DE933043C - Gas-filled discharge tubes for storing and counting - Google Patents

Description

Gas-Filled Discharge Tube for Storing and Counting It is known to use gas discharge tubes for counting and storing in calculating machines and the like. It is also known to provide tubes with several cathodes and a common anode, in which the glow discharge can be reversed from one cathode, the so-called point cathode, to the next, so that the respective existing glow discharge represents a stored value. A disadvantage of this known arrangement is that only positive values can be stored or additions can be carried out, while negative values can only be treated with special switching measures. The invention relates to a storage arrangement with a gas-filled discharge tube, in which, in addition to the positive values, negative values can also be processed. In particular, the invention is of importance in calculating machines controlled by recording media. According to the invention, a forwarding cathode is provided between the position cathodes arranged at approximately the same distance from one another along a closed glow discharge path, and each position cathode is also assigned a holding cathode. Each holding cathode is assigned to a position cathode in such a way that a glow discharge can migrate from each position cathode to its associated holding cathode and vice versa. The forwarding from one position cathode to the next position cathode takes place via the forwarding cathode assigned to the position cathode in the glow light path. The position of the glow discharge represents the value stored in the tube. The glow discharge is forwarded by controlling the cathode potentials, and additional glow light transmission means are provided to facilitate the forwarding.

These consist e.g. B. from lines, each of which has one end the cathode to which the discharge is to be transferred is firmly connected and the other free end in the area of strong ionization of the currently existing Glow discharge protrudes. The invention will be explained in more detail with reference to the figures.

Fig. I illustrates an embodiment of the invention; Fig. 2 is a timing diagram; FIG. 3 shows an arrangement for generating that shown in FIG Impulses.

The invention is based on a gas-filled glow discharge counter tube off, the ten digit cathodes, ten glow light transmission cathodes and one all Cathode contains common anode. A forwarding cathode is between two consecutive digit cathodes. The twenty cathodes together form a closed glow light transmission ring. Everyone in the company causes that Forward cathode fed negative impulse a transmission of the glow discharge from one place cathode to the one next to it, representing the next higher digit Site cathode. In this way the glow discharge travels through the forwarding cathodes supplied negative pulses along the closed glow light transmission ring from cathode to cathode. This gradual forwarding of the discharge is Insensitive to current and voltage fluctuations of the negative pulse value. An additional cathode is also provided for each position cathode. These Additional cathodes are called holding cathodes because they control the glow discharge during the application of non-countable time pulses compared to a specific one Hold the digit cathode firmly. All cathodes are designed as hollow cylinders and coated with a suitable material so that the glow discharges on the Inner cylinder surfaces are limited. Furthermore, glow light over-. transmission lines provided between these holding cathodes and the associated position cathode, so that an existing glow discharge from this point cathode to the holding cathode and can be transmitted vice versa. All holding cathodes are with each other and with one Voltage source connected. If negative values are to be stored in the tube, the holding cathodes are energized, and the glow discharge is from a spot cathode transferred to the holding cathode assigned to it. After a certain time will be the holding cathodes are re-energized and the glow discharge becomes the site cathode transferred from which it was previously transferred to the holding cathode. After that effected every negative pulse applied to the forwarding cathodes is a step-wise progressive one Glow transmission. As a result, negative values are considered to be their nines' complements inserted into the tube.

In Fig. I the counting and storage tube zo is shown according to the invention. This embodiment has a storage capacity of ten digits, namely o b-is 9. The position cathodes Cp-o to Cp-9 are each with the corresponding Reference number denotes. The forwarding cathodes C-o to C-9 are between two consecutive site cathodes. The cathode C-9 is located between the Position cathodes Cp-9 and Cp-o. All site cathodes are with the common clamp i i connected to which a positive DC voltage is applied. All forwarding cathodes are connected to the common input terminal z2, the one at regular intervals negative time pulses are fed. From the later description it follows that the actual selection of the impulses to be stored by the location of the glow discharge is set in the tube.

