DE1212154B - Counter with adjustable counting capacity - Google Patents

Description

Counter with adjustable counting capacity The invention relates to a Counter with adjustable counting capacity X, which consists of a series of input pulses emits the Xth on the output side, especially for systems of control, monitoring and / or measurement technology. Such a counter can be built according to the block diagram according to FIG. 1 train.

The in F i g. 1 shown counter Z has three inputs and one Output: An "on" pulse applied to the first input e1 determines the beginning the counting of a pulse series pending at the second input e2. The one through the setting of the counter Z determined Xth pulse appears at output a and can, as in the Figure shown, via the third input e3 as an "off" pulse, the counter Z against further, block pulses fed to the second input e2. With such a counter you can For example, processes in packaging technology can be controlled in which a predetermined amount is to be counted and after counting a signal z. B. to Control of certain facilities is needed.

A counter is known in which bistable multivibrators form a binary divider are interconnected. For example, M = 256 needs for a maximum counting capacity eight flip-flops and an encoder with many diodes that make it possible to any desired counting capacity from X = 1 to 256 can be set. One of the "one" - and switches controlled by "off" pulses, which allow or block counting pulses must, is usually formed by a further trigger stage with a diode gate. A such a counter is relatively expensive and has a further disadvantage a constant, relatively large electricity demand.

It is also a magnetic core divider that works according to the counter core principle known. With this magnetic core divider, the output pulses of a first magnetic core the input winding of a second magnetic core that works according to the counting throttle principle supplied, which completely remagnetises after a certain number of supplied pulses is and by the resulting greater current flow through its input winding an output pulse causes the second magnetic core via a reset winding returns to the rest position.

Two such magnetic core divider stages can be added to the one shown in FIG. 2 interconnect the two-stage divider shown. In the first stage of this divider, stage Stl, the driver core K1 is remagnetized by a counting pulse at the counting input e. The secondary pulse of constant voltage-time integral arising at the output winding w3 of this driver core K1 reaches the counting winding i14 of the counting core K2 via the conductive diode D 1, the flow of which is thereby changed by a certain amount. An auxiliary pulse following the counting pulse sets the driver core K1 back to its starting position via the auxiliary winding w2. The secondary pulse is blocked by diode D1. The nth counting pulse brings the counting core K2 into saturation, so that the pulse supplied by the output winding w3 drops across the resistor R2, overcomes the bias voltage U "and thus makes the transistor Tsl conductive. This transistor Tsl sets the counting core K2 via the reset loop e, -a, back again and forwards the nth pulse as a counting pulse to the next stage, stage St2, which in turn only emits a pulse on the output side after n2 pulses.

With three levels, each up to the fixed counting capacity of one level, d. H. counting the step capacity »a = 8, one can count in this way a counting capacity Achieve M = 512. The arrangement only takes about a third of the effort a corresponding binary divider built with flip-flops is required. Also the power consumption is much lower. The disadvantage, however, is that the counting capacity is not without further adjustable within wider limits. The magnetic core divider is with it for many applications that require adjustability, e.g. B. when counting of piece goods, in time division multiplex transmissions and in control technology, not readily suitable.

The object of the invention is therefore to provide a counter whose Counting capacity to any whole number between specified limits can be set.

According to the invention, the counter includes two types of cascaded ones Counting levels that are individually based on each integer level capacity x between the value 1 and an upper value m can be set, and from which one Kind as an adder of the impulses applied to their input the last one set number x1 and all following can go to the next level, and the other type as a multiplier of the impulses entering them only in each case sends the last of a further set number x2 on the output side. Here you can the set numbers x1 and x2 also be the same.

These measures have the advantage that adjustable counters, especially high counting capacity, can be realized with much less effort can be better known than is the case with various adjustable dividers used as counters Kind of is the case.

In a further embodiment of the invention, the counting stages are as Magnetic core dividers designed according to the counting core principle, their driver core for setting the counting capacity as a secondary winding in each case switchable partial windings, in particular same number of turns.

