DE840621C - Electronic counter - Google Patents

Description

Electronic counter It is known how to put two vacuum tubes in a trigger circuit for a reciprocal, in 12eaction to commonly received connecting electrical impulses going on working, thereby causing a ll'ing of two tubes are formed; however, such circuits are for more than two tubes not suitable. This invention makes it possible to have more than two tubes in one endless To unite a chain of operations in which a completely new, from the previously known Different circuits is used.

The invention provides an electronic counter for counting electrical Pulses, which includes an odd number of vacuum electron tubes, of which each has an anode, a cathode and a control grid; the said tubes are connected in a ring so that one after the other, one at a time, in one predetermined, endless chain sequence in response to electrical, on they are made conductive together impulses transmitted, each impulse the conductive tube extinguishes and in the next tube in the sequence enables the ring to enter the conductive state; a network of electrical Resistors are provided to supply the tubes with anode and grid potential; with this network the anodes and grids are symmetrically connected; the said Network arrangement allows only one tube at a time to be conductive and has hot conductive state of a tube a potential distribution that occurs when the conductive Tube the two in order directly to the manager Tube adjacent tubes prepared to become conductive; Connections between When the tube goes out, choose between the tubes that of the two named adjacent tubes, which follows in the order for the conductive one State off, whereby they ensure that the tubes become conductive one after the other, that in response to the reception of pulses and in predetermined endless Chain sequence takes place.

Herein and in the claims below where the term trigger is used, this expresses that in a tube the grid with respect to the Cathode is provided with a potential of such a value that this becomes conductive the tube allowed. In trigger-connected tubular hair and trigger circuits the tubes are coupled in pairs so that when one tube of the pair is in conductive state that other necessarily does not conduct while the mode of operation or the mode of operation of the pair of triggers, which of the two tubes is currently in a conductive or non-conductive state, by electrical Impulses changes.

The meter according to the invention has a network arrangement, to provide the grid of the tubes with a control potential in such a way, that when one tube is conductive, the grids of the other tubes are sufficient negative potential obtained in order to prevent the conduction of said other tubes. Only the grids of those two tubes that are in the order immediately are adjacent to a conductive tube with respect to their anode connections with a lower control potential than the grids of the other non-conductive tubes, if present, provided: further means are provided which the anode of each Couple the tube with the grids of the two adjoining tubes mentioned so that at Onset of the conductive state in a tube on a negative potential pulse the grid of those of said adjacent tubes which in the order preceding the tube is transmitted, while when the conduction ceases in the tube transmit a positive potential pulse to the grid of the other adjacent tube will.

In the embodiment of the invention described hereinafter in its details are described with reference to the drawing, is any Tube of the ring intended to stand for two possible items of an indication; further a pulse dividing means is provided, which the received pulses through divides two and one pulse for every two of the pulses received by the sub-means transfers to the counting ring. The state of conduction of a tube in the counting ring means the registration of an indication, and one must at the conductive tube and consider the pulse division means which of the two possible indication items through the conductive state of a particular tube is shown. It is clear that the tubes of the counting ring after switching off the partial means of the counting ring too can be used to display individual disclosure items.

In the ring described here five tubes are provided, one of which every two consecutive digits in a series of digits in the decimal number system represents. A tube can e.g. For example: 8 and 9 or 9 and o, o and i or i and 2, depending on whether o or i is considered to be the starting point of the ring. If one tube represents the digits o and i, so represents the next tube of the ring the numerals 2 and 3. The conduction status in a tube indicates that one of the registered with the two digits it represents. The state of the part mean determines which one of the two possible states prevails of the two digits is registered.

It is emphasized that it is essential and basic principle of the invention is a circuit arrangement for a number of more than two high vacuum electron tubes in which to create a given Time only one tube can be conductive, in which furthermore the tubes, and that in each case one, in order and in response to each of the electrical received in common Potential pulses can be made conductive.

