DE1219980B - Magneitian pulse counter - Google Patents

Description

Magnetic pulse counter The invention relates to a magnetic one Pulse counter (circuit arrangement for magnetic pulse counting), the core of which is a essentially rectangular hysteresis loop (characteristic) and through a predetermined plurality of input pulses from a first state of the magnetic Saturation in a plurality of steps in the state of the opposite magnetic Saturation is driven, whereupon an output pulse is generated.

As a result of their simplicity and long life, they have magnetic Pulse counters the bistable multivibrators previously used for this purpose as well as the circuits that work with charge and discharge of capacitors, largely displaced. However, they have the disadvantage that the counted number of pulses is limited; it is a maximum of about sixteen. Should a larger number of Pulses are counted, so it is necessary to have a plurality of counting stages to be provided.

The invention is based on the object of creating a magnetic pulse counter which is capable of counting a larger number of pulses, for example 29 pulses, in one stage, which was previously not possible. Despite the increased number of pulses, the pulse counter should work reliably and be usable within a larger temperature range than was possible with previous pulse counters with a smaller number of pulses.

The essence of the invention is that at least two cores or Core parts are used, which have a different characteristic from each other and which are acted upon simultaneously by the input pulses, the characteristics are chosen so that the steep rise of the individual curves at different Set so that first one core and then the other core step by step is driven to saturation.

In a not previously published, older invention (German patent 1165 662) a magnetic pulse counter is proposed in which a chain of magnetic cores reversible at different field strength values is used as a multistable storage element, via which a current flow is initiated with each counting pulse, the pulse counter in such a way is designed so that when one of these cores is reversed, the current flow via the chain is switched off and switched on in the reverse direction to such an extent that all cores previously reversed at lower field strength values are returned to their initial state. This proposal differs from the invention in that the individual cores are not driven by a predetermined plurality of input pulses in several steps from a first state of magnetic saturation to the state of opposite magnetic saturation, whereupon an output pulse is triggered, but that the magnetization each in a single step. In contrast to the invention, in the case of the aforementioned proposal, when one of the nodes is reversed, the current flow via the chain is switched off and switched on in the opposite direction to such an extent that all cores previously reversed at lower field strength values are returned to their initial state. In effect, it is a multi-stage pulse counter, the stages of which consist of individual cores that can be reversed for different field strength values.

Some embodiments of the invention are in the drawings shown.

F i g. Fig. 1 shows the circuit of a magnetic pulse counter of the previously known type; F i g. Fig. 2 is a schematic perspective view of the same pulse counter; F i g. 3 shows the hysteresis loop of this pulse counter for a pulse number of ten to be counted; F i g. Fig. 4 is a similar illustration; it shows the relationships that would result if one wanted to count twenty-five pulses with the same pulse counter; Fig. 5 is a schematic perspective view of a first embodiment of a pulse counter according to the invention; F i g. 6 is a cross-section along 6-6 of FIG . 5; F i g. 7 is a table illustrating the relative magnetic properties of the "Ortlionics" and "Molybdenum Pennalloy"materials; F i g. 8 is a table showing the relative magnetic properties of the none of FIGS. 5 illustrates; F i g. 9 shows the hysteresis loop of the cores of FIG. 5 for a number of pulses to be counted of twenty-six; F i g. 10 is a table showing the values of the component parts of a pulse counter according to FIG. Fig. 5 shows when the number of pulses to be counted is thirty; 11 shows a schematic perspective view of a second embodiment of a pulse counter according to the invention; F i g. Figure 12 is a table illustrating the relative magnetic properties of the cores of Figure 11; F i g. 13 shows the hysteresis loops for the cores according to FIG. 11, the number of pulses to be counted being thirty; 14 is a table showing the values of the component parts of a pulse counter of FIG . 11 indicates the number of pulses to be counted being thirty; Fig. 15 is a schematic perspective view of a third embodiment of a pulse counter according to the invention; F i g. 16 is a schematic perspective view of a fourth embodiment of a pulse counter according to the invention; Figure 17 is a cross-section along 17-17 of Figure 17. 16; F i g. 18 is a table showing the relative magnetic properties of the cores of a pulse counter of FIG . 16 illustrates; 19 shows the hysteresis loop for the nuclei according to FIG . 16; Fig. 20 is a table showing the values of the constituent parts of a pulse counter shown in Fig. 16 , the number of pulses to be counted being thirty; F i g. Figure 21 is a schematic perspective view of a fifth embodiment of a pulse counter according to the invention; Figure 22 is a cross-section on 22-22 of Figure 21; F i g. 23 is a schematic perspective view of a sixth embodiment of a pulse counter according to the invention; Figure 24 is a cross-section along 24-24 of Figure . 23; F i g. 25 is a schematic perspective view of a seventh embodiment of a pulse counter according to the invention; Fig. 26 is a similar view of an eighth embodiment of a pulse counter according to the invention; F i g. 27 shows the hysteresis loops for the cores of FIG. 25th