The counting stages can also be used as magnetic core dividers according to the counting core principle are formed, the counting core for setting the counting capacitance as a primary winding each switchable partial windings, in particular the same number of turns, carries. The setting of the counting capacity of one and the same magnetic core divider can be used be made in that both the secondary number of turns of the driver core as well as the number of primary turns of the counter core is varied. It's an advantage such a counter that without the additional expense of logic elements and with a relatively small number of stages, one setting of the counting capacity in one very large area is possible.

It is advisable to use special, series-connected windings each from the output pulse of the counter postpone. The multiplier levels reset themselves, z. B. by the fact that the counting core of each multiplier stage with its own (x-th) Output pulse is applied. An advantage of this arrangement is that associated with it quick readiness to count.

In a further development of the invention, the adding and multiplying stages arranged in the chain circuit of the counter in such a way that they alternate with one another follow. This has the major advantage that the counter with a minimum can be realized in steps. The effort for the individual Reduce the stages even further by making the multiplier stages optional can only be set to the values x = 1 or x = m.

An equal structure of all stages is made possible by the fact that all Counting stages of the counter have the same maximum stage capacity m.

It is also useful to insert a switching stage in front of the counting stages, which can be controlled in such a way that the counting pulses applied to the input are only received after they have been received of an "on" pulse is allowed through and blocked when an "off" pulse is received will. The "off" pulse can be formed by the output pulse of the counter will. The "on" pulse can also be activated at the same time as the switch is switched on reset the counting cores of all counting levels and thus, for example, as a synchronization pulse Cancel previous, incomplete counts. By applying these measures the counter is suitable for counting, signaling when a certain value is exceeded Limit or the like with the advantageous use of the counter as an analog-to-digital converter z. B. the "on" pulse is expediently when a certain value is exceeded Voltage threshold formed.

The switching stage before the counting stages can also be a transfluxor included, with the Transfluxor advantageously at the same time as a switch and Driver core is usable. The Transfluxor is particularly useful as a magnetic component adapt well to the magnetic core divider. In addition, it has no permanent power requirement.

The output circuit of the transfluxor and the driver cores of all counting levels can each have two primary windings, one of which is the counting effective Receives input pulses and the others are all connected in series and resetting auxiliary pulses received, which are opposite to the counting pulses at the counter input are staggered in time. The associated joint control of all divider stages is made possible with little effort and requires little performance.

You can also train the counter in such a way that the output pulse is taken directly from the adder, so that the counter cores of the adder from Output pulse cannot be reset, and that the counting cores of the multiplier stages have special, series-connected windings that control the counter core when it occurs of output pulses in each case in the saturation reached after counting. Since there is no resetting after counting is complete, such a counter is effective in total as an adder stage.

The counter can be used advantageously in monitoring devices in wide area technology. An electronic remote control for monitoring wide area systems, for example, connects many substations with the control centers via a common transmission channel. A substation may only transmit on this channel if it has received the Xth pulse assigned to it from a series of call pulses. To do this, each station needs a counter that can easily, with little effort, e.g. B. should be adjustable from X = 1 to X = 200.

The invention is illustrated by means of the FIG. 2 illustrated magnetic core divider and on the basis of the FIGS. 3 to 6 illustrated embodiments shown in more detail.

F i g. 1 shows a block diagram of an adjustable divider; F. i g. Fig. 2 shows a magnetic core divider with two stages; F i g. 3 shows a block diagram of the meter according to the invention; F i g. 4 shows a three-stage counter; F i g. 5 shows the scheme of a decade adjustable counter with the maximum counting capacity 9999; F i g. 6 shows a preferred switch and counter core arrangement in the decadic adjustable counter. In Fig. 2 is, as partially already explained at the beginning, a counter is shown, which consists of two magnetic core divider stages Stl and St2, which work according to the so-called counter core principle. Both stages are Stl and St2 constructed in the same way. Corresponding parts are labeled in the same way.

