DE906519C - Circuit arrangement for displaying or registering instantaneous values - Google Patents

Description

Circuit arrangement for displaying or registering instantaneous values The invention relates to circuit arrangements for displaying or registering Instantaneous values. In particular, it relates to devices for converting values variable size in numerical or table values, which in any way can be registered, for example in the .Weise that holes in cards be made.

At present, experimental data is usually either manually or by means of automatic recording devices, for example self-writing galvanometers, registered. In general, the manual method is only used when the data to be registered are only available in small numbers and the time between successive evaluations is large enough to allow the observation by the allow the human eye and manual recording. When a wide choice for statistical purposes or if the evaluations are desired at a speed must be made that is larger than that of the human eye and the Automatic registration is used corresponding to the human hand. In certain cases, however, such as those in which the evaluations - discontinuous or subject to major changes or fluctuations Do not use automatic recording devices. Furthermore, if a big amount of. Rows of graphical data registered and added together, checked or needs to be corrected or compared with each other, the follow-up treatment or checking the data is tedious and time consuming, even then if an 'automatic registration is used.

Therefore, the invention relates to a new and improved device for converting instantaneous values or averaged values over a relative short period of time which values are taken from. are of variable size, in Values that are represented by table numbers, for example for converting The value of a continuous physical variable that occurs over a period of time of selectable variable length is averaged out into a two-digit table (square series link), the above-mentioned type converting device being simple is under construction and consists of a very small number of components.

The invention enables such a conversion without sacrificing accuracy is forfeited by using a unit in the two-way playback system, whose value is equal to or just a little less than the interference level that the Variables that are to be measured corresponds to and what is peculiar to them is what the corresponds to best practice prescribed by current transmission theory will. The invention also enables tabular values, which instant or correspond to averaged values of variable size, make visible or to register.

According to the invention, all of this is achieved in that a voltage, which corresponds to an instantaneous or mean value of a variable, one after the other to a number is transmitted by relay devices, which tension according to values the consecutive two-digit row (square row) obtained. One Sufficient number of relay devices is applied to keep up with the required Degree of accuracy the highest: being able to reproduce tabular value that registers shall be.

An electrical switching device is connected to each relay device brought, which works automatically, to the input signal, that of a preceding Relay device is transmitted, the next of the following relay devices to submit. When the input signal is that of a preceding relay device is transmitted, is less than the voltage that is required to the switching device to make it effective., the input signal is sent to the next of the subsequent ones Relay devices passed on unchanged. However, when the input signal is too a preceding relay device is strong enough to power this relay device To make effective, the switching mechanism works automatically in such a way that it to the next of the relay devices the difference between the input signal to the previous relay device and the tension transmitted to it.

Any relay device that works in the prescribed manner can be made, is able to operate a corresponding optical display device or to effect a suitable registration, for example the punching of a card.

When the signal to be converted is moving at a relatively high speed changes, devices are used to measure the instantaneous values of the signal at the beginning of each conversion period, with the selected values corresponding to are obtained, are converted into tabular values of the type described above.

With a circuit arrangement of the type described above, instantaneous values a variable can easily be converted into two-table values. Still works the rear derailleur of the type used in such a way that it is the actuation of a Relay device prevented, unless it is actually to be actuated, whereby errors are reliably avoided.

In some typical applications of the invention to which later is discussed in detail, it is assumed that the variables to be registered can be simulated by a voltage of appropriate magnitude. Indeed you can almost all physical variables whose experimental measurements are desired, can be simulated in practice. A typical example of such a measurement is the measurement of the light intensity through a photo-amplification tube, which when it is noticed generated by light a corresponding voltage across a load resistor.

In practicing the invention, the voltage which corresponds to the variable., compared sequentially to each of a number of voltages, which with respect to the size of consecutive table values in a two-table system correspond. The greatest of the latter tensions and the one with which .the voltage corresponding to the variable to be measured is compared first, has a magnitude equal to the highest power of 2 that can occur or in other words the uppermost limit of the voltage to be recorded. the Magnitude values of the following voltages, with which the voltage, that of the variable corresponds, is compared, corresponds to successive smaller patents of 2, where as many can be used as are necessary to! the to register the voltage to be registered with the desired degree of accuracy can.

If in any comparison stage the voltage that of the variable Corresponds to the amount to be measured; is greater than the equivalent stress, so just becomes the difference between the two. Tensions for comparison with the voltage that corresponds to the next lower power of 2. To the At the same time, switching and control means for producing a display or registration. On the other hand, if the tension -which corresponds to the variable amount, is smaller than the comparison voltage, which the former voltage unchanged for the purpose of comparison with the voltage passed on, which corresponds to the next lower power of 2.

The ones used for comparison (for subtraction from the input signal) Voltages can, if desired, be taken from any reliable voltage source will. In certain embodiments of the circuit arrangement according to the invention batteries are used for this. Storage batteries that are well charged or dry cell batteries are generally satisfactory. It is well known that certain standard cells or batteries, such as the calomel cell, have a reference voltage of deliver high uniformity and with a value that is in certain critical Dates exactly. Such cells are preferably used as measuring voltages for physical or chemical experiments.

