DE917858C - Electric gas-filled discharge tubes - Google Patents

Description

Electric gas-filled discharge tube Addendum to patent 911874 The invention relates to gas-filled discharge tubes with several discharge paths in which a glow discharge is transmitted from path to path by the action of successive corresponding pulses.

A gas-filled cold cathode discharge tube was already included in the main patent described with separate cathode surfaces and one or more anodes, the one Arrangement of discharge paths with essentially the same glow discharge voltages and form current characteristics and are arranged so that a discharge, the at any line by applying a voltage pulse to all lines is effected, due to the ionization coupling between the routes such Condition creates that the next voltage pulse applied in the same way a Discharge in an adjacent path causes and further successive Voltage impulses each cause a discharge in the path that is currently being run unloading route is adjacent in the same direction.

In this tube designed according to the main patent, each following effective impulse ignited a further distance, whereby the glow discharge is maintained on the previously ignited routes of the facility (or, if temporarily extinguished, re-ignited). In this way the total discharge current flowing through the tube increases with the number of ignited Stretch on. With regard to the circuit, this type of actuation leads to difficulties and not only with regard to the large change in the total discharge current, but also because of the accumulation effect of ionization a number of simultaneous discharges tends to reduce the total ionization value in the discharge tube to a value that increases with a larger number of Stretching results in a reduction in the geometrical and circuit tolerances Has.

A more favorable type of actuation is that a single discharge, apart from a constant discharge, from route to route the tube is advanced in stages, with the addition of a subsequent Pulse ignited a new route and deleted the previously discharged route will.

The use of such a tube in which a single discharge Progress in parts has already been proposed. With this discharge tube are the individual discharge paths in three separate groups or sub-arrangements divided, of which every second route as a route of a storage arrangement is connected and the intermediate links as parts of a pair of transition link arrangements. The incoming impulses are alternately first one and then the other Transition line arrangement supplied. A single glow discharge in one the storage path is kept, can in this way to the next neighboring Storage section with the help of a temporary discharge in the intermediate transition section be transmitted. The transition sections must be arranged in alternating groups and the pulses are switched alternately from one group to the other in order to avoid that the discharge when a pulse is applied by one Move forward and return to its starting position when the next pulse is applied is moved back.

To eliminate the difficulty introduced by symmetrical ionization coupling a discharge path is caused to each side, was initially also a already proposed measure applied, according to which the cathodes of the storage electrode arrangement and, if desired, an intermediate junction electrode assembly specially shaped are, in such a way that the associated discharge paths are unidirectional Have ionization coupling. With tubes designed according to this measure the incoming pulses are common to all sections of the junction electrode arrangement supplied, and the discharge is from one storage section to the next transmitted along the array in one direction only. The difference between the ionization couplings in the forward and backward directions is due The special shape of the electrodes is large enough to allow unidirectional transmission secure the discharge.

Such tubes as described above are grounded here as being unidirectional Called cold cathode discharge tubes. To be clear between a temporary Discharge, for example a spark discharge, and the build-up of a glow discharge, which can be maintained to distinguish is said above and below, that a section is ignited if the discharge is within this section has built up a space charge to such an extent that the glow discharge maintained by continued application of a voltage between the electrodes which is equal to the operating voltage of this path. Sometimes it is common to speak briefly of the ignition of a cathode, which is ignited by the ignition of a another cathode was prepared. Of course, this is the cathode in each case associated anode-cathode path, meant, which is ignited in this way. Furthermore, of course, the discharge of this path, which is the ignition of the Anode-cathode section, which belongs to another cathode, has been prepared.

The subject of the present invention is a unidirectional one Cold cathode discharge tube with electrodes that form an arrangement of glow discharge paths form, which are arranged in pairs along a line such that the ionization coupling between the two stretches each of these pairs has great value, while the Ionization coupling between any two adjacent lines not of the same pair has a smaller value than that which is peculiar to the shape of the electrodes.

In such a tube the electrodes themselves can, as mentioned above, be undirected. When using directed electrodes in one according to the invention Tube becomes a much bigger difference between feed forward and feed back achieved. This significantly increases the switching tolerances.

