge can then migrate into a second route, where it has the statistical duration for this route you can reduce or eliminate it entirely and where it depends on your spatial and reduce the voltage required to ignite the second path over time can. This reduction in the ignition voltage and the statistical delay in the second section as a result of the discharge in the first section is referred to here as »pre-glowing«, and the amount (in volts) by which the ignition voltage of the second path changes as a result of the discharge decreased in the first is called the ionization coupling factor. He is one Function of the positional relationships of the two pairs of discharge electrodes. By appropriate arrangement the discharge electrodes can be the ionization coupling between an ignited and make a non-ignited path sufficiently large so that the ignition voltage of the non-ignited Stretch until it is pressed down to its continuous tension.

In the case of trigger tubes, there is generally a main discharge path to which one suffices Voltage applies to maintain the discharge there and one for a weak current dimensioned auxiliary distance for tripping, which is set up is that it has a lower ignition voltage than the main line, so that a weak one to the Trigger path applied pulse causes the main path to ignite. The length of time between the ignition of a trigger path and the establishment of the space charge conditions on the main discharge path must elapse is referred to as the transmission time between the trigger and main line. Therefore, in a trigger tube the period of time between the application of a pulse to the trigger path and the ignition of the Main route elapses, divided into the statistical time delay of the triggering route, the Transmission time and the setup time of the main line. In general, the pipemaker can work on the construction time does not have an effect, but he can construct a tube so that the transmission time becomes negligibly small.

As an alternative solution to the measures already mentioned, it has long been known to use the statistical Reduce or eliminate delay time by putting in a glow discharge tube maintains a preparatory auxiliary discharge, which has the task of providing the necessary charged To supply particles to start with so that a line can ignite at all. In general A discharge at the pre-glow path also reduces the ignition voltages of all others Stretch in the tube. For some purposes it may be desirable that the pre-glow discharge the Reduce the ignition voltage of one or more sections in the tube to a specific value target; again, it may sometimes be desirable to add only the statistical time delay to switch off the ignition of a certain individual distance.

There are also already gas-filled glow discharge tubes with cold cathodes and at least three discharge paths, namely a main discharge path, a control or trigger path and a pre-glow path, known. With these well-known However, the electrodes of these individual discharge paths are arrangements in relation to one another arranged that the ionization products of the individual routes affect the other routes.

In order to avoid this disadvantage, in the case of a gas-filled glow discharge path with a cold cathode and at least three discharge paths, namely a main discharge path, one Control or release path and a pre-glow path, proposed according to the invention, the control or To arrange the triggering path between the pre-glow path and the main discharge path, that the electrodes of the control or release path are the main path against ionization products shield the discharge of the pre-glow path, during the discharge of which is sufficient for the statistical delay time of the To eliminate control or release path essentially.

It is important that the pre-glow discharge be uninterrupted. With many of the earlier ones Suggestions that worked with auxiliary discharge, the discharge was not steady or of the type of ' Tilting vibrations, which are to be referred to below as blocking vibrations. For example, in some of the earlier proposals the discharge was of the corona type, the is fundamentally discontinuous, since it contains sudden current surges, which are called Trichelian discharges are known. When working with rapidly deionizing discharge sections, it has been observed that too Auxiliary discharges with discontinuous peaks used for occasional purposes give rise to decided uncertainty in the ignition time of the started discharge path, an uncertainty that disappears,

as soon as the preparatory auxiliary discharge runs steadily.

The invention will now be described with reference to the drawings. It is Fig. Ι the schematic structure of a trigger tube based on the invention,

Fig. 2 is an enlarged view of part of the tube Fig. I,

3 shows the structure of the preparatory auxiliary section of Fig. i,

4 shows a characteristic circuit arrangement based on the invention,

Figure 5 is a partially cutaway view ^of. The electrode structure of another embodiment of a tube due to the invention,

FIG. 6 shows a vertical section through the structure of FIG. 5.

FIG. 7 shows a horizontal section along the line VII-VII in FIG. 6;

Figs. 8, 9 and 10 are views of another embodiment of the invention, respectively Figures 5, 6 and 7 correspond.