The magnetic core divider stage St 1 or St2 contains the driver core K1 and the counter core K2. The input ex of the stages Stl and St2 is led via the winding wl of the driver core K1 and the resistor R1 connected in series to the negative pole of the voltage source B 1, the connection b 1 with the potential - UB. The output winding w3 of the driver core K1 is connected on one side via the diode D 1 and on the other side via the resistor R2 to the counting winding w4 of the counting core K2. The base of the transistor Tsl is located at the connection point between the counting winding w4 and the resistor R 2. The emitter of the transistor Tsl is connected to earth, its collector via the output az and the terminal it is led to another winding 11.5 of the counting core K2. The other end of this winding w5 is connected to terminal a, .. The driver core K1 also has the auxiliary winding w2, to which auxiliary pulses are applied to reset the driver core K1 to the starting position.

The two magnetic core divider stages Stl and St2 are connected in a chain. The emitters of the transistors Tsl are jointly connected to earth, to which the positive pole of the voltage source B1 and the negative pole of the further voltage source B2 are also connected. The connection point of the resistor R2 with the driver winding u! 3 is in each case on the positive terminal b2 of the voltage source B2. The resistors R1 are common to the connection b1. The auxiliary windings 14.2 of the driver cores K1 are connected in series in that the auxiliary pulse output ah of the first magnetic core divider stage Stl is connected to the auxiliary pulse input eij of the second stage St2. The output winding w5 of the counting core K2 of the first stage Stl is via the terminal a ,. this stage St l and the input e, the second stage St2 and from there via the resistor R1 of that stage St2 to the terminal b1. The load resistor R6 is located between the output winding w5 of the counter core K2 of the second stage St2 and the connection b1. The auxiliary winding w2 is connected to the terminal b 1 via the auxiliary pulse output ah and the resistor R5.

This in FIG. The divider shown in 2 is only for a fixed one Divider ratio suitable.

The one shown in FIG. 3 counter according to the invention consists of the input-side switching stage S and the series-connected counting stages A, B, C, D, E, of which the first, third and fifth counting stages, ie the counting stages A, C and E, as adding stages, and the second and fourth counting stages, ie the counting stages B and D, are designed as multiplier stages.

Switching stage S lets through all counting pulses that follow an "on" pulse at input e1. The auxiliary pulses indeed have no counting function, run continuously from further input e4 through all the steps and through the resistor R5 to the negative pole of the voltage source B1, ie the terminal b 1. Zählkerne the adder A, C and E are only the X- th output pulse is reset, which also opens the switching stage S again at the same time. The multipliers B and D, on the other hand, reset themselves when they emit their own output pulse. In contrast to the adding stages A, C and E, whose stage capacities x can be set to all values between the limits 1 and m, the multiplying stages B and D can only be set to counting capacities x of size 1 or m .

This simply structured counter can be set to all integers between the value 1 and the third power of the maximum step capacity in. When the counter is set to the counting capacity X , the adding stages A, C, E only contribute to the counting capacity X according to their stage capacity x if all the following stages are set to the value 1; otherwise the contribution of the respective adder stage is reduced by one unit. So z. B. in the case of a number that is less than or at most equal to the maximum step capacity m, the first step A is set to the counting capacity X, and all following steps B, C, D, E are set to the value 1.

If, on the other hand, the counting capacity X to be set lies in the range between the maximum step capacity m and the second power of the maximum step capacity m, then in addition to adding stage A, multiplier stage B and adding stage C are set to values that deviate from the value 1. The adding stage A therefore does not contribute to the counting capacity X according to its stage capacity x, but must be set to a value that is one unit higher.

For a counting capacity X = 4 - [- 3 - 5, z. B. as step capacity , y for level A the value 5 and for level B the value 3. the Level C receives setting 5, since levels D and E, i.e. H. for all following stages, the stage capacity results in 1.

If the value 10 is selected as the maximum step capacity m for each of the multiplier stages B and D , a counting method is obtained which corresponds to that of the decadic number system.

If in the counter according to FIG. 3 the switching stage S is not opened by the output pulse, the counter works as a divider; that is, with the pulse repetition frequency f on the input side, the frequency f: X is obtained at the output, so that an unknown frequency f, which is a multiple of the output frequency, can be measured or set by determining the output frequency.