Therefore stand for registration measurements with an exact physical or chemical experiment very well known, generally recognized and preferred Standard voltage to be used for the basic comparison and subtraction circuits according to the (invention available. However, it is also possible to use electron sources to apply for comparison and subtraction voltage when using Batteries or standard cells are not recommended.

The invention will now be described in more detail with reference to the drawing i shows a circuit arrangement of a basic element: that can be used for transmission devices according to the invention, Fig.2 shows a circuit arrangement of a similar nature for a basic element, which is more advantageous for use in of the invention, Fig. 3 is a circuit arrangement of a selection device and a Zeitwerk, which devices used for a transmission device according to the invention can be, Fig. q. a circuit arrangement with a number of relays and Switching mechanisms to be used in the new transmission system, FIG. 5 a Circuit arrangement of a registration and display device for use in the system according to the invention, while Fig.6 is a diagram of a suitable relay or a Microswitch represents which can be used in the system.

A typical switching element which. can be operated in the manner described above, is shown in Fig. i. It consists of an electron tube io with a grid ii, which is connected to the negative pole of a bias voltage source 12, the positive terminal of which is connected to an input line 13. The input line 13 is provided with a screen 49 which is earthed as shown. The grid ii is also connected to a conductor 14 which leads to a stationary contact 15 of a relay 16, the winding of which is between a suitable anode voltage source B -I- and , the anode 17 of the tube io 1. The input line 13 is also connected via a conductor 18 to another stationary contact i9 of the relay 16. In the rest position, the contact i9 is in contact with a movable contact arm 2o, which via a conductor 21 is connected to leads to an output terminal 22. When the relay 16 is energized, the contact arm 20 leaves the contact i9 and lies on the contact 15.

For the explanation of the mode of operation it should be assumed that .the bias voltage caused by the voltage source, the value of a corresponds to a certain power of 2. If now the voltage of the input line 13, which corresponds to the variable quantity to be measured, positive and is greater than the bias voltage of the voltage source 12, the tube becomes conductive, whereby the relay 16 responds, so that the movable contact arm 2o the contact i9 leaves and hangs up on contact 15. The output power that of the next Stage is transmitted to the output terminal 22, is therefore the same as the difference between the voltage to be measured and the preload. However, if the input voltage on the input line 13 is less than the pre-voltage, the pipe remains OK non-conductive, and the movable contact arm 20 therefore remains in contact with the Contact i9. The output power to the next stage is therefore equal to the input on line 13, this time without change.

As a result of the inaccuracy in the operation of the usual relays, for example the relay bounces and the large differences in the opening and closing times of relays of the same type, it is desirable to have two Relays to be used to either provide the input power to the one stage or the Input power to the control grid of the pipe in this stage to the next stage to switch on, as shown in FIG.

In fing. 2, the signal input track is transmitted to the input terminal 13 via a negative bias voltage source 23 and a resistor 24 to the control grid 25 of a conventional q.-electrode gas discharge tube 26. The cathode 27 and the screen grid 28 of the tube 26 can be connected to earth at 29, while a capacitor 30 is connected between the grid 25 and the cathode 27 in order to prevent the tube 26 from being ignited by interference or stray signals.

The anode 31 of the gas discharge tube 26 is connected via a conductor 32 in series with the winding of a relay 33 which has a movable contact 34 which can selectively touch either one or the other of two stationary contacts 35 and 36. The movable contact 34 is connected via a conductor 37 to an output terminal 38, while the contact 36 is connected via a conductor 39 to the movable contact 40 of a relay 41, which can be energized in a table value conversion system by a suitable timer, as shown in FIG will be described in detail below. The fixed contact 35 of the relay 33 is via a. Conductor 42 is connected to a stationary contact 43 of the relay 41, which is also connected to the negative terminal of the bias voltage source 23 by means of a conductor 44. A second stationary contact 45 of the relay 41 is connected to the positive terminal of the bias voltage source 23 and to the input line 13 via a conductor.

In the idle state, the gas discharge tube 26 is non-conductive, due to the negative. Pre-tensioning that is pressed onto the control grid 25 by the voltage source 23. The input voltage 13 which is to be measured is transmitted to the control grid 25 in series with the bias voltage source 23. If the bias voltage is greater than the voltage to be measured, the gas discharge tube 26 remains non-conductive, so that when the relay 41 is subsequently energized by the timer, the voltage to be measured is passed on to the next stage via a circuit; which runs from the input line 13 via the conductor 46, the relay contact 45, which interacts with the contact arm 40, conductor 39, relay contact 36, which interacts with the contact arm 34, and the conductor 37 to the output terminal 38.

However, if the voltage to be measured is greater than the preload, then the gas discharge tube 26 is conductive and the relay 33 responds. This has to The result is that the contact arm 34 leaves the contact 36 and relies on the contact 35 hangs up. In this case it becomes the difference between the voltage to be measured and the bias of the next stage transmitted through a circuit which runs from input line 13 through conductor 46, bias source 23, conductor 4.1. and 42, stationary contact 35, which cooperates with the movable contact arm 34, and conductor 37 to output terminal 38. The subsequent energization of relay 41 .by the timer does not affect this circuit in any way.