"· When considering the structure of a trigger tube great speed according to the present invention must after eliminating the effect of Statistical Delay The other time factors are considered to be related to the operation of the trigger tube have to do and can be influenced by the pipe builder. It is the educational delay in the triggering section, the transmission time and the deionization time in the triggering section and the main section. If the The voltage applied to the electrodes of the discharge path is reduced below the value that is necessary to maintain the space charge conditions, the charged particles become The route is ultimately eliminated by the following processes: Reunification of ions and electrons in the gas, diffusion out of the path and absorption in electrode surfaces. diffusion and reunification of gas ions are both slow. For those in one of the below Embodiments described present charge distributions are calculated that by 4-5 reunion in the whole affected volume the number of free ions in the course of a half Second is only reduced by half. So it is clear that if operated at high speed It is necessary that the ions are set in motion so rapidly towards the electrode surfaces must be, as it is only possible, without one to somehow create significant numbers of new ionizing electrons. For rapid deionization If it proves necessary, the -electric field to reduce the distance between the electrodes by a very specific amount at most. In order to If the ions move away due to acceleration towards the cathode, deionization takes place fastest when the ions are forced to move into very specific ones during the quenching Move lanes. Rapid deionization times can therefore be achieved if for the sections of cylindrical electrodes are used, the outer cylinder forming the cathode. On the other hand, you have to go to a route in general a voltage above the continuous voltage can be applied so that it can be discharged through a discharge a trigger path is ignited. Of course, as long as there is no discharge, it is practical due to the lack of a voltage drop across the load resistor, the voltage across the main electrodes always greater than the continuous voltage. In most electrode designs, however, a minimum voltage which is above the continuous voltage of the main line, below which a transfer of the discharge from the release line to the main line does not occur. this As application examples of the present invention, includes cases where the transmission time when a transmission takes place is negligibly small or zero. From the point of view of a lower one Transmission voltage, the design should be such that, during the build-up of space charge conditions in the main path, the ions on the Want to converge cathode. In the case of a concentric discharge electrode arrangement, the Cathode therefore form the inner conductor. It follows that when both short deionization times as low transmission voltages are required, the most favorable arrangement is the use requires flat electrodes.

An example of application of the invention using planar electrodes is shown in FIGS. 1, 2 and 3 shown. In order to bring out the details of the construction in these figures, the Thickness of the individual electrodes, insulators and their spacing drawn considerably exaggerated. the Tube consists of a conventional glass bulb 1 with a pressed glass base 2 on which the electrode system is constructed between a pair of mica insulators 3 and 4 as in conventional radio tubes. The main discharge path 5 is formed between an anode 6 and cathode 7, while a Trigger electrode 8 is installed in the space between anode and cathode so that a trigger path 9 is created. The trigger electrode 8 is shaped so that a closed space 10 is created, the is shielded from the field of the anode 6, since the release path 9 is on the edge of this space. An auxiliary discharge path for pre-glowing is provided by an auxiliary anode 11 and an auxiliary cathode 12 formed while the actual discharge surface of the anodes, as explained later, on the walls of a Opening 13 remains restricted. The auxiliary discharge line is thus built behind the main line 5, SO 'that it is shielded from them, whereby the Shell is provided with a path through passages 13, 14 and 15 in the various components, so that ionization products - practically an electron beam - pass through the trigger path can.

The components belonging to the main and release line are part of a single unit united, while the pre-glow path forms a different unit for itself. The anode 6 is off Shaped sheet metal, the ends of which are bent so

that they pass through slots in a mica plate 16, these ends on the other Side of the plate, as shown at 17, are bent. The mica plate is secured by ring rivets 18 16 on opposite upwardly curved sides 19 and 20 of a pair of opposite sides Profile metal pieces 21 clipped (Fig. 2). The cathode 7 is on a mica plate 22 approximately like the anode 6 attached. Meanwhile, the cathode material is sputtered into the mica insulator can not affect the edges of the cathode 7 opposite the surface of the insulator 22 raised in that the part 7 sits on a thin metal strip 23, the Ends are inserted through slits in the insulating mica and bent on the opposite side. This metal strip 23 is of a thickness which is smaller than the length of the cathode fall at normal glow discharge at cathode 7, so that

so the glow light is on that side of the cathode electrode limited facing the anode. The trigger electrode 8 is shaped so that a shell that is open on one side is created. It sits on the plate 22 like a container on a wall.