In a further application, the counting pulses applied to switching stage S at input e2 are fed to a device under test, which they e.g. B. deformed with increasing number of pulses. A measuring device controlling the test object sends the "off" pulse to switching stage S when the deformation at pulse y exceeds a limit value. If the counter is set to the value X, it is easy to signal whether y <X or > X , since the counter does not give an output pulse one time and the other time the output pulse. With two counters that work in parallel and are set to X1 and X2, you can check whether y is within the limits of X and X2.

The F i g. 4 shows a counter with three magnetic core divider stages. The counter then contains, besides the switching stage S which between themselves like adders A, C and the multiplier B. The adder stages are each set with the preferably constructed as a rotary switch with two levels Sch l and Sch 2 switches on one of the values 1 to. 6 Solder bridges or the like can also be used instead of the switch.

The switching stage S is located at the input of the counter. The one in it The included Transfluxor Tfl is provided with the windings w11 to w15. For controlling of the transfluxor Tfl are the transistors Ts11, Ts12 and Ts13, their emitters are connected to each other and connected to earth.

Each of the counter inputs e1, e2 and e4 is led via a resistor to the base of one of the transistors Ts 11, Ts 12, Ts 13, namely the input e 1 for the "on" pulse via the resistor R14 to the transistor Tsll, furthermore the input e2 for the counting pulses via the resistor R15 to the transistor Ts12 and finally the input e4 for the auxiliary pulses via the resistor R16 to the transistor Ts13. On the base side, the transistor Tsll is led via the resistor R19, the transistor Ts12 via the resistor R17 and the transistor Ts13 via the resistor R19 to the terminal b2 with the voltage U i.

The adder A contains the driver core K3 and the counter core K4. The input winding w 16 of the driver core K3 is led on one side to the collector of the transistor Ts14 and on the other side via the resistor R20 to the connection b1 with the potential -U $. The output winding w17 of the driver core K3 and the input winding w23 of the counter core K4 are connected to one another via the diode D2. Both windings w17 and w23 are provided with taps so that they each consist of several partial windings connected in series. Of the two partial windings w18, w19 of the secondary winding w17, both partial windings w18, w19, and with the switch positions 5 to 6 only the partial winding w19 between the one pole of the diode D2 and the connection b2 are connected to the switch level Sch 1 in the switch positions 1 to 4 placed with the potential + Uv. In switch position 1, switch level Sch2 places partial winding w29, in switch position 2 also partial winding w28, in switch positions 3 and 6 the partial windings w26 to w29, in switch position 4 the partial windings w24 to w29 and in switch position 5 the partial windings w27 to w29 of the primary winding w23 between the other pole of the diode and the resistor R21, the other end of which is connected to the base of the transistor Ts15 and via the further resistor R22 to the terminal b2.

The other adder stage C is constructed in the same way. Same Parts have the same names.

The multiplier B is essentially constructed in the same way as the adder A and C. The corresponding part of the multiplier B only differs from the above-described part of the adder A insofar as in the switch levels Sch 1 and Sch2 of the multiplier B only the switch positions 1 and 6 belonging contacts and partial windings are connected. These unconnected contacts and partial windings, which can also be omitted, are not shown in more detail in the figure.

To interconnect the switching stage S and the counting stages A, B, C, the winding w11 of the transfluxor Tfl is connected to the connection b1 via the series-connected windings w22 of the counting cores K4 of all stages A, B, C and the resistor R23. The other end of the winding w11 is connected to the collector of the transistor Tsll.

The collector of the transistor Ts12 is connected to the terminal b1 via the winding w13 of the transfluxor Tfl and the resistor R11 connected in series. The collector of the transistor Ts13 is connected via the winding w14 of the transfluxor Tfl and the series-connected windings w20 of the driver cores K3 to the contact of the switch position 2 of the switch level Sch2 of the last stage. The base of the transistor Ts14 grounded on the emitter side is led on the one hand via the resistor R13 and on the other hand via the resistor R12 and the winding w15 of the transfluxor Tfl connected in series to the connection b2. The collector of the transistor Ts14 is connected to the terminal b1 via the winding w16 of the driver core K3 and the resistor R20 of the adder stage A.