The exemplary embodiment chosen to illustrate the invention relates to the counting or adding of numerical data in which the decimal system is used. It is clear, however, that the principle of the invention goes far beyond the number of tubes used in this disclosure and the designation given to them, as well as the idea of using one tube of the ring to represent two digits, since the invention is suitable for many uses as will become apparent from the following description given with reference to the drawing. The drawing shows a typical circuit arrangement in which the pulse dividing means, the counting ring with five tubes and a display means for translating the display status of the tubes into the decimal number system are shown. General description A source of sine wave pulses is provided as the source for the electrical pulses to be counted, which is indicated in the usual way and connected to poles 20 and 21. All specified potentials are related to earth potential. The cathode heating is shown in the usual way. Po12i is grounded. Pole 2o is connected to the control grid 23 of the vacuum amplifier tube 24 (e.g. an American pentode type 1852, which has a grounded cathode 28) through capacitor 22. The grid is provided with control potential far beyond the cut-off point in that it is connected through resistor 25 of 50,000 ohms to the potential dividing resistor 26, which is connected between earth and conductor 27, which is provided with a negative potential of igo volts. The anode 30 is connected by point 31 and resistor 32 of 25,000 ohms to conductor 33, to which a potential of 120 volts is brought positive. The screen grid 34 is coupled to ground by a 4 microfarad capacitor 35 and connected to the 120 volt positive conductor 33 by a resistor 36 of 50,000 ohms. The braking grid 37 is grounded. Under these conditions the potential of point 3 will decrease due to resistor 32 every time a sine wave in excess of 15 volts is transmitted to poles 20 and 21 as tube 24 is rendered conductive during part of the positive half of the sine wave.

The negative potential pulses brought to point 31, each of which represents a sine wave, are fed through the capacitors 38 and 39 of 10 microfarads each to the control grids 40 and 41 of the vacuum tubes T i and T 2, respectively. The aforementioned IZihren are pentode amplifiers, which can be of the American type 18,52, and are arranged in a trigger circuit by coupling the anode of each tube to the control grid of the other tube of the pair. Upon receipt of a jointly received negative potential pulse on the control grids 40 and 41, the tubes will continuously assume a working mode in which one or the other of the tubes is conductive. The aforementioned continuous mode of operation follows the reception of the pulse which causes the conductive state in the conductive tube to cease; this cessation in turn brings about the beginning of the conductive state in the other cell, whereby, owing to the nature of the coupling circuit, it is impossible for both cells to be conductive at the same time. The cathodes 42 and 43 of the tubes T i respectively. T2 are grounded through their connection to conductor 29; the same is the case with the brake grids 44 and 45. The anodes 48 and 49 of the tubes T i and T 2 are connected to the 120 volt positive conductor 33 by resistors 46 and 47, respectively, of 5000 ohms each. The screen grids t 55 and 156 of the tubes T i and T2, respectively, are connected to the 120 volt positive conductor 33. The anode 48 of the tube T i is coupled to the grid 41 of the tube T2 by a resistor 5o of 50,000 ohms and a capacitor 5i of 50 micro-microfarads in parallel therewith. The grid 41 is connected to the 180 volt negative conductor 27 through resistor 52 of 50,000 ohms. Similarly, the anode _a9 of the tube T2 is connected to the grid 4o of the tube Ti through a resistor 53 of 50,000 ohms and a capacitor 54 of 50 micro-microfarads in parallel therewith. Grid 40 is connected to negative conductor 27 igo volt through resistor 55 of 50,000 ohms. Under these conditions, the conductive tube of tubes T i and T 2 becomes with each negative pulse. which is transmitted jointly to the grids 4o and 41, non-conductive. The subsequent increase in potential of the anode is transmitted to the grid of the other tube of the pair and puts it into a conductive state. Trigger tube circuits of this type are known and comprise a vacuum electron tube ring of two tubes. The one in the anode of one of the two tubes T i or T 2 at The negative potential impulse caused by the beginning of their conductive state is transmitted to the grid of the other tube of the pair and keeps this at a point which is more negative than the critical point, which is 20 volts for the tube type used, until the function of the tubes is changed.

From the point 157 connected to the anode 49 of the tube T2, the change in potential caused by the resistor 47 when the conductive state of the tube T2 ceases is transmitted through the capacitor 56 of 10 micro-microfarads to the control grid 57 of the pentode amplifier 58, which is of the American type 6AG7 can be transmitted, the entire grid being connected to the i8o volt negative conductor 27 through resistor 59 of 50,000 ohms, normally beyond the critical point of 30 volts with a negative control potential. Cathode 6o is connected to 180 volt negative conductor 27 through 25,000 ohm resistor 61 and coupled to point 262 through 4 microfarad capacitor 6a. Screen grid 63 is connected to 120 volt positive conductor 33 through resistor 64 of 3750 ohms and grounded through capacitor 65 of 4 microfarads. Anode 66 is connected to the i2o volt positive conductor 33 through resistor 67 of sooo ohms. Braking grid 68 is connected to the cathode.