A typical digit conversion system employing a number of elements or components of the type shown in Fig. 3 is illustrated in Figs. Since in some cases the voltage to be evaluated changes extremely quickly, it is desirable to provide a selection circuit arrangement for measuring the instantaneous values of the voltage to be measured in the times shortly before the start of the successive conversion periods. A typical selection circuit arrangement 47 (FIG. 3) can consist of an ordinary electrical tube 14o with a control grid 141 connected to the input line 13, with a cathode 1 4 2 also being provided, which is connected via a resistor 1 Earth is at 48, as well as a screen 49 for the input line 15, which is also earthed via a conductor 50.

The tube i4o has, for example, an indirectly heated cathode and works as a cathode amplifier. For this purpose there is a resistor in the cathode circuit switched on so that the potential of the cathode follows that of the control grid. Its anode 51 is over a. Conductor 52 to the positive terminal of a suitable one Anode voltage B -1- switched on. The output from tube 140 is from its cathode i42 transmitted by means of a conductor 53 to a stationary contact 54 of a relay 56, which of. a movable contact arm 55 is touched.

A fixed capacitor 57 is provided between the movable contact arm 55 and ground; which is arranged to be charged by the output of the cathode 142 to a value which is proportional to the voltage to be measured when the relay 56 is energized to bring its movable contact 55 into contact with the stationary contact 54. The voltage thus impressed on the capacitor 57 is transmitted by means of a conductor 58 to the control grid 59 of a second electron tube 6o, the electrodes of which are shown in the same envelope as those of the tube 140 and which is also indirectly heated and connected as a cathode amplifier. The anode 61 of the tube 6o is connected to the positive terminal B -I- of the anode voltage source by means of the conductors 62 and 52, while the cathode 63 is connected to earth via a cathode resistor 64. At the end of each conversion period, the capacitor 57 is discharged to earth via a circuit with a resistor 65, a conductor 66, the contacts 81 f and 82 f of the timing relay 72 f and a conductor 154, as will be explained in detail below.

The selection of relay 56 is energized once at the beginning of a j Eden conversion period through a circuit, which one Mikroschä'lters 144 which normally contacts a fixed contact 115 from the positive KlemmeB the anode voltage source via conductors 52 and 78, -the movable contact arm 77, a Conductor i 18, a stationary contact 127 which is touched by a movable contact arm 129 of a relay 12o, a conductor 13o, the relay 56 and a resistor 145 runs to earth.

The microswitch 144 is activated by energizing the control relay 76 (Fig. 3 and 6) operated at the end of a conversion period, and the aforementioned circuit will. closed when; the microswitch contact arm 77 in its zero position later returns and then interacts with contact 115.

When energized, the relay 56 touches the contact arm 55 -the contact 54, whereby it is possible for the selection capacitor 57 to reach the output voltage to charge at the cathode 142 of the tube i4o.

At the moment in which the microswitch contact arm 77 in his Zero position, in which ground contact i 15 touches, returns, becomes electrical Energy via a parallel circuit with the iig and i2o relays connected in series in one branch and a capacitor 122 in one other branch, pressed on. Therefore, one end of the parallel circuit is connected to a conductor i 18 and the other is connected to earth through a resistor 121. While. the relay i2o de-energizes is, the selection relay 56 remains energized through the aforementioned circuit. The excitement of relay i2o causes relay 56 to drop out, which is the selection capacitor 57 of: the cathode 142 of the: tube 14o switches off. The excitation of the relay i ig has the consequence that its movable contact 125 with a stationary contact 123 comes into contact, so that the positive terminal B -I- of the anode voltage source : the conductors 52, 124 are connected to a conductor 74, whereby the actuation of the 7_eitschaltwerk to be described later is triggered.

The purpose of the capacitor i22 is to energize the relays iig and i2o delay until the selection capacitor 57 has had time to focus on the voltage to charge at the cathode 142 of the tube i4o. After the capacitor 157 becomes full has charged, it is charged by the cathode 142 by the response of the relay i2o and 56 shut off, its voltage being substantially constant throughout Conversion period remains.

The output of the tube 6o is continuously via a conductor 67 of the first of a number of digit conversion stages 68 a, 68 b, 68 c, 68 d, 68 e. 68 f and 68 g (Fig. 4) transmitted. In order to counteract the constant flow of current from the tube 6o, it is desirable to provide a suitable voltage source 69 in series with the conductor 67 as shown. In any specific digit conversion system, the number of counting levels depends on the degree of accuracy required. FIG. 4 shows a system with only seven levels: for example, it shows how it is necessary to have a response resp. To achieve a reproduction accuracy of about i%.