Assuming that a glow discharge takes place between the position cathode Cp-o and the anode (not shown) and a negative pulse is fed to terminal 12, the negative pulse front increases the voltage difference between the common anode and the forwarding cathodes until it is greater than that between the Anode and the site cathode is Cp-o. As a result, the glow discharge reaches the relay cathode Co via the line ZWO, which is connected to the relay cathode C-or at the other end, and now exists between this relay cathode and the anode until the negative pulse voltage goes in the positive direction turns over. This voltage then causes the voltage difference between the site cathodes and the anode to be greater than that between the relay cathode Co and the anode. As a result, the glow discharge is transferred from the cathode Co to the position cathode Cp-i via the line L i connected at the other end to the position cathode Cp-i. The glow discharge remains in a stable equilibrium between the position cathode Cp-i and the anode until a further pulse is applied to the tube, which changes the voltage ratios in such a way that the glow discharge is passed on. each subsequent negative pulse fed to terminal 12 causes the glow discharge to be passed on in the same way to the digit cathode representing the next higher digit. Finally, the tenth such pulse causes the glow discharge to be passed on from the position cathode Cp-9 to the position cathode Cp-o, as a result of which the glow discharge has again reached its starting position. Instead of the lines L, LH, LS and LW , other known means can also be used to define a specific starting position for the glow discharge and to continue the glow discharge from one position cathode to the next.

The holding cathodes Cs-o to Cs-g are provided for the introduction of digits with negative signs in the form of their nine's complements. Each of these cathodes is connected by glow light transmission means to the position cathode, which has the same reference number. The lines LH are connected at their respective one end to the holding cathode assigned to the position cathode, and their other end extends into the region of intensive ionization between this position cathode and the anode. These lines LH cause the glow discharge to be transferred from the position cathode to its holding cathode. Further lines LS are also provided for each point cathode, one end of which is connected to a point cathode and the other end of which protrudes into the area of intense ionization between the associated holding cathode and the anode. These lines LS cause the glow discharge to be transferred from the holding cathode to its position cathode.

All holding cathodes Cs-o to Cs-g are on line 15. If a voltage is now applied to line 15 that the voltage difference between the holding cathode and the anode is greater than that between the position cathode and the anode, it closes glow discharge to one of the position cathodes. the holding cathode, which is coupled by the line H to this point cathode. If, on the other hand, the glow discharge runs to one of the holding cathodes and the voltage difference between the holding cathode and the anode is less than that between the position cathode and the anode, the glow discharge passes over to the position cathode, which is coupled to this holding cathode by the line LS.

The line 15 is also connected to a flip-flop circuit 16, whose voltage changes are fed to all holding cathodes, so that a transition the glow discharge between holding and position cathode or vice versa depending on the Direction of the respective voltage change takes place.

The flip-flop circuit 16 contains a vacuum tube 17 with two triode tube systems L or R. These systems are mutually alternately conductive and non-conductive, whereby two stable states occur. Such a toggle switch is called a trigger designated. When system L is conducting, system R is non-conducting; one speaks then from the left state of the toggle switch. On the other hand, if system R is conducting; the system L is non-conductive; the toggle switch is then in its right-hand state. The anode of each system is connected to terminal 18 via a resistor, which is connected to the positive pole, e.g. B. 150 volts, a voltage source is connected, and over a resistor with a capacitor in parallel and a protective resistor connected to the control grid of the other pipe system. Every control grid is also led out via a resistor to terminal i-g, at which a suitable negative bias. Both control grids of the tube systems are also over Coupling capacitors connected to input terminal 2o. When switching on the Toggle switching always assumes the left state, which is done by known means and is indicated by an X at the bottom left of system L.

The flip-flop can switch from one stable state to another negative pulses are switched over at terminal 2o and does not speak to positive ones Impulses. The first negative pulse at terminal 2o does not have an immediate effect the non-conductive state of the tube system R of the tube 17, because the voltage is already below the blocking value on its control grid. However, there the tension is above the blocking value at the control grid of system L, this sets a negative pulse the voltage on the control grid of the system L decreases. This increases the tension at the anode of the system L. This increased voltage is generated via the parallel connection transferred from resistor and capacitor to the control grid of the system R and makes this conductive. The negative pulse occurring at the anode of the system R. is connected to the control grid via the parallel connection of resistor and capacitor of the system L and makes this even less conductive. This effect rocks up until system L is no longer conducting and system R is fully conducting, d. H. the toggle switch is switched to the right state. Will now be the terminal If a second negative pulse is fed in, the voltage at the control grid drops of the conductive system R, and the above-described effect occurs in the same way one that brings the flip-flop back into the left state. When supplying further negative impulses this process is repeated.