The output a of the counter is connected to the connection b 1 via the resistor R 10. The collector of the transistor Tsll is connected to the terminal b1 via the winding w11 of the transfluxor Tfl and the windings w22 of the counting cores K4 of all stages and the resistor R23.

The transistor Ts14 of the switching stage S and the transistors Ts15 of all stages with the exception of the last stage, ie stages A and B, are connected to the terminal b 1 on the collector side via the winding w16 of the driver core K3 and the resistor R20 of the following stage. In contrast, the collector of the transistor Ts15 of the last stage C is led to the output a of the counter via the windings w21 of the counter cores K4 of all the adder stages A and C and via the winding w12 of the transfluxor Tfl.

If one adds the counter according to FIG. 3 through a further multiplier stage D constructed like stage B and a further adder stage D constructed like stage C, the extended counter can be set between the limits X = 1 and M = 251 .

The step capacity x results from the ratio of the number of turns of windings w23 and w17. It is always greater than the ratio of the number of turns of these windings w23 and w17, as part of the voltage output by the driver core K3 drops at the resistors R21 and R22 and therefore not at the counter core K4 for magnetization is available. From a manufacturing point of view, it is expedient for the cores to have the same windings To wind number of turns as parallel wires.

In the multiplier stages, e.g. B. at level B, only the settings are x = 1 or x = 6 provided. It is an advantage of the meter that it is largely made up same components, namely from magnetic core divider stages with the maximum counting capacity m = 6 can be put together and at the same time it allows any values below the to set the maximum counting capacity M of the counter.

The Transfluxor Tfl provided in switching stage S offers essential Advantages: It does not need a quiescent current and switches very safely. In addition, is it can be produced with little effort.

The transfluxor Tfl is set with an “on” pulse which reaches the setting winding w 11 via the collector-emitter path of the transistor Tsll. At the same time, all counting cores K4 are returned to their starting position. The counting pulses arriving at the transffuxor winding w13 via the emitter-collector path of the further transistor Ts12 magnetize the output hole of the transfluxor Tfl so that the transistor Ts14 conducts and passes the counting pulses on to the first counting stage A. The auxiliary pulse following each counting pulse is amplified in the transistor Ts13 and magnetizes the exit hole of the transfluxor Tfl again and at the same time also sets all driver cores K3 back to their original position. The Xth output pulse of the counter sets the counter cores K4 of the adding stages A, C, E to the starting position and blocks the Trans- $ uxor Tfl. Further counting pulses are ineffective because they are no longer transmitted on transistor Ts14.

A new "on" pulse is required to start counting again. This usually finds counting cores K4 that have already been brought into the starting position, because those of the addition stages A, C, E were reset by the output pulse and those of the multiplier stages B, D reset themselves. However, there are also operating cases in which the Transfluxor Tfl is blocked by another winding before the counter emits the output pulse. Then the "on" pulse must first set the correct starting position for all counting cores K4.

The one shown in FIG. 4 is particularly suitable for monitoring devices in long-distance technology, as it requires little electricity.

In FIG. 5 is the scheme of a decadic adjustable counter which can be set to the values 1 to 9999, whereby the set Counting capacity can be read directly from the switches of the decades. All counting levels A to G of this counter are dimensioned for the value 10 of the maximum step capacity m.

The switching stage S is arranged in front of the counting stages A to G. This switching stage is supplied with "on" pulses via input e1, counting pulses via the further input e2 and an "off" pulse from output A of the counter via input e3 after counting is complete.

The first digit (one) of a decade number is set with the switch Se , the effective switching level of which is determined by the relay contact z.

To set the further decades, two counting levels are required, namely a multiplier and an adder are provided. They are used for setting the tens the levels B and C, for setting the hundreds the levels D and E and to set the thousands the levels Fund G.