With the exception of the last stage 68g, the various counter stages are the same as the individual ones shown in FIG. Step, where corresponding parts have been given the corresponding reference numerals. The last stage 68g is different from. that in Fig. 2: shown in such a way that the relays which correspond to the relays 41 and 33 are omitted because they are not needed there. Furthermore, the movable contact 34 1 of the relay 33 f is connected to earth via a resistor 70, to which a capacitor 71 is connected in parallel. This prevents any increase in: the grid tensions, while: the movable ones. Contact arms of the relay: are in motion between the stationary contacts, thereby improving stability.

The relays 41 a, 41 b, 41 c, 41 d, 41 e and 41 f are arranged so that they are energized one after the other via suitable time switching means, which consists of a number of time relays 72: a, 72 b, 72 c, 72 d , 72 e and 72 f (Fig. 3) can exist. A terminal of the relay 72 a is on the conductor 73 a. and 74 are connected to the fixed contact 75 of the microswitch 144, which is normally touched by the moving contact 77, the latter being connected via the conductors 78 and 52 to: the positive terminal B + of the anode voltage source. As best seen in Figure 6, microswitch 144 is designed to be actuated by punch relay 76 when the latter is energized. The relay 72 a (Fig. 3) is also connected via a conductor 79 a via the winding of the relay 41 a (Fig. 4) and a resistor So a to earth (Fig. 3).

The relay 72a has a stationary contact 8i a, which is connected to the line 74 via a conductor 145 a. The contact 8i a is touched by a movable contact 82 a, which is connected to one output of the following relay 7! 2 b by means of a conductor 73 b. The other terminal of the relay 72 b is connected in series with the relay 4.1 b (Fig. 4.) and connected to earth (Fig. 3) via a resistor 8o b. In the same way, each of the remaining relays 72 c, 72 d, 72e and 72f is arranged in such a way that they are connected to the positive terminal B + of the anode voltage source via the contacts of the preceding relay and connected to ground via the corresponding relays 41 c, 41 d, 41 e and 41 f in the different counting stages (Fig. 4) and the resistors 8o c, 8o d, 8o e and 8o f in the timer (Fig. 3) are connected.

In the anode circuits of the various gas discharge tubes 26 a, 26 b, 26 c, 26 d, 26 e, 26 f and 26 g (FIG. 4) there is a number of relays 83 a, 83 b, 83 c, 83 d, 83 e , 83 f and 83 g (Fig. 5) switched on. All these relays except for relay 83 a, that is: relays 83 b, 83 c, 83 d, 83 e, 83 f and 83 g, have the same structure, so that it is only necessary to describe one in detail, whereby the corresponding parts of the rest are provided with corresponding reference numerals. The relay 83 b has a movable contact arm 84 b, which normally affects a fixed contact 85 b and is arranged so that it has a second. Contact 151 b can operate. The movable contact 84b is connected to a conductor gi while the contact b 151 via a conductor 99 b to a terminal b ioo a registration device is ioi turned on, which is a conventional Holllerith-card puncher can be.

The relay: 83 b is assigned a display circuit, which consists of a neon tube 96 b and a series resistor 97 b. This display circuit is excited by means of an electric circuit; which runs from the positive terminal B + of the anode voltage source via the conductors go and 89, resistor 97b, tube 96b, conductor gi, a movable contact 92 of a switching mechanism: 93, which interacts with a stationary contact 94, to earth 95. The relay contact 85 b is connected to a connection point between the resistor 97 b and the tube 96 b. Since the movable contact arm 84 b normally touches the contact 85 b, the Neom: lamp 96 b is short-circuited so that it does not light up. However, if the relay 83 b is energized, the movable contact arm 84 b leaves the contact 85 b, whereby the shunt = circuit is interrupted, so that when the contact 92 of the switching mechanism 93 is brought into contact with the stationary contact 94, the Neon lamp 96 b lights up.

The relay 83 a serves as a control to indicate that the to be evaluated Voltage has left the area, d. H. has risen above a predetermined value is that: is determined by the voltage source 23 a. For this purpose is the Head gi connected to a fixed relay contact 85 a, which normally is in contact with the contact arm 84 a, the latter via: the conductor 86 a and 116, the normally open contacts 113 and 114 on relay 76 (Fig. 3) and a conductor 117 is applied to the contact io2 on the hole punch ioi (FIG. 5).

As is therefore easy to see, if: the relay 83 e is not energized during a conversion period, one or more of the relays 83 b, 83 c, 83 d, 8-3 e, 83 f and 83 g are respond, by closing the contacts 113 and 114 when energizing the relay 76 connections between the punch terminal io2 and one or some of the terminals ioo b, ioo c, ioo d; ioo e, ioo f and ioog, for which a respective relay 83b, 83c, 83d, 83 e, 93f and 83g has been energized, is made, thereby actuating the punch ioi and causing it to punch holes in a card corresponding to the number to be registered to punch. If the relay 8.3 a has been energized, however, the opening of the contacts 84 a and 85 a makes impossible that the punch terminal i o2 connected to any of the terminals ioo b, ioo c, ioo d, ioo e, ioo f and ioo g. becomes, and the punch ioi therefore remains ineffective. If desired, can. the contact 151 a can be connected to a punch terminal ioo a via a conductor 99 a, "-which causes the punch ioi to register an X, for example, when the relay 76 is energized.