Tabs on the trigger electrode 8 extend through slits in the mica part 22 and are after outward curved, d. H. perpendicular to the plane of the drawing Fig. 1.

In order to eliminate irregularities in the formation delay time of the triggering path, the Trigger discharge set up in such a way that it occurs on a limited, well-defined part of the cathode surface occurs and is not punctiform. For this purpose, the end of the cathode tapers and reaches just inside into the envelope formed by the trigger electrode 8, so that they facing it as a triangular surface. Both from the point of view that the ignition voltage of the The trigger distance should be as short as possible, such as that the transfer time should be as short as possible should, the distance between the cathode and trigger electrode is made so that it is approximately equal to the Length of cathode fall for normal glow discharge at the cathode is.

* 5 To avoid the possibility of a discharge between To exclude the trigger 8 and the anode 6, the trigger surface opposite the anode becomes covered by an insulator 24, which is inserted through slots in the profile share 21, as can be seen at 25 in FIG. As another precautionary measure, you can remove the inner surface of the With the exception of a narrow area opposite the cathode extension, the trigger electrode 8 calorifies.

A metal plate 26, the function of which will be explained later, can be the front side of the insulator 24 cover and is held by the same slots in the profile share 21 so that they are in electrical Contact with them.

Around a discharge between the cathode and trigger leads on the back of the isolator To prevent 22, another plate 27 of insulating material covers the bent parts of the Cabinet flaps of the cathode and the trigger. The insulating plates 22 and 27 are bent over to the Pages 28 and 29 of the profile parts 21 attached by means of ring rivets 30. The ones for the main and Tripping path described construction, the distance between the main path electrodes by the Side parts of the profile pieces 21 is observed, ensures that there are tight manufacturing tolerances and the tube properties can only be changed very little from tube to tube.

The pre-glow path kit consists of a mica plate 31 on which the auxiliary anode 11 and cathode 12 sit. The cathode 12 is formed by a piece of ribbon-like metal 32, the End pushed through a slot 33 in the insulator and bent so that it is flat on the The small bent piece forms the cathode electrode. the Anode 11 consists of a one provided with an opening Piece of sheet metal, the ends of which are bent over and riveted to the insulator 31, as can be seen at 34 in FIG. The metal of the anode is thicker than that of the cathode, so that the The anode does not touch the cathode and leaves a gap which is shorter than the length of the cathode fall for a normal glow discharge at the cathode 12. An opening 13 is in the anode mounted opposite the cathode 12. The insulator 31 is attached to rods 35 by means of ring rivets, which are welded to the corresponding rivets 18 and 30 of the main and trigger line assembly are. As a result, the pre-glow path is precisely defined in relation to the triggering space 10.

Because of the small distance between the electrodes, the normal discharge is limited to the opposite the opening 13 lying zone of the cathode, the discharge path between this Area and the wall of the opening forms.

The assembly of the main and trigger line is used together with that of the pre-glow line held by means of wires and tabs that are connected to the electrodes and profile parts are. These pass through openings in the mica disks 3 and 4.

It should be noted that, while in the application examples described, electrons from the preparatory Auxiliary route can enter the space 10 and actually through the openings 13, 14 and 15 are beamed towards it, it itself can be set up in operation so that due to the voltage gradient between the electrodes 7 and 9 no electrons escape from the release path 9, since these electrodes are all charged particles that would otherwise diffuse past them.

In addition to their task of creating a very specific distance between the main electrodes, have the profile parts 21 together with the sheet metal 26 important tasks in the operation of the Tube. First and foremost, they serve to shield the main line from external electrical ones Fields and ensure that, apart from the charge parts coming from the release path 9

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otherwise nothing can get into the field of the main line. By applying a suitable Pre-tensioning assists the sheet metal 26 in particular in reducing the transmission tension to one Minimum value. The effect of the profile parts and the sheet metal is of the greatest importance in operation 26 for the deionization time of the tube. As already explained, must for the purpose of rapid deionization the positive ions in the path are accelerated to the cathode. If gives the profile parts and the sheet metal 26 as great a positive preload as is possible, without a discharge being maintained between them and the cathode or any other electrode can, it turns out that the resulting electrostatic field is a marked improvement in the deionization time of the tube.