In the aforementioned connections, tube 58 acts as an overdrive potential provided amplifier applied to each positive transmitted by capacitor 56 Impulse responds by guiding. It therefore reacts to two each on poles 21 and 22 sine wave pulses transmitted in tube T2 when the conductive state ceases once and in this way forms a mean which the input sine wave pulses divides by two. As a result of the resistor 67 in the supply conductor for anode 66 at point 69, each time tube 58 begins to conduct, a drop in potential occurs a. The drop in potential at point 69 causes each time tube T2 stops conducting, a violent negative impulse is transmitted on conductor 70.

Tube T i can be made conductive by earthing its grid 40, and in fact the earthing takes place in such a way that switch 71 is temporarily opened and then closed. Thus, if tube T i is rendered conductive in this manner, then when the first sine wave input pulse is transmitted to poles 20 and 21, tube T i will be rendered non-conductive and tube T2 will begin to conduct. Upon transmission of the sine wave input pulse on poles 20 and 21, tube T2 is rendered non-conductive, tube T i begins to conduct, and a violent negative pulse is transmitted on conductor 70.

The tubes 1, 2, 3, 4 and 5 are high vacuum electron tubes of high mutual conductance, each of which has an anode, a cathode, has a control grid, a screen grid and an electrode that connects to the cathode is connected to effectively direct the flow of electrons to the anode. The American Tube type 6Y6G is for use in this case, namely in the exemplary embodiment sufficiently suitable for the invention set out here; it is clear, however, that the Special features do not form a fundamental part of the invention that furthermore the Range of the invention by the type of tube, by the screen grid, by the electron-directing cathodes or by the individual in connection with the tubes used values for resistance and capacitance is not limited as the work essentially through a triode vacuum electron tube with an anode, a cathode and a control grid can be executed.

Cathodes 72, 73, 74, 75 and 76 are connected to ground conductor 29 and screen grids 77, 78, 79, 80 and 81 are connected to conductor 82, to which a positive potential of 30 volts is applied.

The 4 microfarad capacitor 83 couples ground conductor 29 and the Screen grid supply conductor 82.

Each of the anodes 84, 85, 86, 87 and 88 is connected to a 290 volt positive supply conductor 94 through a 25,000 ohm resistor numbered 89, 90, 91, 92 and 93, respectively. The anodes are connected to one another in an endless row by conductors 95, with a resistance of 25,000 ohms in conductor 95 between each two adjacent anodes in the row. In this way resistor 96 connects anode 84 of tube i to anode 85 of tube 2; Resistor 97 connects anode 85 of tube 2 to anode 86 of tube 3; Resistor 98 connects anode 86 of tube 3 to anode 87 of tube 4; Resistor 99 connects anode 87 of tube 4 to anode 88 of tube 5, and resistor ioo connects anode 88 of tube 5 to anode 84 of tube i. There is a pair of resistors, each connecting two adjacent anodes and forming part of the resistor network; each of the resistors has a value of ioo, ooo ohms; Resistors io6 and 107 connect the anodes of tubes i and 2, resistors io8 and `log connect the anodes of tubes 2 and 3, resistors i io and iii connect the anodes of tubes 3 and 4, resistors 112 and 113 connect the anodes of the tubes 4 and 5 and resistors 114 and 115 connect tubes 5 and i. From the connection point of each of the last-mentioned pairs of resistors, namely points 215, 116, 117, 118 and i i9, a connection goes through a resistor of 100,000 ohms, similar to resistors 120, 121, 122, 123 and 124 to a supply conductor 125 for negative potential of 320 volts. By connecting the anodes of the tubes 1, 2, 3, 4 and 5 in a symmetrical resistor network arranged in such an endless chain, which consists of a ring of resistor loops, a state is created at the potentials specified for the supply conductor and when the labeled tubes are used which, when one of the tubes in rows 1, 2, 3, 4 and 5 is conductive, gives certain potentials of correspondence to the connection point to the anode of the conductive tube as a result of the current flowing through the conductive tube. Since the network formed by the resistors is symmetrical and the anodes of the tubes i, = 3, 4 and 5 are connected to the network at points ioi, io2, 103, io4 and 105, respectively, in a symmetrical form, the pattern of potential variations is in that Network ring arranged regularly but in steps around the ring in an order corresponding to the order in which the tubes become conductive in response to the reception of pulses, as will be explained.