The invention is not limited to the embodiments shown only as examples limited, but also extends to modifications and combinations of these Embodiments that are within the scope of the inventive concept presented.

In Fig. 1 and 2 the previously known pulse counter is shown. He is described under the name "Incremag" in the United States in trade and USA. Patent 2,897,380. The counter has an input terminal 110, an output terminal 111 and an earth terminal 112. Power is supplied by a battery or the like, which is denoted by the reference symbol V. The heart of the counter is a saturable inductor core assembly 115 with an input winding 116, an output winding 117, a trip winding 118 and a reset winding 119; these windings are wound on a No 120. A transistor 122 having a base b, an emitter e and a collector c is connected in such a way that its input circuit is connected in parallel with the trigger winding 118 and its output circuit in series with the reset winding 119.

F i g. FIG. 2 shows a schematic perspective view of the cable 120 with the windings 116 to 119. The FIG. Windings 116 to 119 are shown, 2 parts of a single coil; It goes without saying that windings 116 to 119 which are independent of one another and which are wound on the core 120 can also be used instead.

The material of the core 120 is selected such that it is gradually brought from the state of negative saturation to the state of positive saturation by the pulses applied to the input winding 116. Was when a predetermined number of input pulses (as determined by the volt-second content) applied to the input winding, the saturation of the core is exceeded, d. i.e. the core is in its working position; as soon as the last pulse ceases, the sudden disappearance of the excess flux in the trigger coil 118 induces a voltage of such a direction that the transistor 122 becomes conductive. The resulting current flow in the reset winding 119 induces a voltage in the release winding 118 , which causes the current flow in the output circuit of the transistor to continue until the negative saturation of the core is reached, i. that is, until the none is in its rest position. When the zero is transferred from positive saturation to negative saturation, an output signal is induced in output winding 117 , which is applied to output terminal 111 . When the core has reached negative saturation, it is ready to accept a new series of input pulses.

In order to prevent the transistor 122 from becoming conductive as a result of the small changes in the magnetic flux which occur at the end of each stage, a damping resistor 123 is connected in parallel with the reset winding 119. In order to limit the base current of the transistor at the high voltage induced in the trigger winding, a series resistor 124 is provided. Furthermore, a small resistor 125 is connected in series with the collector of the transistor 122, the purpose of which is to limit the reset current; this not only protects the transistor, but also prevents the battery V from being overcharged. In order to keep the input pulses applied to the counter at the same strength, an input stage 127 is provided which contains a transistor 128 and an input resistor 129 . The transistor 128 also has a base b, an emitter e and a collector c; it becomes conductive when negative pulses are applied to input terminal 110 , since transistor 128 is an NPN transistor.

The in F i g. The counter shown in FIG. 1 has an output winding 117. This can also be omitted, the output being derived from the emitter of transistor 122. The arrangement according to the invention comprises both possibilities.

, A magnetic counter of the type described may include only a limited number of pulses per stage; if the number of pulses to be counted is higher, a plurality of counters must therefore be connected in series. It has been found that the largest pulse count of such a counter is about sixteen per stage. In addition, certain numbers of pulses cannot be easily counted with such counters. For example, to count a pulse number of twenty-nine, one would have to cascade a counter with the pulse number ten and another counter with the pulse number three (which would result in the pulse number thirty), and then one would have to add an additional circuit to subtract one unit from it. The reason for the limitation of the number of pulses to be counted per stage of such a magnetic counter can be seen from the illustration according to FIG. 3 and 4 can be seen.