A typical tube of the type described above is sized as follows:

Main line length 3 mm

Length of the release path 0.3 mm

Distance between the electrodes in the tempering section 0.25 mm

Opening 13 in the anode of the

Tempering distance 1 mm diameter

knife capacitance of the release compared to the cathode 1.6 pF

Capacity of the release with respect to the cathode and all other electrodes

less than 5 pF

The electrode system is housed in a standard miniature tubular flask (B 7 G), the with a mixture of 92% neon, 7% hydrogen and ι% argon at a pressure of 80 mm Mercury is filled. When using nickel electrodes, the voltages are as follows:

Ignition voltage of the main line .... 380 volts Continuous voltage of the main line 165 volts

The minimum current in the main line is 2 mA, and the tube is for discharge currents up to 15 mA in the main line connected to power sources rated for a maximum voltage of up to 360 volts. The constant pre-glow discharge can be limited to 0.5 mA.

The ignition and continuous voltage of the release path are nominally 160 and 150 volts, respectively. In the In practice, however, one finds it more expedient to require that at a specified fixed preload the trigger path and ignite under certain conditions. for anode voltage and Trigger pulse a transmission to the main line should take place. These operating limits are are touched again in connection with the circuit arrangement now to be described.

In the circuit of FIG. 4, the main anode 6 of the trigger tube 36 has a resistance of 5000 ohms connected to terminal 37 for 300 volts positive operating voltage. The cathode 7 of the The main line is connected to earth via a load resistance of 5000 ohms, which is connected to a capacitor of 1000 pF is parallel, and at an output terminal 3S. The trigger electrode 8 is via a External resistance of 1 megohm connected to a bias voltage tap +140 volts against earth and is also connected to a pulse input terminal 40 via a capacitor 39. Terminal 41, which is connected to the anode 6, allows extinguishing pulses to be applied to the main discharge path. In the continuously working pre-glow path, the cathode 12 is connected to earth and the anode 11 is connected to a resistor of 380,000 ohms connected to the power source terminal 37.

The profile parts 21 and the sheet metal 26 from FIG. 1 and FIG. 2 are represented by shield electrode 42, which is provided with a bias tap + 150 volts is connected to earth.

In the above circuit, a pulse of 24 volts amplitude applied to terminal 40 ignites the Tube within 1.25 μβεα Since no statistical If there is an ignition delay and the transmission time is negligible, then this period is thus the training delay of the release path. The training delay for the release route now changes by no more than 20% when the amplitude of the triggering pulse is depressed to a minimum (while lengthening the pulse width of the trigger pulse will).

The limitations of the operation of the release path given by the design are such that if the operating voltage at terminal 37 ¹ Qo is increased to 360 volts while the release is biased to 145 volts, a release pulse of 12 volts and a duration of 20 μβεΰ then covers the main path no longer triggers. If the voltage of the power source is reduced to 250 volts while * ° 5 the bias voltage of the trigger electrode is kept constant, the main section ignites with a trigger pulse of 24 volts amplitude and 20 μβεΰ duration. A very high input resistance can be achieved through the construction of the release path, no and in the circuit of Fig high mean input resistance H5 which results in a high peak current.

In order to extinguish the main line, a negative pulse with an amplitude of 170 volts is applied to the anode. This impulse brings the anode 25 \ ^r olt below the continuation potential of the discharge path. If the operating voltage is raised to 325 volts, a rectangular extinguishing pulse does not need to last longer than 30 μβεε in order to extinguish a discharge with the maximum current of 15 mA. With smaller currents, the full battery voltage can be reached after just one

Apply it to the tube again for a shorter period of time.

The tube described above is a universal trigger tube for high working speeds S has been designed, which has wide tolerances with regard to the operating voltage. For purposes of use, where either shorter deionization times or a lower minimum transfer voltage is required, a ίο cylindrical electrode system can be used for the main discharge path use.