A display circuit with a resistor 97 a and a neon tube 96 a is provided between: the conductors 9i and 86 ca, and the latter conductor is connected to the conductor 89 via a resistor 8: 7 a, which prevents the keyhole circuit from being disturbed if that Relay. 83 a. is not aroused. Normally, the tube 96a is short-circuited by the actuated contacts 84a and 85a of the relay 83a. The excitation of the latter has the opening: the contacts result, whereby the tube 96 a ignites and indicates that the voltage to be evaluated has exceeded the range.

The actuation of the keyholeer ioi (FIG. 5) at the end of each conversion period can be effected by means of a relay 103 (FIG. 3) which is connected in series with the timing relay 72d. The relay 103 has a movable contact arm 104 which normally rests against a stationary contact 1 05 , but which can be brought into contact with a stationary grain clock. A capacitor io8 is provided between the movable contact arm 104 and ground io7. When the movable contact arm io4 is in contact with the contact io5 as shown in Fig. 3, the capacitor ioS is charged through a resistor iog and a conductor iio which leads to the positive terminal B T of the anode battery.

When relay io3 is energized, movable contact arm 104 leaves contact io5 and contacts contact io6, thereby applying the voltage on capacitor io8 to relay 76 via conductors iii and 112. The relay 76 is only fully energized after a certain time has elapsed which, by: the size of the capacitor io8 and the size of the inductance in the relay 76 is determined. The system is preferably dimensioned in such a way that the full excitation of the relay 76 is effected shortly after: the response of the timing relay 72 f. Furthermore, the capacitor io8 is of such a size that the time constant of the circuit containing it. and the windings of the relay 76, which keeps the latter closed for a long time in order to operate the keyhole roi.

The excitation of the relay 76 also has: the actuation of the microswitch 144 (Fig: 3 and 6) result, whereby his contact arm leaves the contact iti5 and with the contact 75, as already mentioned, is brought into contact.

At the beginning, the biases: which are caused by the voltage sources 23 a, 23 b, 23 c, 23 d, 23 e, 23 f and 23 g, are selected so that they are proportional to the successive power - In of 2, and in such a way that the last voltage source 23 g is approximately equal to: the noise level in the system and that the voltage source 23 a is proportional to the highest power of 2, which is required to convert the expected maximum number of voltage values, which are represented by a digit- or tabular value is to be expressed. In this manner, in a typical circuit arrangement of the voltage sources 23 a, 23 b, z3 c, 23 d, 23 e, f 23, and 23 g of bias voltages supplied ioo, 50, 25, 12.5, 6.2, 3 , 1 and 1.5 volts.

When the system is working, the one to be evaluated is: Voltage, namely the input power on conductor 13 (Fig. 3), always: the grid 141 of the pipe 140 transmitted so that the voltage on the cathode 142 is in a corresponding manner changes. Assume that the filaments of the tubes have warmed up and the anode voltage is transmitted to the system; then relay 56 is energized, namely via a circuit which runs from the positive terminal B -h the Anode voltage source via the conductors 52 and 78, the movable contact arm 7,7 of the microswitch 144, - which is applied to the stationary contact i 15, the conductor 118, . The stationary contact 127, on which the movable contact arm 129 of the relay i2o is applied, conductor 13o, relay 56 and resistor 145 to earth, whereby the relay 56 responds. This moves the movable contact arm 55 so that he meets the contact 54, whereby the capacitor 57 to the cathode 142 of the I4o tube is switched on. This is that. Select switching operation, and he has result, that a voltage is produced on the capacitor 57, which is proportional to the instantaneous value of the input voltage that: the pipe 140 is transmitted from the input conductor 13.

The voltage across the capacitor 57 is fed to the control grid 59 of the cathode tube 6o transmitted, whose output voltage at the cathode 63 is constantly on the conductor 67 and. the equalizing voltage source 69 to: the first counter stage 68 a (Fig. q.) is turned on.

When the input voltage to the first stage 68 a is greater than the bias voltage from the voltage source 23 a, the tube 26 a is conductive, whereby the relays 33 a (Fig. Q.) And 83 a (Fig. 5) are energized. As already mentioned, when the relay 83 a is energized, the circuits for actuating the punch ioi are interrupted, so that the latter is unable to perform a punching process, regardless of which of the relays 83 b, 83 c, 83 d, 83 e , 83 f and 83 g may be aroused later in the conversion period. This switching state corresponds to the overrange state.

At a given point in time, which is determined by the capacitor 122, for example 20 ms after the energization of the relay 56, the relays iig and 120 (FIG. 3) respond. When the latter relay is energized, contacts 127 and 129 open, causing relay 56 to drop out, so that the selection circuit process is interrupted. The voltage then present at the capacitor 57 remains essentially constant during the conversion period.

When the relay iig is energized, its contacts 125 and 123 are closed. As a result, the conductor 74 is connected to the positive terminal B + of the anode battery via the conductors 124 and 52, whereby both the first time relay 72 a and the relay 41 a, which is assigned to the gas discharge tube 26 a (Fig. Q.) , are excited, and at the same time anode voltage is applied to the gas discharge tubes 26 a, 26 b, 26 c, 26 d, 26 e, 26 f and 26 g.