Thus, when the flip-flop is in the left state, that is Voltage at the anode of the non-conductive system R high; in the right state is the Voltage at the anode of the conductive system R low. The voltage on that anode is transmitted via line 15 to the holding cathodes Cs-o to Cs-g. In the left state the voltage fed to the holding cathodes is greater than that at the point cathodes lying voltage, so that the voltage difference between the holding cathodes and the anode is less than that between the site cathodes and the anode. Consequently the glow discharge continues to a point cathode if this is before the Toggling the toggle switch was the case, or the glow discharge will if they led to a holding cathode before switching the flip-flop circuit, to the corresponding one Position cathode transferred. On the other hand, in the right state, the tension is between the holding cathodes and the Anode larger than that between the site cathodes and the anode. As a result, the glow discharge from the site cathodes increases transferred to the holding cathode, if it was not transferred to there before.

Fig. 2 shows the pulses generated during the operation of a calculating machine or several by a punch card or the like with fourteen punch points per card pass controlled circuits can be generated. The punch card mentioned here is only given as an example. Other recording media or also other ones can also be used Impulse means such as buttons etc. can be used. Time pulses are between consecutive Hole point pulses generated at each hole point between the hole point o to 9 provided. At each hole point from X to 9, a card pulse is an erase pulse at the punched point location 13 and a carry pulse at the punched point location 14 generated if it is a counter. At the hole point point D ends one card circulation, and the next following circulation begins. An impulse in time X of the circulation indicates that the information punched in the card is negative.

Assume that the storage tube is in its initial state is located, in which a glow discharge between the site cathode Cp-o and the anode consists. The flip-flop 16 is in the left state; the voltage difference between the holding cathode and the anode is less than that between the cathode Cp-o and the anode.

A positive value is saved by applying a time pulse introduced to terminal r2. The negative leading edge of the time pulse i, which is immediately follows the index position o, the voltage on the forwarding cathodes C-o decreases to C-9, and that existing between the adjacent site cathode Cp-o and the anode Glow discharge will form between the forwarding cathode C-o and the anode, because the voltage difference between the cathode C-o and the anode is greater than which is between the cathode Cp-o and the anode. This transfer of the glow discharge takes place by means of the line ZWO, which is connected to the cathode C-o.

The rear front of the time pulse i is then fed to terminal f2. As a result, the voltage on the forwarding cathodes is finally increased so that the voltage difference between the site cathodes and the anode is greater than that between the forwarding cathodes and the anode. The glow path therefore wanders from the cathode -: - C-o to the cathode Cp-i and now exists between this and the Anode. The same transmission of the glow discharge takes place in each of the terminals 12 supplied pulse instead of; each pulse moves the glow discharge to the neighboring one Position cathode further.

It is often not necessary to save during the entire card cycle take place. The card is perforated at the point of delivery where the storage is positive Processes should stop. For example, if -I- 2 is stored by the tube 1o is to be, the card is in the hole point location 2 with a hole or a other suitable markings. As a result, the time: 2 becomes a negative card pulse 2 ° generated and the terminal 2o of the flip-flop 16 pressed. This pulse causes the toggle switch 16 to switch from the left to the right state. The voltage on line 15, which is the anode of the tube system R with the holding cathodes connects, falls, so that the voltage difference between the holding cathodes and the anode is larger than that between the site cathodes and the anode. Consequently the glow discharge existing between the cathode Cp-2 and the anode goes to the Holding cathode Cs-2 and the anode over. The following during this card pass the input 12 of the tube 1o supplied time pulses have on the position of the glow discharge no influence; it does not find any further storage during this card cycle in the tube 1o instead.