An application example of the invention, which is built for low minimum transmission voltage, is shown in Figs. 5, 6 and 7 where the main is Section cathode 43 and anode 44 are concentric cylinders. The anode 44 sits on a rod 45, which is melted into the pressed glass base 46 of the piston, the remaining parts of which are not shown are. An inner metal band 47 connected to the anode provides support for one Mica insulator 48, which carries a metal tube 49, which is the anode of the preparatory auxiliary discharge path forms. The tube 49 is attached to the insulator 48 by means of riveted attachments 50 attached. A line 51 makes connection with the tube 49 via one of the extensions 50. An auxiliary cathode 52 sits in the driving seat between two mica insulators 53 inside the tube 49. A metal cylinder, which forms the trigger electrode 54, sits on the insulator 48 and is attached to it a line 55 led out through the base of the tube is welded on. The cathode 43 looks like an upturned cup, the cylindrical wall of which is the same diameter as the trigger electrode 54 has. The trigger electrode 54 and the cathode 43 are through three insulating washers 56, 57 and 58 aligned with one another, which are fastened to one another by an annular rivet, the washers 56 and 58 sit within the ends of the trigger electrode 54 and the cathode 43, respectively, while the Disk 57 has a larger diameter, is placed between them and thus keeps the two electrodes apart. The cathode 43 is attached at the top by a ring rivet to a mica insulator 59, the inside the anode 44 sits on a resilient collar 60, while extensions 61 are bent over on the anode are to keep the whole thing. One on the ring rivet securing the cathode to the insulator 59 welded line 62 is led out of the top of the tube.

In the application examples Fig. 5 to 7, the release path is through opposing parts the trigger electrode 54 and cathode 43 are formed by slots cut into the insulators 56 and 57 and are denoted by the digits 64 and 65, respectively. Part of the edge of the trigger electrode is cut away, leaving a tongue 165 which is bent over slightly to fit into the slot to protrude and to form the discharge surface of the release electrode. To the glow state on the The triggering and starting path can be better observed in the anode 44 opposite the triggering path cut a hole 66.

It can be seen that, apart from the opening at the triggering section, the starting auxiliary section completely shielded from the main line by the surrounding trigger electrode and the insulator 56 is. Therefore, as in the last embodiment, charged particles from a Continuous discharge at the pre-glow path prepare the trigger path electrically, but it is theirs not possible to get into the main section between the cathode 43 and anode 44. The operating conditions and properties of a tube such as that described with reference to Figures 5-7 may be similar to those of the tube of Figures 1-4 be, but the more favorable transmission voltage of the cylindrical design allows further limits for the operating voltage at the expense of the lower secondary ignition frequency due to the slower one Deionization that can be achieved with the cylindrical construction described.

Exactly the opposite considerations apply to what is now to be described with reference to FIGS. 8 to 10 Application example. Here, greater ignition frequency is at the expense of narrower limits reached for the permissible operating voltages. In this application example, the main path electrode is seated 86 within the cathode 67. The triggering path 68 is formed between the cylindrical parts Wall of the cathode 67 and a trigger electrode 69, which are bent from a metal strip is. The assembly of the pre-glow path 70 is offset from the axis of the tube so that it is closer comes to lie below the trigger path as if it were as in the application example described last would be built.

In building the tube system in Figures 8, 9 and 10, a hollow metal cylinder 71 is placed on a support rod 72 which is fused into a glass molding 73 which forms the base of the tube piston. An internally attached collar 74 carries a mica insulator 75 to which the assembly 70 of the pre-glow path is attached. The structure of the Vorglimmstrecke the same as in the application example FIGS. 5 to 7. Another metal collar 76 supports a mica insulator 7J, which is held in place by bent tabs 178 that protrude from the metal cylinder 71. The insulator JJ carries the release electrode 69 which is held in the middle by an annular rivet and to which a discharge line 78 is welded, the wire 78 being passed through an opening in the center of the insulator. The insulator JJ also carries the anode 166 which looks like an inverted cup and is attached to it by lugs which are inserted through slots in the insulator and then bent over as indicated at 79. The cathode 6j carries an inner collar 80 which forms a support for an insulator 81 which is clamped in place by the extensions 82. An opening in the center through which the anode lead extends is used to secure the anode with respect to the cathode, the cathode being held in place by its connection to the fixed rod 84 which passes through the pressing member 73

and melted down. An observation hole 85 allows observation of the cathode glow. As in the two application examples described above the main line is shielded from charged particles, which is from the starting line diffuse forth so that their effect on the trigger path 68 is limited.