If the input voltage to the first stage 68 a of the counter is less than the bias voltage caused by: the voltage source 23 a, none of the relays 33 a or 83 a is excited. As a result, when the relay is energized, q. i a the input power to the first stage 68 a passed without change to the input of the second stage 68 b.

If the input voltage to the second stage 68 b is greater than: the Vor: rvoltage, which is caused by the voltage source 23 b, the gas discharge tube 26 b is conductive, whereby the relays 33 b and 83 b (Fig. 5) are energized. By energizing the latter relay, a circuit to terminal ioo b of the punch ioi is prepared, so that when the circuit to terminal io2 is established when the punch relay 76 is actuated, a hole is made according to the arrangement of the terminal ioo b in a card is punched. Since the relay 33 b is excited, the difference between the input value to the second stage and the bias voltage, which is caused by the voltage source 23 b, is passed on to the input of the third stage, and the subsequent excitation of the relay 41 b by the timing relay 72 a has no effect.

On the other hand, if the input value to the second stage is less than the bias, which is caused by the voltage source 23 b, so speaks none of the relays 33 b and 83 b on, so that no perforation according to the position the terminal ioo b is punched through the punch ioi. It continues when aroused of the relay 41 b through the timing relay 72 a the input value to the second stage to Third stage input passed unchanged.

The input value to the first stage 68a is in this way given one after the other to the inputs of the following stages, either unchanged or reduced by the value of the bias voltage which is caused by any of the voltage sources, which is smaller than the size of the input value to the relevant one Step. Whenever one of the gas discharge tubes 26a, 26b, 26c, 26 d, 26 e, 26 f or 26 g has been made conductive, a circuit is made to the corresponding terminal i oo b, i oo c, i oo d, i oo e, i oo f or ioo g of the punch ioi produced, so that corresponding holes are made in a card by the latter when: the punching process is initiated.

The excitation of the timing relay 72 c during the time sequence causes both the timing relay 72 d and the relay 103 to be excited. When relay 103 responds, the voltage that has arisen across capacitor io8 is transmitted to relay 76. As indicated, the capacitor io8 causes a time delay which prevents the relay 76 from being fully energized before the last timing relay 72 f has been actuated. When the relay 72 f is energized, the contacts 8 1 f and 82 f are closed, whereby the conductor 66 is connected to earth and the selection capacitor 57 is discharged via the resistor 65.

A short time later the relay 76 is fully energized so that its movable contact arm 113 strikes the contact 114. This connects the terminal 102 of the punch ioi (Fig. 5) with the terminals ioo b, ioo c, ioo d, ioo e, ioo f and ioo g, for which relays 83b, 83c, 83d, 83e, 83f and 839 during the period of transformation have been excited so: that a. Hole process is effected and. Perforations according to the numerical value; to be registered must be punched into a card.

Upon actuation of the punch relay 76 of the micro switch is activated 144 (Fig. 3), whereby its contact arm 77 of contact 1 15 is separated. This interrupts the connection between the conductor 118 and the positive terminal B + of the anode voltage source, so that the relays ii 9 and 12o are de-energized. Due to the de-energization of the relay iig, the conductor 74 is separated from the conductor 52, but electrical energy is still temporarily supplied to the timing relay (FIG. 3) and the anodes of the gas discharge tubes in the various conversion stages (FIG. 4) by the microswitch contact arm; ; transmitted, which is now in operative connection with the contact 7-3 . De-energizing relay 120 prepares a circuit to select relay 56 which is established when microswitch 144 returns to its zero position at the end of the conversion period.

After the capacitor 108 is sufficiently discharged, the relay 76 is de-energized, whereby its contacts 113 and 114 open. At the same time the microswitch 144 is released so that its contact arm 77 leaves the contact 75 and strikes the contact 115. By opening the contacts 75 and 77, the anode voltage is separated from the time relays (FIG. 3) as well as from the gas discharge tubes in the various counter stages (FIG. 4). Hence the latter. non-conductive, so that each of the energized relays 33 a, 33 b, 33 C, 33 d, 33 e, 33 f and 33 g as well as 83 a, 83 b, 83 c, 83 d, 83 e, 83 f and 83 g ' returns to its normal de-energized zero position. The closing of the contacts 77 and 115 in turn energizes the selection relay 56, whereby a new selection process is initiated, whereupon the conversion process is repeated essentially in the manner described above.

The resistor 152 is parallel to the relay 56 and causes a time delay which is sufficient to ensure a complete de-energization of the last time relay 72 f before the relay 56 is energized, thereby avoiding a possible charging of the grid 59 of the tube 6o by means of the resistor 65 will.

A resistor i53 can be shunted to the last time relay 72 f (Fig. 3) so that the contacts on relay 41 f are given enough time to close and that the gas discharge tube 68 f ignites (when it is supposed to ignite ) before the relay contacts 81 f and 82 f (FIG. 3) close and the selection capacitor 57 discharges.

