DE1101029B - Device for counting or controlling processes - Google Patents

Description

Device for counting or controlling events. The invention refers to a device that is used to count and control consecutive Operations. Changes in electrical voltages correspond to these processes or currents which are fed to the counter as control signals.

For the construction of counting circuits one often has next to decadal Systems Dual systems with subsequent evaluation of the binary numbers in the decadic System used. In addition, other intervals, such as. B. Systems with five counting steps and also subsequent evaluation, became known. In addition, there are also arrangements in which an interval of more than ten, is composed, for example, of twenty steps.

The storage of the individual counting steps until the next counting pulse can be used in electrically or electronically working memory circuits, e.g. B. at bistable tilting arrangements take place. The flip-flops for the individual stages which represent counting steps are usually capacitively coupled to one another.

Counting circuits are often found in various types of control devices Use. Mechanical stepping mechanisms, as they are often used in machine tool controls are used, have the disadvantage that they are resistant to vibrations, dust etc. are sensitive. In addition, they are subject to a certain amount of wear and tear, so that it for operating cases with requirements for a high level of accuracy and safety cannot always be regarded as reliable enough. Furthermore, the switching speed is with a mechanical stepping mechanism only to a limited extent, while in many cases, z. B. with measurement controls, higher step speeds are required and an upward and downward counting with a switching frequency is often required, which corresponds to a frequency of several kilohertz.

It is already known per se to use controllable semiconductors in counting circuits, especially transistors. Furthermore, one also has many counting circuits constructed with tubes, with high vacuum tubes as discharge paths from case to case or gas or vapor-filled discharge vessels were used. Both known counting circuits are generally concerned with each counting step to store with the help of a bistable toggle circuit per se. With tube circuits one can use discharge vessels with double discharge paths for this purpose. at the use of transistors can be seen in the characteristic curve of tip transistors exploit; which has two stable states, so that with only one Tip transistor could possibly build a bistable circuit. Tip transistors however, they have various disadvantages that they do not in some applications seem suitable, so that one mostly uses transistors has passed, which each have only a single stable state, such as this is the case, for example, with the surface transistors. Accordingly, require bistable multivibrators each with two flat transistors. One could also think of to use composite transistors, which are then similar to the double systems of discharge tubes would correspond to two separate transistors.

In the known counting circuits, as mentioned, usually from one capacitive coupling of the individual stages, which correspond to counting steps, use made. Counting circuits with capacitive coupling are exceptional against interference pulses sensitive, on the other hand the transition to galvanic coupling would be a high one Mean expenditure on components and bring other difficulties with it. In contrast it is important in the invention, while saving components to a to arrive at a greatly simplified, but operationally reliable facility which, above all, can reduce the number of tax routes. The invention is important for control lines that are located within a high vacuum discharge vessel are located as well. for steam and gas discharge devices. Farther limited the invention does not apply to the use of discharge vessels with thermionic Cathode, rather it is also easily possible to use cold cathode tubes or to provide other electron-emitting electrodes instead of heated cathodes.

The invention consists in a device for counting or control of chronologically successive processes involving changes in electrical voltages or currents and which are supplied as control signals to the counter are, with only one discharge path per stage, that the discharge paths High vacuum tubes are that the anode of each tube with the control grids of the neighboring ones Tube via a resistor and a valve as well as with the control grids of all the remaining tubes are galvanically coupled via a resistor each.

The invention is to be explained in more detail with reference to the drawing. the Figures show exemplary embodiments in their essential parts for the invention in a simplified schematic representation.

The embodiment shown in FIG. 1 is to a counting circuit, in which for the sake of simplicity of illustration in place a decade an interval of six levels is illustrated.

As already mentioned, one of the decadal division can also be used different number scales can be used. The last level of the respective interval is with switching elements of the same type as they are between the individual stages, reconnected to the first stage, making a ring of completely alike built-up steps results. From a certain point you go to decadic The division continues to the next decade, in this way the individual decimal places to be able to form.

In each individual step, i.e. for each counting step, there is only one only discharge path provided. With 1 to 6 the individual are grid controlled Triodes symbolized discharge paths called. It can be act as separate tubes, but it is also easily possible to have two or more To accommodate discharge paths in a single bulb. This has mainly because of that particular importance, since the individual discharge paths are connected to one another on the cathode side are connected, so that under certain circumstances a common cathode as the electron source for two or more, possibly all of the discharge paths can be used can.