While the principles of the invention are above in connection with specific examples of use and special varieties of it have been described. It should be emphasized, however, that this description has been given for the sake of example only and not a limitation as to intended to represent the scope of the invention.

Claims (20)

PATENT CLAIMS: I. Gas-filled glow discharge tube with cold cathode and at least three discharge ao stretch, namely a main discharge path, a control or release path and a pre-glow path, characterized in that, that the control or release path between the pre-glow path and the main discharge path is arranged so that the electrodes of the control or release path the main path against ionization products the discharge of the pre-glow path, while the discharge of the pre-glow path is sufficient to essentially cover the statistical delay time of the control or release path to eliminate. 2. Gas-filled glow discharge tube according to claim 1, characterized in that the Electrodes of the tripping section (auxiliary section) are arranged in relation to the main section are that when igniting the trigger path in the main path a discharge with negligible Transmission time arises when on the main line and load resistance existing main line circuit a voltage of such magnitude is applied that taking into account the load resistance caused by the main line current If there is a voltage drop on the main line, a voltage remains that is required to maintain it a discharge current in the main line is sufficient. 3. Gas-filled glow discharge tube according to claim 1, characterized in that the The main route is formed by an anode and a cathode parallel to the anode, and furthermore Another electrode (trigger or auxiliary electrode) is provided, which has a discharge surface has parallel to the above cathode and with the latter a trigger path in the space between Anode and cathode form the main line, and that this trigger electrode is shaped like this is that it forms a cladding which is shielded from the field of the anode, that furthermore the trigger path is at the edge of the enclosed space and that the electrodes the pre-glow path are shielded from the main discharge path so that there is only one way for the transmission of ionization products the pre-glow path is exposed in the enveloped space formed by the trigger electrode, thereby at least the charge particle in to bring the field of the release path and thus enable the ignition of the release path. 4. Gas-filled glow discharge tube according to claim 3, characterized in that the Discharge surfaces of the anode, the trigger electrode and the cathode are flat and the Anode on a plate made of insulating material and the cathode and trigger electrode an opposing second plate made of insulating material are arranged and the Trigger electrode is shaped such that it forms a container open on one side from which the second plate protrudes, and the cathode protrudes into this open container and the pre-glow path is behind the second plate made of insulating material, which is behind the part of the cathode protruding into the container is pierced to form a passage to allow the ionization products of the pre-glow path to the trigger path. 5. Gas-filled glow discharge tube according to claim 4, characterized in that the Distance between the edges and the adjoining bottom of the cathode and the second plate made of insulating material smaller than the length of the cathode case for a normal one There is a glow discharge on these surfaces. 6. Gas-filled glow discharge tube according to claim 4, characterized in that the Cathode made of a metal strip attached to the second plate made of insulating material consists on which a metal plate, the edges of which protrude beyond the metal strip, is appropriate. 7. Gas-filled glow discharge tube according to Claims 4 and 6, characterized in that that the end of the cathode plate protruding into the container which is open on one side is narrowed is. no 8. Gas-filled glow discharge tube according to claims 4 to 7, characterized in that that the opposite discharge surfaces at the opening edge of the container Trigger electrode and the narrowed cathode form the trigger path, which is essentially the length of the cathode drop for a normal glow discharge. 9. Gas-filled glow discharge tube according to claims 4 to 8, characterized marked iao net that the electrodes and brackets of the main and trigger path into one unified Component are designed in which the two plates made of insulating material to the corresponding Sides of a pair of rigid profile parts are attached. ίο. Gas-filled glow discharge tube according to claim 4 ,. characterized in that the Pre-glow path from a cathode plate and from an anode plate provided with openings consists, which is arranged at a distance from the cathode plate, which is less than the length of the cathode fall for a glow discharge between the two each other facing plate surfaces, so that the discharge between the opening walls of the Anode plate and the cathode plate runs. 11. Gas-filled glow discharge tube after Claim 10, characterized in that the cathode of the pre-glow path consists of a A metal strip attached to a plate made of insulating material and the anode from one apertured metal strip that is thicker than that of the cathode and consists of Anode strips on the same plate ao insulating material like the cathode at right angles to this is attached and the ends of the anode strip are bent back to the Separate the discharge area from that of the cathode by the required amount. 