Finally, at time 13, input 2o of the flip-flop 16 is supplied with a negative erase pulse that moves it from the right to the left state switches, which increases the voltage at the holding cathodes and the voltage difference between the site cathodes and the anode versus that between the holding cathodes and the anode is enlarged. As a result, the one run to the holding cathode becomes Cs-2 Glow discharge through the cathode connected to Cp-2 and spread into the area intensive ionization of the holding cathode Cs-2., extending line LS2 to the position cathode Cp-2 headed.

The removal can, for. B. be done by the tube 1o ten Has counts carried out. If several tubes 1o are to be used as a counter, so you can give these, which form the next digits, a carry, impulse C forward, but this is not the subject of the invention.

The storage of negative values takes place via the nine's complement of the regular negative value. It is assumed again that the counter tube is in its initial state in which there is a glow discharge between the cathode Cp-o and the anode. The negative sign is indicated in the card by a hole or another suitable identifier at the hole point location X. The S-pulse generated in this way is fed to terminal 2o of the flip-flop circuit 16 and switches it to the right-hand state, whereby the glow discharge passes from the position cathode Cp-o to the holding cathode Cs-o, which discharge state remains stable until the flip-flop circuit again is switched to the left state. The time pulses occurring immediately after the time o and the time i therefore have no influence on the stable state of the tube 1o when they are fed to the terminal 12. When the negative value: 2 is stored, a card pulse 2e is generated at the time: 2 at the hole point position 2. This pulse switches the toggle circuit 16 back to the left-hand state and returns the glow discharge to the position cathode Cp-o. The seven time pulses following time 2 then switch the glow discharge step-by-step to the digit cathode Cp-7, as a result of which the -2 is stored as -I- 7, ie equal to the nine's complement of the negative quantity.

In Fig. 3, for. B. a card-controlled pulse generation is shown, however, the pulses can also be generated in a different manner known per se. A punch card 40 is between the brush contact roller 41 and the brushes 42 and 43 introduced. When the brush 42 passes through a hole in the card with the roller 41 in Contact is made, an impulse is generated. There is such a brush for each meter 42 provided. When the brush 43 makes contact with the roller 4i, it creates one S pulse (Fig. 2) indicating that a value should be subtracted. It is only one only brush43 provided in the storage or computing device.

The time pulses (see Fig. 2) are generated by the pulse transmitter 44, which contains the contact rails o-9, 13, 14, D and X. A brush 45 rotating with the shaft 46 makes contact with these rails one after the other as the shaft rotates. The rails z to g are connected to one another, and their common output terminal 12a is connected to the input terminal z2 (see FIG. Z). These terminals are also connected via a resistor 47 to the positive pole 48 of the network, e.g. B. at -I- Zoo Volt. The brush 45 is connected to the brush contact roller 41 and to the positive power terminal 49 which, for. B. is connected to -f- 40 volts.

The block T5o is a flip-flop, similar to that shown in FIG Circuit 16, however, the grids of the two tube systems have separate inputs (see connections 51 and 52). This toggle switch responds to negative impulses, which are fed to the control grid of their conductive tube system. The x on the left in the block indicates that the left tube system is initially conductive; therefore will the toggle switch is switched to the right state when terminal 5 z has a negative Voltage is supplied. It can then by a negative applied to terminal 52 Voltage can be switched back to the left state. That toggle switch applied negative voltage may be the front of a negative pulse or be the falling side of a positive pulse. According to the illustrated embodiment the flip-flop is switched by the fall of a positive pulse. the Output terminals 53 and 54 are the anodes of the left and right tube systems, respectively the toggle switch T 5o. Terminal 54 is connected to terminal 56 via line 55 of block S57 connected.

The block S57 is a known electron tube switch, its multi-grid tube is connected in such a way that, with the simultaneous supply of two pulses, e.g. B. positive impulses, which are sent via terminals 56 and 58 to one of the two grids are fed. The anode of the tube is connected to the terminal 59, which is on the line 6o is connected to terminal 61 in block J62.