As the illustration shows, all cathodes are connected to one another and placed at zero potential while for the working electrodes, which in this case formed by the anodes, resistors 7 to 12 are provided, which their Voltage obtained by connection to the positive pole of the anode voltage source 13. It would be equally possible, in place of anode resistors or in addition to this also resistors with cathode-side exit of the tubes are to be provided. Included If necessary, there would still be the option of using the cathodes as output electrodes to use and on the cathode side to take the power that is used to control the should be used next level in counting direction.

Each of the anodes 14 to 19 of the discharge tubes 1 to 6 is connected to one another Resistor and a diode with the control grid connection of the following in counting direction Discharge path connected. Since in the illustrated embodiment, the counting direction run from front to back and again from back to front on a case-by-case basis can, the resistors 20 to 25 are provided for the operation of the counting up, which feed the control voltage to the next step when counting up. In order to be able to work in reverse direction, the resistors are accordingly 26 to 31 are provided. The corresponding diodes are 32 to 37 and 38 to 43 designated.

At the same time there is a connection from each anode connection to the Control electrode connections of all other discharge paths, d. H. so all of them Discharge routes, apart from the two adjacent routes, via a network of resistances. So is z. B. between the anode 14 of the discharge path 1 and the control electrode of the discharge path 3 a resistor 44. To the circuit diagram The individual connections of the coupling resistors have been made clearer with the associated anode connections and those connected to the resistors are omitted Lines denoted by 14 to 18, that is to say with the same reference numerals as the provided with individual anodes. This means that these lines are connected to the appropriate Points of the circuit are placed to think about. So leads from the anode of the tube 1 in each case to the control electrode of every other discharge path except for paths 2 and 6 such a resistor connection; so the resistor 45 to the control grid the discharge gap 4 and the resistor 46 to the discharge gap 5.

Correspondingly, there are discharge paths on the anodes of the other discharge paths the resistors 47 to 61. As the illustration shows, no Resistance to the following path in counting direction, d. H. neither to the one in front lead to the discharge path behind it.

In addition, the diodes 62 to are connected to the resistors 20 to 31 73 placed, which together with the resistances have an effect according to a so-called Have "and" gates. The diodes 62, 64 and 66 are in the input E1, the diodes 63, 65 and 67 are combined to form input Ei. The high-value resistors 74 to 79 are only used to supply the necessary grid bias for the individual discharge paths, with the necessary negative potential from a grid voltage source 80 is derived.

The circuit arrangement makes it possible that only one Discharge path can be in the blocked state. In this system flows then no or only an extremely low anode current, so that in each case associated resistance of the resistors 7 to 12 no or no significant voltage drop entry. The anode in question is then practically at the same potential as the anode voltage source. This gives all the remaining discharge paths via the Resistors from their control electrode terminals to the anodes of the blocked Systems lead, control voltages and are thus live. When dimensioning of the resistances between the anode of the previous or following stage on the one hand and the control grid of the stage to be considered, it should be noted that that with regard to the behavior of the respective diode and the dimensioning of the grid resistances a favorable working point for the discharge path is formed. Possibly were it is also possible, in contrast to this arrangement, with only one discharge path at a time is locked to cause by appropriate modification of the circuit that each only one tube is open while all the rest Discharge routes are blocked.

In order to understand the mode of operation of the circuit arrangement shown, it is assumed that the discharge path 1 is initially in the blocked state and that all other paths carry current accordingly. The input El of the two inputs Ei and Ei may be de-energized, ie at zero potential. Since the cathode connections also have zero potential, this would mean that Ei is at zero or ground potential. The other input, namely Ei ', may have received or just received a positive signal from the input from a flip-flop circuit or some kind of switching device. If the control voltage is now changed, i.e. Ei is applied to zero potential and a positive control voltage is made effective at Ei, the discharge path 2 must switch to the blocking state at this moment, because its control grid input (in front of diode 32) arrives via diode 63. To lie zero potential, and there then no more control current flows through the diode 32. The diodes 37 to 43 have a higher threshold value than the diodes 62 to 73, so that zero potential is then actually reached at the control electrode of the path 2.