In one embodiment of the invention is a unidirectional Cold cathode discharge tube with cathodes provided, which are in pairs in a Line are arranged. The distance between the cathodes of each of these pairs is small, the distance between adjacent cathodes of the same pair is not larger. If in this way each of these cathodes with the associated anode has a discharge path forms, the result is an arrangement in which two consecutive adjacent Alternately stretch a large and a small value of mutual ionization coupling exhibit.

In other embodiments of the invention, use can be made of the new knowledge of the relative proportions according to which photons, electrons and ions are involved in the ionization coupling. It must be noted that under ionization coupling the effect not only of the scattering of charged particles or photons from line to line is understood, but also the scattering of the electric field in one line as a result of the space charge in an adjacent discharge line. If one wanted to consider the last-mentioned form of coupling separately, one would have to designate it as field coupling. The ionization coupling is measured by reducing the ignition voltage of a path due to the presence of a discharge in an ignited path and can advantageously be given by the equation are marked in which $ the degree of ionization coupling, VBN and V ,, the normal ignition or. Burning voltage and VBr denote the actual ignition voltage, i.e. the ignition voltage that has been reduced by the effect of the ionization coupling.

If the field coupling is neglected, as has been determined, the proportions of photons, electrons and positive ions in the ionization coupling 60, 27.5 and 2.5 per cent, and it can be assumed that these relative proportions are largely independent of changes in the spatial arrangement of the electrodes, the material or the gas atmosphere used. It is therefore evident that a great deal of unidirectional coupling between pairs of adjacent lines by shielding the light of the glow discharge between the routes of a given Pair can be obtained.

Accordingly, another feature of the invention is unilateral Directional cold cathode discharge tube in front of cathodes that are in a line are arranged and with an associated anode an arrangement of discharge paths as well as with light screens between alternating pairs of these cathodes Reduction of the light from the cathode glow of one of the cathodes of each of these Pairs in such a way that the discharge path to which the other cathode of the pair belongs is irradiated.

The invention is described in more detail below with reference to the drawings will. In these drawings is shown in detail Fig. I a schematic circuit, the typical connections with a unidirectional follow-up discharge tube illustrates; Fig. 2 a somewhat idealized diagram of various such Tubes of occurring voltage current characteristics, Fig. 3 electrode arrangement in a unidirectional follow-up discharge tube according to the invention, Fig. q. another possibility of forming such an electrode arrangement, 5 shows a further electrode arrangement designed in accordance with the invention; this figure shows a section through that used in the tube of fig Electrode arrangement, the structural details can be seen, Fig. 6 perspective View of a unidirectional follow-up discharge tube according to the invention, whose dimensions, in particular the material thicknesses, are exaggerated in order to make the representation to make it clearer.

The follow-up discharge tube i in FIG. I has an anode 2 and an arrangement of cathodes 3, of which only the first few pairs and the last pair are shown. The cathodes, which need not be itself is not unidirectional in the present invention are constructed in two groups or sub-arrays, namely, an array of storage qa cathode, qb, qc ... qz and such intermediate cathode 5 a 5 ... y which are formed as a group of transition cathodes. Each of the storage cathodes q is connected to earth via an RC circuit 6 (resistor RA parallel to capacitance C). The anode 2 is connected to the positive voltage source HT via a series resistor Ra. The junction cathodes 5 are connected in parallel and connected to the pulse input terminal 7. The last cathode qz of the arrangement is still connected to the output terminal 8. At the beginning or for the purpose of reaching the starting position, the first storage cathode qa can be supplied with a negative bias voltage from the battery 9 by closing the switch io.

The positive voltage HT, the common anode resistance Ra and the cathode resistances RA are selected so that a constant current Ik occurs when any storage path is discharged.

The voltage current characteristic for any one of the discharge paths in tube i is shown in Figure 2 by curve A-B. The characteristic is somewhat idealized on the assumption that the voltage is constant over a greater part of the range remains at the voltage value of the route for normal discharge. Against that The voltage increases towards the end of B of the characteristic. This occurs as soon as the entire available cathode area is covered with the discharge. Then the discharge abnormal. At the other end A of the characteristic, the voltage rises sharply. if in this area the current without a very noticeable increase in the supplied Voltage is reduced, the number of ions formed is insufficient to maintain the space charge conditions of the glow discharge.