The relays 83 g, 83 for $ 3 e. 83 d, 83 c. 83 b and 83 a correspond to the successive powers of 2, whereby the relays 839 and 83a correspond to the zeroth and the sixth power. If, for example, the input voltage to the first counter stage 68 a (Fig. 4) is such that the relays 83 b and 83 d are to be actuated at the end of the conversion period, the first gas discharge tube 26 a does not ignite, but the entire input voltage becomes the second Stage 68 b forwarded. Here the input voltage is greater than the bias voltage which is supplied by the voltage source 23b, so that the gas discharge tube 26b ignites. As a result, the input voltage to the third stage 68 c is equal to the original input value - 50 volts, the bias voltage supplied by the voltage source z3 b. The input value to the third stage 68 c is not sufficient to ignite the gas discharge tube 26 c, but is passed on unchanged to the fourth stage 68 d. The fourth is btufeneingangswert in turn, so that the gas discharge tube 26 ignites d greater than the bias voltage supplied from the source 23 d. Therefore, the input value that is transmitted to the fifth stage is equal to the fourth stage input value -12.5 volts, that of the bias voltage, which is supplied by the voltage source23d. In the present case, the differential voltage (if any) is not sufficient to ignite any of the gas discharge tubes 26 e, 26 f and 26 ä.

The actual numerical value that is set in the punch ioi can be made visible by closing the switch 93. As a result, the lamps 96 a, 96 b, 96 c, 96 d, 96 e, 96 f or 96 g corresponding to the relays 83 a, 83 b, 83 c, 83 d. 83 e, 83 f and 83 g, as these are excited at the end of a transition period, are made to light up. Therefore, for the assumed case, the lamps 96 b and 96 d would light up according to the table values 32 and 8.

The system described above is a self-regulating, i.e. H. the time, The system itself determines in which evaluation and punching takes place. That System is preferably designed so that the self-control operation with a frequency which is determined by the fastest time with which the punch ioi can punch and advance. For a standard keyhole The usual type can be an automatic operating speed with one perforation per 89 ms regarded as satisfactory and easily achieved with the present system will. However, there is a faster working device for punching or other marking from table values available, the self-control work speed of the digit conversion system can be increased significantly.

Instead of using the self-steering conversion system described above, the circuit can also be operated at any speed by means of appropriate control devices be evoked. This can. be effected, for example, that the Lines to relay 103 short-circuited and lines i 16 and 117 (Fig. 3) be led to an alternating or periodic switching mechanism. It is not difficult understand that every time such a switching mechanism executes a closing movement, a punching process is effected and the device then switches to the next punching process adjusts itself again in essentially the manner described above.

As already stated, the digit conversion system according to the Invention can be used to register any values which are represented by a correspondingly changing electrical signal can be reproduced. For example, you can Curves of the technical literature by a conventional photo amplifier device or the like. be evaluated, the output voltage of the input line 13 (Fig. 3) of the Digit conversion system can be transmitted. In addition, the initial value of the system through other devices than through a card punch ioi (Fig. 5), which is only given as an example, evaluated or registered will.

From the above it is easy to see that the invention a new and extremely effective system for transforming the values of oneself changing size is created in numerical values, in which form it is then immediately, for example as perforations: @ in punch cards to be able to be registered. Means the new circuit arrangement of the type described above can have a very large number of data at high speed and in a very convenient manner for a subsequent one Evaluation of eyelids, other treatment, such as offsetting, correcting or for other statistical purposes. The circuit arrangement described above is also able to effectively change discontinuous values Register size.

As is easy to see, the embodiment described above can can be modified in various ways without d: aß the scope of the invention is left. For example, high vacuum tubes, which are in a so-called flip-flop circuit Od. The like. Are used in place of the gas discharge tubes 26a and so on. Transformers can also be used for this purpose.

Claims (13)