When controlling the arrangement, it is then assumed that the Control signal, which is an alternating voltage or a direct voltage changing polarity or a pulse voltage, so to the inputs is applied that once - one input terminal to zero potential and the other is on positive or negative control voltage and when switching to the next Counting step the two polarities are swapped. When counting down, what is only to be described in more detail below, the same polarity reversal or occurs Pole reversal as in counting up. The waveform of the control voltage should if possible have a rectangular course. It is only towards it Make sure that there are no excessive amplitude fluctuations in the control signals are present, so a minimum amplitude is guaranteed, which depends on the input impedance however under certain circumstances. can be very small. So it is also without further possible with the help of a simple switching device, so z. B. in primitive Way with a limit switch to evoke the control voltages, by alternately the input terminals. Ei and Ei 'are set to zero potential.

As soon as the discharge path 2 blocks and thus the voltage drop across the anode resistor 8 drops, the anode 15 becomes increasingly positive and a control current flows through the resistors 21 and 47, 48 and 49. As a result, the lines 3, 4, 5 and 6 remain in the current-carrying state. However, there is now also a connection to the control electrode of the discharge path 1 via the resistor 26. As a result, the discharge path 1 is now also live. The next time the signal at Ei and Ei changes , line 3 is blocked and line 2 is energized again. Each time the input signal changes, switching takes place, and the outputs at the anode connections 14 to 19 receive signal voltage one after the other. After the discharge path 6 follows the path 1 again in accordance with the ring coupling, so that after the discharge path 6 has been blocked, the path 1 returns to the blocking mode of operation.

The circuit arrangement shown is expediently used as a decade build up. If necessary, however, one can also provide twenty or more counting steps. If there are more than ten steps, however, the effort involved in coupling resistances may under certain circumstances are viewed as undesirably high. However, it is possible according to further invention make substantial savings on coupling links. This should be based on the Fig. 2 will be explained in more detail.

In FIG. 2, a resistance field for a decade is illustrated, for the sake of simplicity only the case was assumed that it is a counting chain with counting in one direction. Accordingly, in FIG. 1 one must think of the connections from the respective anodes to the control electrode of the preceding section to be omitted, that is to say the resistors 26 to 31 must be removed. For this purpose, corresponding anode-control electrode connections would then have to be created in the resistance field in connection with the resistors 46, 50, 54, 58 and 61.

In the network shown in Fig. 2, the connections to the individual Anodes 81 to 90 of nine discharge paths on the one hand and the connections 91 to 100 on the other hand, which lead to the control electrodes of the ten systems. As the illustration shows, there is one each of the anodes 81 to 84 Resistance connection to the control electrode connections of the discharge systems 96 to 100. This is illustrated by the dashed line 101. Likewise exists from the anodes 96 to 99 a resistance connection to the control electrodes of the Discharge paths 91 to 95 in which are delimited by the dashed line 102 Space. These two networks of twenty resistors each can be made by circuits of four diodes and five resistors each have to be replaced.

An exemplary embodiment for this is shown in FIG. At the control electrode connections of the tube systems 96 to 100 resistors 103 to 107 are illustrated, which in turn are connected to the anodes 81 to 84 by means of diodes 108 to 111. The possibility of such a combination is all the more appropriate, the higher the number of counting steps the circuit has. With twenty steps z. B. two networks of ninety resistors each are replaced by ten diodes and nine resistors each. If necessary, an intermediate amplification system can also be used for signal amplification.

In the embodiment shown in Fig. 1 is the possibility counting down has been taken into account. The dashed connections that lead to the inputs E2 and E2 '. on in this way the same conditions for counting down come about, with then the process in a corresponding manner from any discharge path from goes on to the previous ones.

In many cases it may be desirable that the circuit when the Operating voltage assumes a certain rest position, d. h., it depends on there not any other discharge path from case to case the starting position certainly. For example, it may be desirable to keep route 1 closed, so that when the Establishment or after short-term arbitrary or unintentional business interruptions always the same starting position is ensured. Provided that the operating voltage through the in a power supply unit Smoothing devices has a slow current rise when switched on, can by interposing a threshold rectifier in the control circuit of the discharge path 1 the desired condition can be easily met.