The last of the series-connected counting stages, the adding stage G, gives the Xth pulse of the counting pulses applied to input e2 at output a of the counter away. This output pulse also reaches the further input e3 of the switching stage S.

The adder controls G T via the relay by means of contact t the switching of the switch Slz the adder E. also controls via the relay H is the switching of the switch Sz of the adder C and via the relay Z switching of the switch Se of the further adder stage A. The adder E controls the relays H and Z, the adder C only the Z relay.

F i g. 6 shows a switch and counter core arrangement of a decadic adjustable counter according to the one shown in FIG. 5 shown scheme. The counter core windings w23 of the adder stages A, C, E, G of this counter are provided with taps 1 to 10 for setting all ten values of the stage capacitance x, each with one of ten contacts assigned to positions 0 to 9 of the switch two levels Schl, Sch2 are connected, that in the one level Sch 1, in which the contacts of the positions 0 and 1 are connected to each other, the contacts of the positions 1 to 9 on the same, in the other level Sch2 the contacts of the positions 0 to 9 are due to the taps that are 1 higher in number. In each case a multiplier and the subsequent adder are also, as shown in FIG. 5 already explained in more detail, combined into a decade. Each decade, with the exception of the first decade, contains a relay Z, H or T, which the switch of the adder stage C, E or G switches on in each case to positions 1 to 9 with the third level Sch 3 , and that when responding with a contact switches the stage capacity of the multiplier stage B, D or F of the same decade from 1 to 10. With a second contact it also switches in the adder stage A, C or E of the previous decade from one level Sch 1 of the switch to the other level Sch2. The relays Z, H and T of the individual decades are connected to one another via the rectifiers D3 and D4 in such a way that the switch of a decade in positions 1 to 9 causes all relays Z, H and T of the previous decades to respond.

Instead of the rectifiers D 3, D 4, contacts of the relays Z, H, T can also be used.

The counter core windings w23 each have eleven connections: the beginning of the winding and ten taps, which are formed by nine taps and the end of the winding. Rotary switches with several levels, namely the levels Sch 1, Sch 2 and Sch 3, are used as switches, with which the counter can easily be set according to a decadic sequence of numbers.

The first decade of the in Fig. 6 partially shown decadically adjustable counter contains only the adder A. It is advisable to connect the third level Schi of the switch of this adder A with the break contacts of the relays of all subsequent decades in series and the controllable switching step S upstream of the counting steps with the switch of the first To keep adder A locked in the zero position. This means that the switching stage which is at the beginning before the counter stage is blocked when the counter is set to the value 0. The switch position and the counting capacity correspond to one another even if the counter is set to the value 0.

The largest counting capacity of the counter according to FIG. 6 would be M = 10 999. The values X = 10,000 to 10,999 can be set if the switch is set to level G another position "10" is assigned, which is connected to the last tap of the counter core is.

One of the described counters is suitable for multiplying in that the counting pulses enter p parallel counters which can be set to different capacities (X, to Xp), and that the output pulses of all counters are passed via an AND gate in such a way that whose output a pulse occurs only when pulses are applied to all counter outputs at the same time. The counter can be designed in such a way that a common input switch is followed by two counter capacities X and X -i-1 which are adjustable by the amount 1 and which work in parallel and whose outputs via the AND gate only after X (X + 1) pulses generate the output pulse, which also blocks the input switch.

Claims (13)