If the anode voltage is characterized by ha, the operating voltage by V '. "And the cathode current by Ik, then Va is given by ha = I% RA + V ..

(i) The cathode voltage Vk is shown in Fig. 2 by the solid line CD and the anode voltage by the line EF. If the necessary positive voltage HT is denoted by Vb, then one has Va = Vb - Ix Ra, (2) and the required value of T'b is given by Kb = Y. -1- I k (RA -f- R. ). (3) As a result of the discharge at a storage cathode, the ignition voltage of the other paths is reduced. The effect of the ionization coupling between one storage section and the next is shown in FIG. 2 by the curve GH, which represents the change in the ignition voltage of the storage section with the discharge current of the preceding storage section. At point P, the discharge current of the discharging storage path causes the anode voltage to rise along the curve EF up to its intersection with GH. When the storage current can increase that much, a second storage cathode will ignite. Then the ordinate PQ can be viewed as the upper current limit during the operation of the tube. The ionization coupling between a storage section and the adjacent transition section is usually dimensioned so that the ignition voltage of the transition section is reduced to its burning voltage value over at least part of the range of the discharge current in the storage section. The change in the ignition voltage at a transition section with the discharge current of the previous storage section is shown by the broken line KL for the discharge current below a given value, from which this curve converges with curve AB, i.e. the active characteristic of the discharging section, since iooo ( If a storage path is discharging and carries a current io, the ionization coupling between transition paths and storage paths is such that the ignition voltage VsaT of the storage path is given by the following equation: where ß indicates the steepness of the curve and I, the current corresponding to the intersection of AB.

It is assumed that the cathode 4b in Fig. I is discharging and that as a result of a negative pulse applied to the terminal 7, the junction electrode 5b is ignited and thus allows a constant discharge current it to flow through 5b. If i, is less than I k , then as a result of the voltage drop across the anode load R ", the current conducted through the cathode 4b suddenly falls to the value Ik-it and tends to increase exponentially to a new equilibrium value which is less than the original value, with the time constant iIR 'C, where R' = Ra RAI (R "-j-RA). The anode voltage falls exponentially with the same time constant to a smaller value it R '. Since the cathode current cannot become negative, the discharge cannot be sustained if the current is reduced to a value smaller than i "». Thus, the condition that the discharge is sustained in the cathode 4b is i k. - it ? im .. (5) It should be noted that the voltage between anode and cathode 4b does not drop below V ", if 1k > it, because RA is greater than R ' two types of actuation possible. With the first, the previously discharged storage cathode remains discharged with a lower current, with the second, the discharge at the storage cathode is extinguished. Let us first consider the case in which the storage cathode remains discharged. If the propagation of the ionization coupling of the discharge at cathode 4b is neglected, the change in the ignition voltage of the storage path assigned by the discharge at 5b prepared cathode 40 is shown by curve 11 i'V in FIG. The next control path will then ignite as soon as the voltage between anode 2 and cathode 4c, which is still at ground potential, is greater than or equal to the ignition voltage of this path. This condition can be expressed by the equation V7.4 b 222 JU (It - tt), where V k, 4 b is the instantaneous voltage of the cathode 4 b.

Allowing a certain delay in the ignition of 4c, during which the voltage at cathode 4b drops somewhat, the sum of this new value of cathode voltage and V; n is shown by the dashed line E'-F 'in FIG. 2, while, when V "" is added to both sides of equation (6), it can be seen that the effective point for igniting the cathode 4c on curve E'-F 'must be above the effective point on curve 19-1V. It should be noted, however, that the curve E'-F 'represents the current through the storage path and 111-N the current through the transition path . " drop, since this cathode is initially at ground potential and its resistance RA can be regarded as short-circuited by the capacitance C for a short time. The cathode 4b, however, is still positive to earth, so that the voltage between anode 2 and cathode 4 is less than the burning voltage of the path, so that it is extinguished. The voltage of the cathode 4b then falls exponentially with the time constant i (RA C. The value of the capacitance C is chosen so that the extent of the increase in voltage between anode 2 and cathode 4b is smaller than the extent of the increase during the duration of the transition pulse the ignition voltage for this section: At the end of the transition pulse, the discharge at the transition section is extinguished by removing the impulse drive voltage, and the discharge current at the cathode 4e increases exponentially to the value I ,;