F i g. 3 shows the essentially rectangular hysteresis loop of the core material of a meter according to FIG . 1, for example the material "Orthonik" type P 1040, as it is sold by the G. L. Electronics Company. The hysteresis loop is divided into ten patches, which are labeled with the numbers 1 to 10. They represent the individual stages of magnetization of the core from the state of negative saturation to the state of positive saturation, if the counter according to FIG. 1 should count ten pulses. The counter described is well suited for a number of pulses to be counted of, for example, ten, since the decrease in magnetic flux after the termination of each intermediate pulse is considerably smaller than the decrease in magnetic flux after the last pulse. These decreases in magnetic flux are shown in FIG. 3 shown. The decrease after the ninth pulse is denoted by A 0 F9 , the decrease after the tenth and last pulse with A OF 10. A 0 F 10 is considerably greater than A (P F 9. The resetting device of the counter is designed in such a way that the Transistor 122 is made conductive by the decrease A OF 10 in the flux, but not by the smaller decrease A OF 9; the latter is not sufficient to make the transistor conductive of the magnetic flux has become conductive, the core is returned to the state of negative saturation, so that the counter is ready to count a new series of pulses.

In Fig. 4 shows the relationships that would result if a larger number of pulses, for example twenty-five pulses, were to be counted. The hysteresis loop of FIG. 4 is divided into twenty-five sections. Since the individual magnetization steps are very small, the twenty-fifth pulse is unable to bring the nucleus into the state of maximum saturation, which is denoted by 0; the magnetic flux generated shortly before the end of the twenty-fifth pulse is therefore considerably smaller than the possible maximum value. The decrease in the magnetic flux after the end of the penultimate pulse, designated A OF 24, is also relatively large compared to the decrease A OF 25 after the last pulse. For the reasons mentioned, the difference between the declines A 0 F 24 and A 0 F 25 is very small. The resetting device could now be made very sensitive so that it can distinguish between the sizes A OF 24 and A OF 25 . However, if one takes into account that other influences can also cause changes, for example when the battery voltage or the room temperature fluctuates, it is easy to see that it is extremely difficult to design the reset device in such a way that it distinguishes between these two quantities with certainty. If the transistor 122 is not tilted into its conducting position when the twenty-fifth pulse has ended, the none is more strongly magnetized by the twenty-sixth pulse, whereby it can come close to or reach the maximum, and the reset device is actuated when the twenty-sixth pulse has ended will. The decrease in flux after the completion of the twenty-sixth pulse would be approximately equal to the sum of the decreases at the end of the twenty-fourth and twenty-fifth pulses. It would therefore be extremely difficult for the reset device to distinguish between these three decreases in flow. As can be seen, it is therefore extremely difficult to provide a counter for such a high number of pulses that is stable and operates reliably. It has been shown in practice that a number of pulses to be counted of sixteen represents the practically achievable limit for a counter of the type described.

According to the invention, means are now provided to increase the number of pulses to be counted and, at least in some embodiments, to increase the permissible temperature range within which the counter works reliably. For this purpose, instead of the arrangement according to FIG. 1, a saturable inductor core arrangement is provided which consists of at least two core parts or contains two separate cores which are designed in such a way that their substantially rectangular hysteresis loops are different from one another. The cores or core parts can be designed so that their external dimensions differ from one another, or they can consist of materials that have different magnetic properties, or both features can be combined with one another; the formation of the cores or core parts must in any case be such that a certain ratio of the ampere-turns is achieved which are required to produce a given flux in d, -n both cores or core parts, as well as a certain ratio of the saturation fluxes of the two Cores or core parts, so that first one core or core part is brought to saturation by the applied pulses without influencing the other, and that only the further pulses bring the other core or core part to saturation. In this modified arrangement, the number of pulses to be counted is the sum of the pulse numbers of all cores or core parts. The step-by-step saturation of the two cores or core parts can take place in different ways. Two of these possible types are as follows. First: The step-by-step saturation of the core or core parts takes place in such a way that only one of them is affected at a time. Second, the gradual saturation of the none or core parts occurs simultaneously, but in such a way that they reach the state of saturation at different times.

5 and 6 , a first embodiment of a magnetic counter according to the invention is shown, which includes two magnetic cells 141 and 142; in Fig. 5 and 6 only the input winding 116 is shown. It goes without saying that the counter also includes the remaining windings of the F i g. 1 includes, formed in the same manner to both cores JE but are wound. The counter thus also contains the windings 117 to 119 (not shown in the drawing). The cores 141 and 142 have different mean magnetic lengths, since one is not arranged within the other, and different cross-sections, as best shown in FIG. 6 to see. In addition, the cores can also consist of various magnetic materials. The core 141 can for example consist of "molybdenum Pennalloy" and the core 142 of "Ortlionics"; these materials are by - driven G. L. Electronics Company.