The counting circuit according to the invention can also be used in multi-contact control systems use. The diodes 62 to 73 are then not connected to the inputs Ei, EI or E2, E2 combined, but each connected to a limit switch that when actuated of the same, the diode located in front of the control electrode has a low resistance to zero potential lies. In this case, the diodes 62 to 73 can safely be omitted will. The counting level can then only be advanced using the limit switch, which leads to the entrance of the discharge system, which of the currently blocked Discharge path follows. Activation of all other limit switches would be ineffective be, d. This means that the limit switches are interlocked at the same time guaranteed.

In Fig. 4, a further embodiment is shown in which for the counting device to work in forward and backward directions Gate coupling formed from diodes and resistors in connection with one each Tilting arrangement is provided for working in forward and backward directions. In this case, the stages forming the predetermined interval are a bistable multivibrator upstream. The circuit shown with ten discharge paths in the decade has ten stable states.

The discharge paths of the decade are labeled 121 to 130. By means of a suitable gate coupling of diodes and resistors and one preferably of two discharge tubes. If necessary, however, a bistable device constructed from two transistors or other devices ensures that the pulses for forward numbers given to the input block the individual discharge paths one after the other. Depending on the counting step achieved, the corresponding counting signal can therefore be taken from the corresponding output electrode of one of the discharge paths.

The control signal voltages for up and down counting are applied to various input terminals of the arrangement. For counting up are the connections Evl and Eve are provided, for downcounting accordingly ER, and ER2, where Eve and ER2 are only required if several decades have become one Decimal counting system can be interconnected. It is assumed that the Signal voltage, which is an alternating voltage or a direct voltage changing polarity or a pulse voltage, so to the input Eve or ER2 is applied that normally these input terminals are at zero potential and then - with a control signal - are at positive potential.

For the process of counting up, the decade is one of the two Discharge paths 131 and 132 constructed bistable precursor connected upstream. For the operation of the - down counting is a corresponding one from the discharge paths 133 and 134 existing tilting stage provided. The ones still lying in the entrance Systems 135 and 136 are only used for signal amplification and are therefore for the Counting device not required immediately.

The function of the counting decade is as follows: In the starting position it is assumed that the discharge path 121 is blocked. may be. It is also assumed that neither a signal for forward numbers nor -for counting down is available. The discharge paths are located accordingly 135 and 136 in the locked state. The control electrode of the discharge path 131 receives positive control signals via the diode 137 and the resistor 138, which with the anode A1 of the discharge path 121 is connected. The same is done on the control electrode the discharge path 133 via the diode 139 and the resistor 140 a control voltage effective through the: connection with the anode A .. The distance is accordingly 131 controlled and the route 132 blocked. Likewise is in the flip-flop at the entrance the distance 133 is controlled for the downcounting and the distance 134 is blocked.

The discharge paths 123 to 129 are received from the anode A1 of the path 121 over the resistor network control voltage. It is namely the anode of one every discharge path with the control electrode every other discharge path except connected to the two neighboring ones. The adjacent discharge path 122 is maintained Control voltage from the anode of the tube 135 via the diode 141 and the resistor 142. The other adjacent discharge path, namely the discharge path 130, is maintained Control voltage via the diode 143 and the resistor 144 from the anode of the discharge path 136 ago. As a result, the two adjacent discharge paths, namely 122 and 130, just like the other discharge paths 123 to 129, live.

It can now, depending on whether a counting pulse is used for up or down counting comes, either the discharge path 135 or 136 are controlled. For example the path 135 is modulated, because of the voltage divider that is generated by the Resistors 145 and 146 from the anode of the path 135 to the negative pole of the Grid voltage source 147 is formed, first the diodes 148 and 149 are transparent. Current can therefore no longer flow through diodes 137 and 150 The path 135 is controlled by the negative grid bias of this discharge system reduced to almost zero. However, this results in a high resistance at the anode resistance 151 Voltage drop caused, so that across the resistor 142 and the diode 141 control voltage is no longer effective at the control grid of the discharge path 122. The result is that the negative grid bias from the current source 147 predominates and the discharge path 122 now reaches the state of the lock. The current effective through resistor 152 can no longer flow through diode 153, Instead, it flows via the diode 154 to the control electrode of the discharge path 121 and controls them. It is assumed that the threshold values of the Control electrodes of the discharge path diodes are higher than the threshold values of the diodes connected to the anodes A1 to A10. The remaining discharge paths 123 to 130 remain leveled as before.