In the event that the transition pulse current is sufficient to extinguish the discharge at cathode 4b, cathode 4c can still ignite and continue the discharge, since it is initially at ground potential. The discharge current of the cathode capacitor, if the path can be ignited, will be sufficient to ensure that the discharge continues during the transient pulse. The condition that the cathode 4c can ignite during the pulse is given by Ikz Rk> I4 (It - 2t) + Ra (zt-Ik) . (7) In FIG. 2, this condition can be expressed by the requirement that the operating point for the storage discharge on the curve EF should be above the corresponding operating point for the transient discharge on the curve MN; namely by an amount which is greater than the voltage Ra (i, - Ix).

If the transient current pulse is so large that the discharge at the Cathode 4 b goes out and the anode voltage falls to a value below the ignition voltage for cathode 4c, the anode at the end of the transition pulse tends to to rise to the voltage value HT. The voltage of the cathode 4b is still positive towards earth, but it has fallen to a value V '. Then the condition is that the cathode 4c ignites faster than 4b, so that it takes over the discharge, simply that the working point on the curve M-N is above the corresponding Point on curve C'-D '. In practice, this condition is always met, and it will always be the case that the next storage cathode opposite the previously discharging storage cathode is preferably ignited, provided it is not already conductive.

If you want to work with a small transition pulse current, you can as can be seen from the above, an ordinate R-S can be determined, which defines a lower limit of the actuation of the tube, such that the curve E-F is above the curve M-N by a given amount. From this, provided that the tube is within the area given by the ordinates R-S and P-Q is, works and further provided that the capacitance C is suitably chosen, to conclude that the transition of the discharge is unilateral in so far as it is assumed that the correct transition electrode is produced by a transition pulse is ignited. However, no reason has yet been given as to why the junction cathode 5 b compared to the cathode 5 a preferably ignites when the storage cathode 4b is in discharge.

In order to determine which of the transition cathodes 5 a and 5 b will ignite when a transition pulse is supplied during the discharge of 4 b, it is necessary to compare their relative ignition voltages. Obviously it is necessary that the ignition voltage of 5 b is smaller than that of 5 a. The ignition voltage curve 5 b is now shown by EL B when 4 b is discharged. It should be remembered that the mutual ionization coupling is the same for non-directional cathodes between adjacent pairs, ie the ignition voltage curve for 5b must be the same for a discharge of 4c as the ignition voltage curve for 4c for a discharge of 5b. The latter is represented by the curve MN. If it is assumed that the same characteristics exist between the same pairs of adjacent sections along the discharge arrangement, then the ignition voltage curve for 5a when 4b is discharged is also MN. Thus, as a sufficient condition for 5 b to be discharged sooner than 5 a, the requirement that curve MN lies above curve KZ B for all storage currents within the operating range of the tube. It can be seen that the amount between MN and the working part of the characteristic AB is lowest at the maximum working current. By separating adjacent cathodes at a distance that is smaller than the length of the cathode fall, 100% ionization coupling is now automatically achieved between these cathodes. It can therefore be set up in such a way that the curve KZ B coincides with the curve AB over the entire working range. It follows that the difference between curves MN and AB then gives a measure of the directional effect of the transition in the tube when, as is preferable, the difference between forward and reverse ionization coupling between one storage path and the adjacent transition path is maximized by ioo ° / o ionization coupling in the forward direction.

From this it can be seen that when using the circuit according to FIG that the coupling between the storage section and the preceding transition section should be smaller. The most direct way to achieve the required difference in the ionization coupling between a storage section and the transition sections on both sides of it is to use the basic principle that made the original construction of the follow-up discharge tube necessary, namely the drop in the ionization coupling as the distance between the affected ones increases and the influencing route. This results in a general electrode arrangement as shown schematically in Fig. 3 in which the discharge tube ii has an anode 12 and cathodes arranged in pairs, of which three pairs, 13, 14 and 15, are shown. The cathodes 16 a, 16 b and i6 c connected to the terminals K are storage cathodes, and the cathodes 17a, 17b and 17c connected to the terminals T are junction cathodes.