In the network ring of resistances, points such as the points ioi, 102, 103, 104 and io5, if none of the tubes is in a conductive state, have a positive potential of about 247 volts. One such possibility does not exist in the circuit shown, except for brief moments, because, due to the use of specially selected relative potentials, there is always a tube will be conductive, namely a tube will be conductive, since it has a tendency to be conductive State because it is of an absolutely perfect state in this respect differs more than the other tubes.

If potentials are applied to the supply conductors, and if one of the tubes becomes conductive before the other, the potentials of points ioi, 102, 103, 104 and 105 are restored as a result of the flow of a current through the tube. Assuming that tube 3 conducts, which can be achieved by temporarily closing switch 126, whereby grid 127 is grounded, the potential of point 103 and the anode 86 of tube 3, as the internal potential drop, when the individual working potentials are applied to the supply conductors on a 6Y6G will be about 7 volts, about 7 volts positive with respect to the grounded cathode 74. The potential of points iö2 and 104, which represent anodes 85 and 87 of tubes 2 and 4, respectively, becomes about 122 volts positive and the potential of points ioi and io5, which represent anodes 84 and 88 of tubes i and 5, respectively, will be about 16o volts positive. Under these conditions, the point i, connected to grid 127 of tube 3, assumes earth potential with the aid of conductors 128 and 129 and brings tube 3 into a highly conductive state. At the same time, the potential of the control grid of tube i has the same value as point 117, since this is connected to it by conductors 263 and 264; this point is negative 60 volts with respect to earth; the grid of tube 2 has the same potential as point 118, namely 14 volts negative with respect to earth, since this is connected to it through conductors 265 and 266; the grid of tube 4 has the same potential as point 215 since it is connected to it by conductors 267 and 268, namely point 2i5 is 14 volts negative with respect to earth; the grid of tube 5 ultimately has the same potential as point 116, being connected to it by conductors 269 and 270 , point 116 being 60 volts negative. Therefore, the grids of the two tubes adjoining the conductive tube in either direction, both tubes, are closer to the critical point, which is about 10 volts negative, than the grids of the tubes further away in the order.

As has been explained, each time tube 58 is conductive, input conductor 70 carries a negative potential pulse, which is passed through capacitors 130, 131, 132, 133 and 134, each of which has a capacitance of 50 micro-microfarads, onto the grids of all tubes i, 2, 3, 4 and 5 is transmitted simultaneously. The weakened negative input pulses transmitted to the control grids are approximately 20 volts. A negative pulse transmitted to conductor 70 when tube 3 is conductive will render tube 3 non-conductive; the subsequent positive potential wave at point 103 is transferred to capacitors 13.5 and 136, each with a capacity of 50 micro-microfarads. The positive potential wave cannot cause any conduction between the anode 139 and the cathode 137 of the double diode rectifier tube 40, which can be of the 6I16 type, since it does not have the correct polarity; the potential wave is further weakened when passing through resistor 138 of i megolim, so that the positive potential impulse which it brings to grid 141 of tube 2, which is connected to resistor 138, is not sufficient to conduct the RJlire 2 to cause.

The positive potential wave through capacitor 136 is on anode 142 transmitted and causes a positive potential wave due to the resistor 120 in point 143 from 40 volts; this wave causes the grid 145 of the tube 4 to become more positive as the critical point and thereby causes tube 4 to become conductive. If tube 4 becomes conductive, point io4 has a negative direction, i. H. of 122 volts positive to 7 volts negative, tending potential wave. This negative wave is going on the capacitors 146 and 147 transfer and causes between cathode 148 and Anode 149 conduction takes place; which in turn causes a strong negative Potential pulse is transmitted to grid 127 of the tube 3, which in her a new Line as a result of the change in potential at point 102, namely from 122 volts positive to 16o volts positive, which on the grid 127 by means of the connected rectifier tube is prevented. In this way the potential waves are in the anodes of tubes i, 2, 3, 4 and 5 in connection with the rectifiers are used to cause the sequential work to only go in one direction takes place.