As is known, the magnetic field strength required to change the magnetic state of a core is equal to the ampere-turns divided by the length one along the path of the magnetic flux. This can be expressed by the following equation: where H is the magnetic field strength in ampere-turns per meter, N is the number of input turns of the core, I is the current flowing through the turns in amperes, and 1 is the length one along the path of the magnetic flux in meters. If this equation is multiplied by the mean magnetic length L. of the core, it reads as follows: This equation gives the ampere-turns required to produce a given flux in a space whose mean magnetic length is L. If the hysteresis loop, i.e. the strength of the magnetic flux as a function of the current, is recorded, it can be seen from the above equation that the width of the hysteresis loop for a certain core is directly proportional to its mean magnetic length and that the width is achieved by changing the magnetic length can be changed. In addition, the inductance of a core is proportional to its cross section; the steepness and width of a given core's hysteresis loop is a measure of its inductance, with the width decreasing as the inductance increases. The width of the hysteresis loop of a core can therefore be changed by changing its cross-section. The hysteresis loops for the two none 141 and 142 of FIG. 5 therefore have different widths, since the cores have different lengths and different cross-sections, and thus different inductances.

If the cores 141 and 142 are made from different materials, for example from “molybdenum permalloy” and from “ortlionics”, the widths and heights of the hysteresis loops also change further. The table of FIG. 7 shows the approximate values of the magnetic properties of "molybdenum permalloy" and "ortlionics", namely firstly the flux density when the material is fully magnetized, secondly the maximum flux density at zero magnetic field strength . H. the remanent flux density, and thirdly the magnetic field strength. As can be seen from the table, the values for "Ortlionics" are significantly higher than those for "Molybdenum Pennalloy". If one records the hysteresis loops for these two materials, one finds that the hysteresis loop for "Ortlionics" is about four times as wide as the hysteresis loop for "Molybdenum Permalloy", since the ratio of the magnetic field strengths is about 4 - 1 ; the height of the hysteresis loop for "ortlionics" is about twice as large as that of the hysteresis loop for "molybdenum permalloy", since the ratio of the maximum flux densities and the remanent flux densities is about 2: 1 . This applies to cores that have the same cross-section.

The relative magnetic properties of two cores, which according to FIG. 5 and which consist of the materials mentioned are shown in the table in FIG. 8 specified. The hysteresis loops of these two cores are shown in FIG. 9 shown. The two in FIG. 9 hysteresis loops shown have the same height. The vertical scale of the hysteresis loop for core 141, however, is about twice as large as that for none 142, so that the hysteresis loop of core 141 is actually twice as high as that of the hysteresis loop of core 142.

It is assumed that the none shown in FIG. 5 have the characteristics described and are arranged in a counter according to FIG. 1 , the number of pulses to be counted being "26" . The twenty-six pulses appearing at the input terminal 10 and applied to the input winding 116 change the magnetization of the nodes 141 and 142, as shown in FIG. 9 is shown. The hysteresis loops are divided into twenty-six parts, which are numbered 1 to 26 and represent the individual stages of magnetization. For example, the first input pulse causes the flow of both none to move from points A to points B and C; When the first input pulse ceases, the flow of both none goes back to points D. As can be seen, therefore, there is a final change in flux in core 141 while the final change in flux in core 142 is zero. The second input pulse drives cores 141 and 142 from point E to points F and G; when the impulse ceases, the flux of both nuclei falls back to point H. Points F and G of core 142 are the same points, so its flow "halts" at that point until the input pulse is terminated. Here too. a final change in the flux of the core 141 occurs while the change in the flux of the core 142 is zero. The third through fifteenth pulses have the same effects as the second pulse; during this time, the none 141 is gradually brought from negative saturation, as shown, to near positive saturation, while the none 142 remains in the state of negative remanent magnetization. The sixteenth input pulse drives both nuclei from point J to points K and L; when it ceases, the flux of both nuclei falls back to the M points. As you can see, there is a final change in the flow of both Nos 141 and 142. The seventeenth pulse drives nuclei 141 and 142 from points N to points 0 and P. The hysteresis loop of nucleus 141 shows that points 0 and P are practically the same, so that none 141 "stops" at this point. At the end of the seventeenth input pulse, both none fall back to point Q. As can be seen from the hysteresis loops, the final change in magnetic flux of core 141 is zero, while in none 142 there is a significant final change in magnetic flux. The eighteenth through twenty-fifth input pulses have essentially the same effects as the seventeenth pulse. The twenty-sixth pulse brings both nuclei from the points R to the points S and T, with which the maximum magnetic flux 0 .. is reached. At the end of the twenty-sixth input pulse, both nuclei fall back to point U. The sum of the decrease in the magnetic fluxes, i.e. the sum of the two fluxes A OF26, is sufficient to trigger the reset effect of the counter so that both cores are returned to the state of negative saturation, i.e. H. to point A, which represents the negative remanent magnetic flux.