Assume that the discharge on a storage cathode is to be transferred from left to right along the array, as indicated by the arrow. Thus, the junction cathode 17 of each pair is closely adjacent to the storage cathode 16 of the same pair and is at a greater distance from adjacent cathodes not of the same pair, for example 17a and 16b. When using nickel electrodes in a gas atmosphere of 92% Ne, 1% A, 70 / r, H2 at 100 mm Hg, the distance between cathodes of the same pair should be about 0.25 mm and that between cathodes not of the same pair o.65 mm in order to achieve a maximum working range of the discharge currents.

In the observations of FIG. 2 it was shown that the upper limit the working current of the tube is given by the intersection of the anode voltage curve E-F and the neighboring ignition voltage curve G-H. From the point of view From the switching tolerances, it is evident that the section P is above the working curve A-B should lie by as large an amount as possible. This amount can be increased are made by using the maximum current in the tube by Increase in the anode resistance Ra, which increases the steepness of the curve E-F will. On the other hand, an increased amount can be obtained if possible is, the distance between the cathodes 16 in Fig. 3 without further enlarging the To increase the distance between a cathode and their junction cathodes on both sides. This can be achieved in that the junction cathodes in the direction of the arrangement can be made longer than the storage cathodes as shown in FIG is in which the storage cathodes with 18a, 18 b and 18 c and the junction cathodes are designated with iga, igb and igc, respectively. The junction cathodes are considerably longer than the storage cathodes.

To avoid an excessively large transient pulse current in this latter construction To avoid it, it may be desirable to use the effective areas of the junction cathodes to be limited by the fact that these are formed in strips, while the storage cathodes are plate-shaped. In this latter case, the operating voltage of the transition sections as a result of the faster ionization diffusion promoted by a thin cathode shape be higher than for a storage path, which, however, reduces the principles of operation are not influenced.

If only the difference in distance between adjacent cathode pairs above was considered, it should be noted that the geometric tolerances are more significant are than in other arrangements now to be described in which the steepness of the Ionization coupling distance curve is a maximum in the region under consideration. A further improvement in terms of the working tolerances of a tube with an arrangement according to Fig. 3 can be achieved that between alternating pairs of Stretch heater walls 2o are provided. These should be arranged so that the glow discharge on a storage cathode from the part of the anode which is immediately above the adjacent storage cathode cannot be seen. Such a radiator wall prevents the electrons from being released from the Electron cloud in the cathode dark space through the field of the anode of the other path to be pulled away. The heater walls can either consist of insulating material or preferably made of metal, so that they can be prestressed in a suitable manner can to keep the electrons away from the path, the discharge of which is not desired is.

In the partially sectioned view of part of the electrode arrangement (Fig.5) is shown an anode 2 1 with storage cathodes 22 and transition cathodes 23 cooperates. The storage and junction cathodes are the same Distance from each other. The distance between neighboring cathodes is smaller than the length of the cathode dark room. Between adjacent pairs of cathodes insulating screens ä4 are arranged, which partially cover these cathodes and point at the anode at a distance of the order of magnitude of the length of the cathode dark space. Then the cathode glow is applied to a cathode, e.g. B, 23b, from the neighboring one Cathode 22c shielded, but not from cathode 22b.

Because the cathode glow from the cathode surface of the neighboring Distance cannot be seen, the effect of photon coupling is negligible; while the screens have little influence on electron coupling. By this means, the ionization coupling between the storage cathode is established 22c and the junction cathode 23b are reduced to about 6o0, (0 while they are between 22c and 23c ioo ° JOig remains. In the arrangement according to Figure 5, the coupling between adjacent storage cathodes reduced by the walls 25 of insulating material, that of a disk made of insulating material 26, to which the anode 2i is also attached is to be held. The radiator walls 25 point in the direction of the cathode arrangement and lie between the screens 24. Their effectiveness depends on theirs Location between the direct path of the cathode glow of a storage cathode and the portion of the anode immediately above the adjacent storage cathode.