Claims: 1. Counter with adjustable counting capacity, which emits the Xth impulse as an output impulse from a series of input impulses, especially for systems of control, monitoring and / or measuring technology of switched counting stages (A, B, C, D, E), which can be set individually to each whole-number stage capacity (x) between the value 1 and an upper value (m), and one of which is an addition stage (A, C , E) of the impulses applied to their input (ez or e2) allows the last of a set number (x1) and all subsequent ones to pass into the next level, and the other type as a multiplier level (B, D) of those entering them Pulses only emits the last of a further set number (x2) on the output side. 2. Counter according to claim 1, characterized in that the counting stages (A, B, C, D, E) are designed as magnetic core dividers according to the counting core principle, their driver core (K3) for setting the counting capacity as a secondary winding (w17) each switchable partial windings ( w18, w19), in particular with the same number of turns. 3. Counter according to claim 1 or 2, characterized in that the counting stages (A, B, C, D, E) are designed as magnetic core dividers according to the counting core principle, the counting core (K4) for setting the counting capacity as a primary winding (w23) in each case switchable partial windings (w24 to w29), in particular with the same number of turns. 4. Counter according to one of claims 1 to 3, characterized in that the Counting cores (K4) of the adding stages (A, C, E) via special, series-connected windings (w21) can be reset by the output pulse of the counter. 5. Counter according to one of claims 1 to 4, characterized in that the adding and multiplying stages (A, B, C, D, E) are arranged in the chain circuit of the counter in such a way that they follow one another alternately. 6. Counter according to one of claims 1 to 5, characterized in that the multiplier stages (B, D) can only be set to the values x = 1 or x = m . 7. Counter according to one of claims 1 to 6, characterized in that all counting stages (A, B, C, D, E) of the counter have the same maximum stage capacity (m). B. Counter according to one of the claims 1 to 7, characterized in that a switching stage (S) is inserted in front of the counting stages (A, B, C, D, E) which can be controlled so that the counting pulses applied to the input only after receipt of a "On" pulse allowed through and blocked when an "Off" pulse is received. 9. Counter after Claim 8, characterized in that the switching stage preceding the counting stages (S) contains a transfluxor (Tfo. 10. Counter according to claim 9, characterized in that the output circuit of the transfluxor (Tfl) and the driver cores (K3) of all counting stages (A, B, C, D, E) each have two primary windings (w16, w20), of which the one primary winding (w16) receives the counting effective input pulses and the other primary windings (w20) are all connected in series and receive auxiliary pulses that are offset in time compared to the counting pulses at the counter input (e2). 11. Counter according to one of claims 1 to 10, characterized in that all counting stages (A, B, C, D, E) are dimensioned for the value 10 of the maximum stage capacitance (m), and that the counting core windings (w23) of the adding stages for setting all ten values of the step capacitance (x) are provided with taps 1 to 10, each of which is connected to one of ten contacts on two levels (Schl, Sch2) assigned to the positions 0 to 9 of a switch, that in one Level (Schl), in which the contacts of positions 0 and 1 are connected to each other, the contacts of positions 1 to 9 to the same name, in the other level (Sch2) the contacts of positions 0 to 9 to those in the number around 1 higher taps, and that a multiplier and the subsequent adder stage are combined to form a decade, and that each decade contains a relay (Z, H, T) which the switch of the adder stage (A, C, E) is set to Positions 1 to 9 with a third level (Sch3) switches on, and that when one contact responds, the stage capacitance of the multiplier stage (B, D) of the same decade switches from 1 to 10 and, with a second contact, also switches from one level (A, C) to the adder stage (A, C) of the previous decade ( Schl) of the switch switches to the other level (Scla2), and that the relays (Z, H, T) of the individual decades are connected to one another via rectifiers (D3, D4) or their own contacts in such a way that the switch of one decade is in each case at the Positions 1 to 9 trigger all relays (Z, H, T) of the previous decades. 12. Counter according to one of claims 1 to 11, characterized in that the first decade of the counter contains only one adder (A), in which the third level (Sch3) of the switch with normally closed contacts of the relays (Z, H, T) of all the following decades is connected in series, and that the switch of the first adding stage (A) in the zero position holds the controllable switching stage (S) in front of the counting stages (A ... G) blocked. 13. Counter according to one of claims 1 to 3 or 5 to 12, characterized in that the output pulse is taken directly from the adding stages (A, C, E, G) so that the counting cores (K4) of the adding stages (A, C, E, G) are not reset by the output pulse, and that the counting cores (K4) of the multiplier stages ( B, D, F) have special, series-connected windings that keep the counting core in the saturation reached after counting when output pulses occur .