A brief consideration of the theory can be useful in order to understand the above-mentioned mode of operation of a counter according to FIG . 5 to understand. The input impedance (the apparent resistance) of a device of this type (and thus the current intensity) depends primarily on the steepness of the hysteresis loop at the point under consideration. The input circuit of a counter according to FIG . 5 can therefore be viewed as consisting of two inductances connected in series, the values of which are determined by the hysteresis loops of the cores 141 and 142. the input voltage is therefore distributed over the two inductances according to their inductive resistances. When the first input pulse is applied to input winding 116 , both Neither of them move rapidly from points A to points B of FIG. 9 and then to points C. As soon as the hysteresis loop of core 141 begins its vertical rise, the inductive resistance of that part of the winding associated with none 141 becomes significantly greater than the inductive resistance of that part associated with core 142 . Since the voltage of the two inductive resistors connected in series is distributed proportionally to the size of the respective resistors, the voltage assigned to none 142 becomes very small after a short time, so that practically the entire voltage is assigned to core 141. This is why the change in the flux of the core 142 is very small and that of the core 141 when the flux goes from the point A to the point C is very large. At the termination of the first input pulse, the flux of both Neither falls back to points D , so that the core 141 experiences a large final change in flux, while the final change in the flux of the core 142 is zero.

This game is repeated until the core 141 has approached positive saturation. At the sixteenth input pulse, the curve of the core 141 begins to bend in the horizontal direction, with the result that the inductive resistance of this part of the winding decreases. A larger part of the applied voltage therefore acts on the circuit 142, so that a change in the flow begins to take place in it. Towards the end of the sixteenth input pulse, the core 141 is essentially on the horizontal part of the hysteresis loop, so that the associated inductive resistance drops to a very low word. At this time, however, the curve of the core 142 begins to rise vertically, so that this part of the input winding has a significantly higher inductive resistance and therefore practically all of the voltage is applied to the core 142. Upon termination of this pulse, the flux of both nuclei falls back to the points M, so that a final change in the flow occurs in both nuclei. In the following pulses practically the entire voltage acts only on core 142, so that from the seventeenth to the twenty-fifth pulse in the none 142 final changes occur, while the final changes in the flux of the core 141 are equal to zero. When the twenty-sixth pulse begins, both Neither are at point R. Since the inductive resistance for the no 141 is very low here, practically all of the applied voltage acts on the no 142, with the result that the flux of the core 142 is driven onto the flattened part of the hysteresis loop, i.e. H. to point T. Neither 141 is also driven to point T, since the inductive resistance associated with core 142 becomes low and the voltage is therefore essentially evenly distributed between both Nodes. At the end of the twenty-sixth pulse, the flow of both none falls back to the points U.

As shown in FIG. 9 , the sum of the drops A OF26 at the end of the twenty-sixth pulse is considerably greater than the sum of the drops A OF25 at the end of the twenty-fifth pulse, so that the resetting device can easily distinguish between these two drops; the reset takes effect at the completion of the twenty-sixth pulse, so that both nuclei return to point A. The combined decrease in flow when the last pulse of a number of pulses to be counted ends is therefore considerably greater than the combined decrease when the penultimate pulse ends; Since the inductive resistances of the two none become approximately the same at the end of the last pulse and the voltage is therefore evenly distributed over both parts of the winding, both cores are definitely brought to point 0, the maximum magnetic flux. The invention therefore provides a stable and reliably working counter for a considerably larger number of pulses to be counted than was possible with the magnetic counters known hitherto. In addition, an even larger number of pulses to be counted can be achieved by arranging more than two cores.

The table of FIG. 10 gives the values for a counter designed according to FIG. 5 for a pulse number of thirty pulses to be counted.