12. Gas-filled glow discharge tube according to claims 9 and 10, characterized in that that the assembly consisting of the main line and the release line and that of the Pre-glow path existing structural unit parallel to each other between a pair of mounting disks, which are supported on the cylindrical wall of the tube are installed. 13. Gas-filled glow discharge tube according to claim 9, characterized in that the Trigger electrode on the side opposite the main line anode with a Strip of insulating material is covered. 14. Gas-filled glow discharge tube according to Claims 9 and 13, characterized in that that the strip of insulating material with a conductive surface, which with the profile parts is connected, is provided. 15. Gas-filled glow discharge tube according to claim 1, characterized in that the Main route consisting of an outer cylindrical electrode as an anode and an inner one for Anode concentrically arranged cylindrical electrode as a cathode, which at the same time Is the cathode of the tripping path, which has a lower ignition voltage than the main path, and that the release electrode of the release path is formed by a cylinder, which has the same diameter as the cathode cylinder of the main line and below Inset of insulating disks arranged coaxially below the cathode cylinder is, and that a tongue is further cut into the cylindrical trigger electrode, which in a section of the insulating discs protrudes, so that the discharge attaching to this tongue the tripping path is spatially limited as a result, and the insulating washers together with the cylindrical trigger electrode a shell around a permanently discharging one Form pre-glow path, so that ionization products from this pre-glow path are prevented from penetrating the field between the anode and cathode of the main line, while the trigger path is prepared for ignition by the pre-glow path. 16. Gas-filled glow discharge tube according to claim 1, characterized in that the Main route from an outer cylindrical electrode as a cathode and an inner, to Cathode is concentrically arranged cylindrical electrode as an anode and that a trigger electrode between the cathode and the anode of the main line and on a pre-glow path is provided which is surrounded by a casing which is arranged in this way is that ionization products of the pre-glow path are prevented from entering the main path to get, however, through this envelope through into the space of the release path can penetrate. 17 · Gas-filled glow discharge tube according to claim 16, characterized in that the Enclosure consists of a cylindrical metal part, one end of which is supported by a disc made of insulating material, and the cathode and anode on the other side of the Seat while the trigger electrode consists of a metal strip that is placed on the Disc within the envelope with the exception of a bent piece of the strip sits, which protrudes through an opening into the space between the cathode and anode. 18. Gas-filled glow discharge tube according to claims 15 to 17, thereby 'marked * °° draws that the anode of the pre-glow path consists of a hollow metal tube and the cathode the pre-glow path consists of a metal strip which is inserted between strips of insulating material inside the anode tube i ° 5 is held. 19. Circuit arrangement with a tube according to claim 1, characterized in that a continuous discharge is maintained on the pre-glow path, while a second Route can be ignited from the outside, and by igniting the second route one third path is ignited, the electrodes of the second path and this path is so constructed even with respect to the first and third path that the ignition of the second Route the ignition potential of the third route is reduced, while the continuous discharge at the first distance can be set so that the statistical delay time during ignition the second path is as good as eliminated without the ignition voltage being caused by the first path the third route is reduced. 20. Circuit arrangement with a tube according to claims 9 and / or 14, characterized characterized that the purpose of the profile parts K »592V21 rapid deionization of the tube, a positive bias is applied. Considered publications: U.S. Patent Nos. 2,375,830, 2,404,920, 419,485 ,. 2,432,608; 2,443,407; Cios reports XXXI-50 in "German Cold Cathode Tubes" from Siemens Reiniger Werke, Rudolstadt, P. 12 ff. Older patents considered: German Patent No. 898489. For this purpose 2 sheets of drawings © 109592/21 5.61