With the next pulse on tubes i, 2, 3, 4 and 5 the tube 4 put in a non-conductive state and the tube 5 in a conductive state. After the tube 5 the tube i is made to conduct. This is going to happen in endless order go, whereby the endless chain of tubes has the ability to with the listed Resistance and capacitor values, tube types and potentials 12 500 pulses per second and react precisely to them.

This means that poles 2o and 21 can be fed 25,000 potential pulses per second; the state of the tubes T i and T2 in connection with the state of the tubes i, 2, 3, 4 and 5 can still be checked at a frequency of 25,000 per second with respect to whether the number of pulses received is accurate to within ten reproduces.

It will be understood that another ring of tubes i, 2, 3, 4 and 5 can be operated in conjunction with a further pulse divider similar to tubes T i and T2 which each time the ring shown in the drawing completes a sequence cycle to move up one level in the order. Since the tubes of a trigger circuit, such as tubes T i and T2, have to be supplied with a negative electrical potential pulse for a work stage, a negative pulse is transmitted to a conductor connected to point ioi every time tube i begins to conduct; Such a negative pulse, if it is in connection with a point corresponding to point 31 , can be used to set a further ring in motion. With the listed second ring, further rings can be connected, whereby one obtains a multi-digit row system with any number of rows of digits. As many rings can be used in series as are necessary to achieve the particular purpose with which the system is to be adapted.

The means for checking the condition of the dividing tubes T i and T 2 and the tubes of the counting ring i, 2, 3, 4 and 5 comprises a resistor network for each tube of the counting ring; one part of each resistor network is connected to the anode of the tube T i, the other part of each resistor network to the anode of the tube T2; the middle part of each of the resistance networks is under the influence of the anode potential of the connected tubes of the counting ring. Point 150 with the potential of the anode 84 of tube i is connected by resistor 151 of i 500,000 ohms, point 154 and resistor 152 of 500,000 ohms to conductor 153, which is connected to point 170. Point 150 also communicates with conductor 178 connected to point 175 through resistor 155 of 1,500,000 ohms, point 156 and resistor 158 of 500,000 ohms. Each of points 159, 160, 161 and 162 are connected to conductors 153 and 178 in the same manner as explained at point 150. A conductor 163 leads from radio 154 to an i-contact 164 of a selector switch 165; From point 1,56 a conductor 166 leads to a 2-Koritakt 167 of the selector switch 165. Point 170 is connected through resistor 171 of 85o,000 ohms to a 400 volt negative pole 172 and through resistor 173 of 500,000 ohms to point 174, which has the same potential as anode 48 of tube T1; Conductor 178 is connected to point 175 which is connected through resistor 176 of 85o,000 olim to a pole of 400 volts negative potential and through resistor 177 of 500,000 olim to point 157 which has the potential of anode 49 of tube T2.

If tube 1 is conducting, the potential of its anode 84 is 7 volts positive, if it does not conduct, this potential becomes 122 or 16o volts positive be. If tube T i conducts when tube i is conducting, and therefore that Potential in anode 84 is about 7 volts positive, then point 15.4 and contact 164 are under a negative potential of about 17 volts. If tube T i does not conduct, then its anode is about 90 volts positive, and point 154 becomes a potential of 2 Volts are positive while point 156 is because tube T2 is conducting and its anode sets positive to 23 volts, will have a 17 volt negative potential. Would the potential at point 15o has a positive amount of 122 or 16o volts, which would be the case if tube i did not conduct and tube T i would conduct, then would points 154 and 156 are under a positive potential of 12 and 21 volts, respectively. As a result, the most negative contact of the two contacts is i or 2 on selector switch 165 represents the registered number. The same in the negative direction Moving potential changes will be reflected on the other contacts of the selector switch result if the connected annular tube is in a conductive state. If the sensing contacts of the selector switch are identified by digits in the specified type switch 71 is temporarily closed and then opened to To bring tube T i into the conductive state; then tube i is referenced in the on tube 3 described type, in which your grid by closing a switch, like switch 126, earthed, made conductive, whereupon the device register i will.