The block 16.2 is a known electron tube inverter which z. B. contains a triode switched in such a way that it responds to negative pulses fed to its grid input 61. The anode of the triode is connected to terminal 63 and, via a resistor, to the positive pole of a voltage source (not shown). The blocks J64, 165 and J66 represent further reversing stages. The anode terminals 67, 68 and 69 of these stages are connected to one another and to the positive pole of a voltage source (not shown) via a common resistor. The terminals 70, 71 and 72 of these stages are connected to separate control circuits. A pulse therefore always occurs at the output terminal 2oa when a pulse is supplied to one of the input terminals 70, 71 or 72. The output terminal 2oa is connected to the terminal 2o (see. Fig. R). The brush 42 is connected via the line 74 to the terminal 72 of the inverter 166 and via the resistor 75 to ground. The brush 43 is connected via the line 76 to the terminal 5 r of the flip-flop T 5o and via the line 77 to the input 71 of the inverter J65 and to the terminal 8o. In addition, the brush 43 is grounded via the resistor 8 1.

The rail 13 of the pulse transmitter 44 is connected via the line 83 to the terminal 58 of the switch S57 and via the resistor 84 to earth. The rail 14 of the pulse transmitter 44 is connected via the line 86 to the terminal 52 of the flip-flop T 50 and via the resistor 87 to earth. In addition, the rail 14 is connected via the line 88 to the input 89 of the reverser Jgo. Negative transmission pulses occur at the terminal 92 connected to the output 9r of the inverter Igo.

The output terminal 63 of the inverter J62 is connected via the line 95 to the input 7o of the inverter J64 and the terminal 96 . The S-pulses occurring at terminal 8o and the canceling pulses occurring at terminal 96 are also applied to inputs 7 1 and 7o of inverters J65 and J64 . From the terminals 8o and 96 subtraction or erase pulses for further operations of a calculating machine are taken, but this is not the subject of the invention.

The shaft 46 of the pulse transmitter 44 runs synchronously with the passage of the Card 4o between the brushes 43 and 42 and the contact roller 41. That is, the Brush 45 makes contact with a rail when the counting point with the same number gives up of the card is sensed by the brush 42. So is z. B. the brush 45 at the time 3 connected to the rail 3. When the brush 45 with one of the rails z to g There is contact, the terminal i2a is on the -I- 4Ö volt connection q.9, and a negative timing pulse is generated. If the brush 45 does not touch a rail, Terminal 12 is only connected to -I- 200 volt connection 48 via resistor 47 tied together. In this position the glow discharge runs in the tube io (cf. Fig. I) to a site cathode, and every time the brush hits one of the rails touched and a time pulse is generated, the glow discharge is over the neighboring Transfer the forward cathode to the next position cathode. Becomes the impulse transmitter operated at high speed so it is advantageous to use smoothing sieve media to switch between the pulse transmitter and the counter tube to ensure that the counter is not operated by accidental voltage fluctuations. Such Arrangement can be provided between the terminals z2a and 1.2.

When the brush 45 makes contact with the rail 13, it becomes a positive Erase pulse generated: This arrives via line 83 to input 58 of the switch S 57, which makes it conductive if its other grid is via input 56 is positive. When the brush 45 touches the rail 14, there is a positive transmission pulse fed via lines 86 and 88 to the input 89 of the inverter T 9o, and to Terminal 92 has a negative transmission pulse (see Fig. 2). At time D (cf. Fig. 2) the flip-flop T 5o is in the left state. Hence the tension at terminal 54 high. This high voltage is applied via line 55 to the input 56 of the switch S 57 supplied. Therefore, the input 58 of the switch switches on S57 positive impulse pressed this switch on, and at its output 59 an impulse occurs.

If -h 2 is to be stored in the tube io, when the brush 45 and the rails i and 2 make contact via the terminals i2 a and 12, the glow discharge in the tube io is passed on from the position cathode Cp-o to the position cathode Cp-2 as already described above. Now the perforation 2 in the card 4o is sensed by the brush 42. "As a result, a -f- 40 volt pulse is fed to input 72 of inverter J66 , and a negative pulse occurs at terminal 2oa (see 2c in FIG. 2) No further migration of the glow discharge; the tube io has the stored value -F- 2.