PATENT CLAIMS: i. Circuit arrangement or switching element for use in an electrical device to distinguish between electrical quantities above and below a predetermined value, characterized by a relay arrangement (26) and an associated electrical switching mechanism (33), which relay arrangement on an electrical input signal of a predetermined value responds and with the switching mechanism cooperates in such a way that the latter works when the input signal falls below the aforementioned value, this signal transmits without change, however when the input value is sufficiently large that the relay arrangement responds, .The switching mechanism is operated automatically in such a way that the difference between the input value and a low one characteristic of the switching element. value is transmitted. 2. Circuit arrangement according to claim i, characterized in that that the relay arrangement is an electron discharge tube (26), the grid (25) of which from a voltage source (23) receives such a bias that the pipe normally is non-conductive, and that the switching mechanism consists of an electromagnetic switching mechanism (33), which is excited by the anode current of the electron tube and its Contacts (35, 36) are arranged so that when the electrical input signal voltage sufficient to make the electron tube conductive, these contacts the input value of the unit to the output in such a way that the input signal voltage remains unchanged is passed to the output of the unit while then when this voltage exceeds the value that is necessary to make the electron tube conductive, the switching mechanism is excited and its contacts the grid of the electron tube switch on the output of the unit and thereby the differences between this output the input signal voltage and the grid bias. 3. Circuit arrangement according to claim 2, characterized in that a further electromagnetic switching mechanism (4i) is arranged to be energized by a timer (72a, etc.) and has stationary contacts (43, 45), each with the input (i3) of the unit and are connected to the control grid (25) of the electron discharge tube, and that the electromagnetic switching mechanism (33) from. Anode current of the electron tube (26) is actuated, a fixed front contact (35) on the control grid (25) of the electron discharge tube is switched on, and a stationary rear one Contact (36) has: the one with the movable contact (40) of the further switching mechanism (4i) is connected in such a way that when the first switching mechanism by the Electron tube current is excited, it the grid (25) of the electron discharge tube (26) to the output of the unit, but then, if it is not energized, if subsequently the further switching mechanism under the control of the timer is excited, it connects the input of the unit directly to the output and as a result, the input signal voltage is passed on unchanged to the output of the unit. 4. Circuit arrangement according to claim 2 or 3, characterized in that the grid bias (23) is chosen so that it corresponds to a given table value and a registration is made when the signal input voltage is sufficient to the electron discharge tube conductive to make. 5. Circuit arrangement according to claim 4, characterized in that a number of stages (68a., 68b, 68c u.sw.) is provided, each of which comprises one of the electrical units which are connected so that each stage behind the first receives an input signal consisting of the output value from the previous stage, the bias voltages (23a, 23b, etc.) being different in the successive stages and. are chosen so that they correspond to different table values. 6. Circuit arrangement according to claim 5, characterized., that the stages have -electric units of the type described in claim 3 and that electromagnetic switching mechanisms (4i a etc.) in .den successive Stages, which are energized by the timer, are operated in sequence. 7. Circuit arrangement according to claim 6, characterized by switching and control elements (i4o, 6o) which respond to electrical values which values of different sizes are the same or correspond to them; for transmitting an electrical signal, which corresponds to an instantaneous value of the variable variable, to the input of the first stage (68 a), the time switch mechanism (72 a, etc.) in a certain temporal relationship for reproducing the electrical signal for the purpose of successive actuation of the corresponding electromagnetic Switching mechanisms in each of the stages is triggered or operated. B. Circuit arrangement according to claim 7; characterized in that the biases (23 a etc.) in successive stages differ by a factor of a and correspond to the various two-digit values (geometric series values) and that an electrical selection device (56, 57), which the input value of the first Stage supplies, is arranged so that it periodically the first stage (68 a) signals transmitted, which is proportional to the instantaneous values of the variable transfer value (or in any other way indicative thereof) are, during a number of circuit preparatory Relays in the anode circuits of the electron discharge tubes of the various stages is provided. 9. Circuit arrangement according to claim 8, characterized by a number of switching mechanisms which are arranged so that they are actuated by the circuit preparing relay (8-3 ä), and by a card punch (i oi) which is provided with a number of circuits which are connected to the aforesaid switching mechanisms and are arranged in such a way that they: are prepared by actuating the switching mechanism by means of periodically effective control means (76, 103) in such a way that those of the punch circuits are established which are prepared, and thereby the Hole punch is operated. ok Circuit arrangement according to Claim 9, characterized characterized in that the switching means for producing the punch circuits relays (76, 103) are; which are controlled by the timer. i i. Circuit arrangement according to claim 6, characterized in that further electromagnetic switching mechanism e (83 a etc.), which by the anode currents of the electron discharge tubes (26a etc.) are excited in the respective stages, each are set up so that by an indicator (96 ca etc.) is operated. 12. Circuit arrangement according to claim 9, characterized in that the timer (72 f) is designed in such a way that it causes the cancellation of the signals that are transmitted to the first stage, and that when the relays (33 a, etc. ), which are controlled by the timer (72 a etc.), become ineffective again, a new signal is transmitted to the input of the first stage (68 a). 13. Circuit arrangement according to claim 6, characterized by an electrical selection device with a capacitor (57) which is arranged so that it is periodically charged to value levels which correspond to the values of the variable transfer value, and which is connected so that it periodically the first stage (68 a) transmits signals that are indicative of instantaneous values of the variable transmission value, and through a card punch (ioi), which has a number of circuits that are connected to electromagnetic switching mechanisms (83 a., 83 h, etc.), which from Anode current of the electron discharge tube of the corresponding stage are excited, turned on and. are arranged so that they are prepared in such a way by the actuation of these switching mechanisms and relays (103, 76), which are temporarily made effective by means of the timer (72 a, etc.) that those of the punch circuits which have been prepared, be produced, whereby the punch (ioi) is then operated, the timing mechanism being designed in such a way that the capacitor (57 is discharged in order to cancel the successive signals which are fed to the first stage, and that the capacitor (57 ) is brought back to a charge value that corresponds to a new value of the variable transmission value when the relays (83 a üsw.), which control the electromagnetic switching mechanisms, become ineffective, whereby a new signal is transmitted to the input of the first stage.