Vacuum tube 168 with a grounded anode is of the same type as tube i, the critical grid potential of which is to volts. As a result, if feeler arm 169 is caused to slide over selector switch 165 by means of the friction drive 271 which moves the axis 1171 (indicated by the dashed lines), the line in tube 168 will be interrupted if contact with such a critical potential or one more negative potential than the critical potential is sensed, whereby the electromagnet 19o, which is normally energized by the conductive state of the tube 168, the energy is withdrawn. This allows the spring 18o to move the pawl 181, causing the feeler arm 169, indicator wheel 182 and axle 1171 to which the wheel and feeler are attached to stop against the action of the RelbantrlebeS 271. Since the indicator wheel 182 is in the position corresponding to the position of the sensor, it not only shows which of the tubes i, 2, 3, 4 and 5 is in the conductive state, but also which of the tubes T i and T 2 in this time heads. The change in potential of the contacts of the selector switch, such as contact 164, when they are no longer sufficiently negative, causes a conduction state to be established in tube 168, whereby pawl 181 is retracted, and causes arm 169 to make another contact with looking for the right negative potential; no contact has the correct potential until the two tubes connected to it all conduct.

By transmitting any number up to ten sine waves to poles 20 and 21, it is possible to operate tubes 1, 2, 3, 4 and 5 differentially in conjunction with tubes T i and T2 to determine the exact number of received 'sine waves to count and display. The '' skins can be transferred to the poles at regular or irregular intervals and up to frequencies of 25,000 per second. It has also been described how matt a multi-digit, high vacuum tubes comprehensive counting device builds up in order to be able to carry out information additions on a larger scale.

Although the circuit shown is intended for operation by the application of sine waves, it is perfectly clear that the use of any other means to activate tube 24 or to transmit the appropriate potential impulses to point 157 or conductor 7o, in belongs to the scope of the invention; and it must also be noted that the tube type used, the specific potential values and the values for the used circuit elements or the given pulse splitting means, in 'view of the Hochvakutimröhrenzählring, no limitations, but merely a practical embodiment of the invention represent. These and other embodiments which contain more or fewer tubes in the ring belong within the scope of the invention, as is indicated in the following claims.

Claims (4)

PATENT CLAIMS: i. Electronic meter with an odd number of vacuum electron tubes, one of which is made conductive in succession in a continuous cycle in response to input pulses emitted jointly via an input pulse conductor and via individual capacitors to the control electrodes of all tubes, the anodes of the IZ <ilirell connected via individual resistors to a positive potential divider connection (e.g. 13, 106, 107) between the anode (e.g. 84) of each tube and the anodes (e.g. 85, 88) of the adjacent tubes, a connection between the midpoint (e.g. 215) of each voltage divider with the most distant tube arranged in the ring, a connection between the control electrodes (e.g. 13.t45) of the tubes and a negative potential source via individual resistors (e.g. 13.t20) and a capacitive coupling (e.g. 13. 136) between the anode (e.g. 86) of each tube and the control element ktrode (e.g. B. 145) of the next tube in the lZing. 2. Counter according to claim t, characterized characterized in that the connection between the anode of each 1Z tube and four control electrodes the following IZölire a rectifier oriented towards the control electrode (142, has. 143) 3. Z "liler according to _ \ nspruch 1, characterized. That the Anode (z. 13.86) of each tube through a capacitor (135) in series with a against the rectifier (t37, 139) oriented to \ node, with the control electrode (e.g. 13. 141) of the preceding tube is connected, the anode voltage being capacitive is derived on the control electrode of the preceding stirrer. 4. A meter according to claim 1, 2 or 3, comprising two further vacuum tubes, of which the anode of each tube is connected to the control electrode of the other of the two tubes, whereby the tubes conduct alternately in response to successive pulses delivered thereon, and one Connection between the anode of one of the two tubes and the pulse input conductor, whereby an input pulse is emitted on the input conductor upon receipt of two signal pulses, characterized by two potential dividers (46, 173, 171 and 47, 177, i76) parallel between positive and negative Voltage poles are connected, the anodes (e.g. 48) of the two adjacent tubes are each connected to corresponding points (e.g. 174) of the two potential dividers, and by resistors (e.g. 152, 151 and 158, 155 ) between further corresponding locations (17o, 175) of the potential divider and the anode (e.g. 84) of each of the tubes of the counting ring, with corresponding locations (e.g. 154, 156) at -d en resistors with the contacts (e.g. B. 164, 167) of a switch are connected, whereby the conduction in one of the tubes (z. B. 1) of the counter ring causes a drop in the potential of the two associated contacts (164, 167) and the potential of one of these contacts (z. B. 164) dunch Idas conduction in the associated tube (TI) of the two other tubes is reduced even more.