At the time r3, when the brush 45 touches the rail 13, a positive pulse is transmitted via the line 83 to the input 58 of the switch S57 and makes it conductive. Therefore, a negative pulse arrives on the line 6o to the input 6i of the inverter T 62, so that from there a. positive pulse reaches input 7o of inverter J64 via line 95 and a negative erase pulse occurs at connection terminal 2o11, by means of which flip-flop 16 is switched back. At time 14, a negative carry pulse is generated, as can be readily seen from the circuit diagram. When subtracting the value 2, the brush 43 touches the contact roller 41 through a special identification hole in the card, whereby an -I- 4o volt pulse is given to the input 5 i of the toggle switch T 5o and this toggle switch from left to right State is switched. As a result, a low voltage is applied to input 56 of switch S57. The same -I- 40 volt pulse also reaches the input 71 of the inverter 165 via the line 77 and generates the negative pulse S (see FIG. 2) at the terminal: 20a. This negative pulse switches the flip-flop 16 to the right-hand state.

The later time pulses i and 2 therefore have no influence on the tube io. However, since there is a perforation at the counting point location 2, the brush 42 touches the brush contact roller 41 at time 2 and leads the input 72 of the reverser 169 to a. + 40 volt pulse to, so that the card pulse 2c at the connection terminal; 2oa occurs and as a result, the toggle switch 16 is switched back to the left-hand state. Therefore, subsequent time pulses are stored in the tube io. At time 13, the -i- 40 volt erase pulse fed to input 58 of switch S 57 via line 83 has no effect on this switch, since the voltage at its input 56 is low. This pulse is therefore not fed to the flip-flop circuit 16.

To the. At point 14, a negative carry pulse occurs at the terminal 92 on. The -I- 40 volt pulse on line 86 also becomes the terminal 52 of the flip-flop T5o supplied. This shifts in front. Right in service: left state, and the arrangement returns to its initial state.

Claims (3)

PATENT CLAIMS: i .. Gas-filled discharge tube with several cathodes and a common anode, whose controlled glow discharge for storage and counting ;, is used in particular in calculating machines controlled by recording media, thereby characterized that between the at approximately the same: spaced from each other Position cathodes (Cp) lengthways. eüwr closed: each corona discharge path has one forwarding cathoid (C) and a holding cathode (Cs) is also assigned to each position cathode is. 2. Order after claims, ah. i, characterized in that the forwarding the glow discharge takes place by controlling the cathode poltentiaae. 3. Arrangement according to claims i and 2, characterized in that additional glow transfer means (L, LH, LS, LW) are provided to facilitate the forwarding of the glow discharge. q .. arrangement according to. Claim 3, characterized in that 11, n of each cathode at least one Gli; mmtransmission.m: means is attached in the form of a conductor, the other free end in the area of strong ionization of the z. Currently existing glow discharge from a neighboring cathode is sufficient. 5. Arrangement according to claims i and 2, characterized in that between the position cathodes (Cp) and the common anode a: fixed DC voltage is, while for the purpose of forwarding your glow discharge from one position cathode to the next, the voltage between the relay, tkatthoden , (C) and the common anode is changed according to the pulses to be stored. 6. arrangement nasch den; Claims; i to 5, characterized by a pulse timer (44, 45, 46) which synchronously with the sensing or evaluation device (4 i, 4z, 43) the cathode potential of the tube; (io) controls in such a way that from, an index point on, e.g. perforation in the card (40); no more values are saved. 7. Arrangement nasch claim i, characterized in that the holding cathodes store negative values in the form of their nine's complements. B. Arrangement according to claims i and 7, characterized in that the Halteka; tho: -dien (Cs) evil one! controlled, flip-flop (i6) can be applied to control voltages through which the glow discharge is transmitted according to a predetermined plan between the holding cathodes (Cs) and position cathodes (Cp). G. Arrangement according to claim 8, characterized in that the transfer of the glow discharge from a point cathode (Cp) to the holding cathode (Cs) assigned to it takes place via an electron tube scraper (S57) for a predetermined time by applying the potentials to the Forward cathodes are degraded. ok Arrangement according to one of the preceding claims, characterized in that the cathodes, a1 & hollow cylinders are formed, the surfaces of which are covered with coatings. that limit the glowing load to the cylinder inner surface. References: U.S. Patent No. z 577 809.