As soon as the counting signal disappears, the path 135 blocks. There is then no more voltage drop at the anode resistor 151 , so that the anode of the discharge path 135 practically assumes the positive potential of the anode voltage source 155. Reverse voltage is now also applied to diodes 148 and 149. Since it is no longer the discharge path 121, but the path 122 blocks, that is, the anode A2 of which is at a high positive potential, the discharge path 132 is connected to the control electrode via the diode 150 and the resistor 156 and the diode 157 and the resistor 158 of the control electrode of the discharge path 134 control voltage effective. The paths 132 and 134 are thereby controlled and thus the discharge paths 131 and 133 of the two flip-flops are blocked. When the next counting signal arrives at the control electrode of the discharge path 135, the discharge path 123 blocks, and the process takes place in a corresponding manner, as described above.

The work cycle takes place in a similar way when signals are sent to the Down counting can be given. If there is a signal for counting down at input ER 1 is laid, controls the tube 136, and it results in the one described above Switching process similar work. For example, last was the discharge path 123 blocked, the line 122 now enters the blocked state.

Since the circuit does not contain any coupling capacitors, so in place an otherwise common capacitive coupling a galvanic connection of the individual Stages is provided, the switching speed is frequency-independent. Up the counting frequency is essentially only due to the switching time of the discharge paths or diodes limited, the galvanic coupling has the advantage that the circuit as a result, it becomes insensitive to interference pulses.

A system according to the embodiment shown in FIG. 4, which encompasses a decade, systems with the same or a similar structure can thus be used can be connected in this way to several decimals of individual decades form. In this way you can build a larger decimal counting system. That The signal for counting up can be sent to all inputs Ey2 at the same time Decades to be given. The connection EV 1 is then always with the output "Zero" of the previous decade connected via a capacitor with a small capacitance. A corresponding connection of the applies for the downcounting in an analogous manner Entrances.

Claims (10)

PATENT CLAIMS: 1. Device for counting or controlling chronologically successive processes to which changes in electrical voltages or currents correspond and which are fed as control signals to the counting device, with only one discharge path per stage, characterized in that the discharge paths are high vacuum tubes (1 ... 6) and that the anode (14 ... 19) of each tube with the control grids of the neighboring tubes via a resistor (20 ... 25 or 26 ... 31) and a valve as well as with the control grids of all others Tubes are galvanically coupled via a resistor (44 ... 61) each. 2. Device according to claim 1, characterized in that two control signal lines (E1, Ei ') the one (EI) to the control electrodes of the even-numbered discharge stages (2, 4, 6) and the second (Ei) to the control electrodes of the odd-numbered stages (1, 3, 5) leads. 3. Device according to claim 2, characterized in that the The counting steps are switched on by the control signal lines (Ei, Ei) are alternately connected to the cathode potential of the control paths. 4th Device according to Claim 2 or 3, characterized in that when the Control signal lines are associated with the discharge paths through each control electrode Contacts can be blocked one after the other and only in the counting direction, always the previous ones Open discharge paths and this state is stable and remains as long as it is, until the next counting step is reached by pressing the next contact, and where appropriate, the blocking and opening of the discharge paths by contactless electronic switching, e.g. B. a semiconductor, especially in a flip-flop circuit can be done. 5. Device according to claim 1 to 4, characterized in that by inserting a diode in the resistor connection of the output electrode, in particular anode, any discharge path to the control electrode of the preceding one and by a diode connection (68 to 73) to two additional steamer signal lines (E2, E2) in addition to an up-counting mode, there is also a down-counting mode is to be formed. 6. Device according to claim 1 to 5, characterized in that for the counting device to work in forward and backward directions Gate coupling formed from diodes and resistors in connection with one each Tilting arrangement is provided for working in forward and backward directions. 7. Device according to claim 6, characterized in that the predetermined A bistable multivibrator is connected upstream of the interval forming stages. B. Facility according to claim 7, characterized in that the bistable multivibrator is provided by discharge paths is formed. 9. Device according to claim 6, characterized in that the bistable Flip-flop controllable semiconductors, in particular transistors, contains. 10. Establishment according to claims 1 to 9, characterized in that some of the discharge paths is formed by controllable semiconductors, in particular transistors. Into consideration printed publications: Electronics, January 1950, pp. 84 to 87.