FIG. 6 shows the structural design of a tube using the electrode arrangement according to FIG. 5. The electrode arrangement 27 is arranged within a casing 28 which is provided with a glass base 29. It is carried by lines that are welded to the tube pins 30. The anode 21 consists of a metal strip; which is bent around the ends of a disk made of insulating material 31, as indicated at 32 and 33. The cathodes 22 and 23 are formed from metal strips which are clamped between an insulating disk 34 and a mask made of insulating material 35. The strips are perpendicular to the anode strips. In the mask 35 there are in a line parallel to the anode 21: right-angled slots, so that the discharge surfaces of the cathodes are left free.

The parts of the mask 35 that pass through the adjacent slits from each other are separated, represent the screens 24. The cathode strips are arranged so that each slot has a pair of cathodes with a screen 24 between adjacent ones Leaves couples free. The cathodes ?? show from one corner of the layer passing through the Disc 34, the mask 35 and the cathodes 23 is formed, to the other corner. the Radiator walls 25 are formed by bridge parts 36 which are perpendicular to the Washers 35, 36 and 31 are attached and serve to separate the anode from the cathode assembly to separate. The assembly is held together by pins 37 on the corners the insulating plates are riveted. It lies above a base plate 38 within of the glass bulb. The electrodes are connected to pins 30.

Claims (7)

PATENT CLAIMS: i. Cold cathode follower discharge tube according to patent 911 874 riding electrodes which form a number of glow discharge paths, characterized in that; that the discharge paths are arranged in a line in pairs in such a way that to achieve a one-sided directional effect of the discharge sequence or to increase an already existing directional effect, the ionization coupling between two paths of each pair has a large value, and between two adjacent paths not of the same pair but a smaller value than the one that corresponds to the shape of the electrodes. 2. Cold cathode tube according to claim i, characterized in that the distance between the cathodes of each pair is small, the distance between adjacent cathodes of the same pair is not greater, so that each cathode formed in this way with the associated anode has a discharge path forms an arrangement of which two immediately adjacent routes alternate have a large and a smaller value of mutual ionization coupling. 3. cold cathode tube according to claim 2, characterized in that the successive Cathodes alternate longer and shorter discharge surfaces along the line of this Have arrangement. q .. Cold cathode tube according to Claims 1 to 3, characterized by screens placed between alternate pairs of this cathode in such a way are that the cathode glow diminishes on one of the cathodes of this pair is illuminated while the discharge path of the other cathode of the same pair is illuminated will. 5. cold cathode tube according to one of the preceding claims, characterized by radiator walls made of insulating material or metal, which are placed between successive Pairs of the routes are arranged such that the ionization coupling between alternating routes is reduced without the ionization coupling between the significantly reduce adjacent stretches of the arrangement. 6. Cold cathode tube according to claims i to 5, characterized in that the cathodes are of a plurality are formed by metal strips that are in a plane parallel to each other and with are attached substantially equidistant, and that the anode is also strip-shaped and parallel to the plane of the cathode strip in such a way is attached that the anode and cathode strips are at right angles to each other. 7. cold cathode tube according to claim 6, characterized in that between Anode and cathode above the cathode a mask of a thickness that is about the length of the cathode dark room for normal glow discharge, is located from the about right-angled at the points of the discharge surfaces of the cathodes Slots are cut out so that the ridges between adjacent slots Form light-reducing screens. B. cold cathode tube according to claim 6 and 7, characterized characterized in that the ionization coupling reducing radiator walls of Strips of insulating material are formed that are perpendicular to the anode in one The distance from this is smaller than the anode-cathode path length. G. Cold cathode tube according to Claims 6 to 8, characterized in that the cathodes and anodes are attached to disks of insulating material and in a certain mutual position by a plurality of bridge-shaped parts on insulating material that effect both the anode and cathode support and at the same time serve as radiator walls. ok Cold cathode tube after any of the preceding claims, characterized in that the ionization coupling between adjacent stretches along the arrangement, ioo 0110 and less alternate than 60 ° / o of normal.