A abgeänderte.Ausführungsform a meter according to - the invention is in .-- - F i g. 11 shown. The two cores 151 -and- 152 are mutually identical. The input winding 1-16 is however so wrapped around the None> that-.on the Kein151 twice as much Winduügs'zahlen7 eiiiwirken as the No 152. The windings-U7 to 119 are shown in FIG. 11 is not estellt darg. - You, # siüd'wound over both cores 151 and 152 , . so that with regard to these - windings both cores are the same. Have waste numbers.

It. it is assumed that both kernels consist of "OrthoiÜk". The table. -the * F i g. 12 shows the magnetic 'properties of these two cores.' The Hysteresisschleifgn there cores 1 51 and 152 are shown in Fig. 13. -, both H hysteresis loops the -gleiche height - because the cores are equal among themselves' who. However, since det-core 151 has a larger number of. Has turns ... is the width of its hysteresis loop -, smaller than that of the hysteresis loop of the core-152. The number of turns of the core 151 is twice as large as that of the core 152. The width of the hysteresis loop of the core 151 is therefore about half as large - as the width of the hysteresis loop of the core 152. - The mode of operation - of the counter according to Fig. 11 is similar to the procedure described above. Since the steep part of the curve of the core 151 is located at a position at which dib - curve of the core 151 virtually extends horizontally, and because conversely the steep part of the curve of the core 152 at a location at which the curve of the core 151 is approximately extends horizontally, is initially the core 151, which has the narrower hysteresis loop brought from the state of negativen'Sättiäung in the vicinity of the positive tive saturation, and then the core 152 until the last pulse No simultaneously achieve both the maximum of the saturation . Assume that the number of pulses to be counted is "thirty". First, the core 151 goes through stages 1 to 19. At the twentieth pulse, the inductive resistance for the core 151 decreases, while the inductive resistance for the none 152 rises, so that the none 152 goes through the stages 20 to 29 in the following pulses. At the thirtieth pulse, both nuclei reach the maximum zero of the magnetic flux; if the thirtieth impulse stops, the flux of both nuclei sinks to the value of the remanent magnetic flux. The sum of the decreases A OT 30 at the termination of the thirtieth pulse is # as from FIG . 13 , much larger than the sum of the drops A 0F29 of the penultimate pulse. Upon termination of the last import pulses is therefore, provision so that both No be returned to the state of the negative magnetic saturation effect.

As further from FIG. 13 , the magnetization levels of the two none are of different sizes. The steps of the core 152 are approximately twice as "r Cr oß as those of the core 151. This is due, as is known to those skilled in the art, from the fact that the size of the steps is inversely proportional to the number of turns. Since the two cores are equal among themselves and the No 151 has twice as many turns as No 152, therefore the steps of the core 152 are about twice as large as those of the core 151. The number of turns and thus the relative widths of the two loops can be selected in any desired ratio, so that a desired number of pulses to be counted is achieved.

The counter of FIG. 11 has two slots 151 and 152. It goes without saying that a larger number of cores can also be used which have different numbers of windings, so that a larger number of pulses to be counted can be achieved. The, as in windings, can also be formed from># F i g. 15 shown. Here, separate windings 116 a and 116 b are provided for the no 151 ä and 152 a, which are connected in series. The operation here is the same as bei'dem meter according to Fig. 11, and- the hysteresis loops are the same as in FIG. 13.

Fig. 14 is a table showing the values of a counter according to Fig. 11 or 15 whose number of pulses to be counted is thirty.

In Fig. 16 and 17 a further embodiment of a counter according to the invention is shown. Two none 161 and 162 are used. The diameter of the cores 161 and 162 are equal, JE but their height is different, so that they have a different cross section, as shown in FIG. Seen 17th F i g. 16 shows only the input winding 116. It will be understood that there are also windings 117 to 119 which are wound around both none at the same time.

Let it be assumed that the material of both is not "ortlionics". The table of FIG. Figure 18 shows the magnetic properties of Nos 161 and 162, assuming that the cross-section of core 161 is about twice that of core 162. The inductance of a core is proportional to its cross-section; the current consumption of the input winding is inversely proportional to the inductance if the applied voltage remains the same. The hysteresis loops of none 161 and 162 are in FIG. 19 shown. Since the core 161 has a higher inductance (a greater inductive resistance) as a result of its larger cross-section, a larger part of the voltage is initially assigned to the core 161 , so that first the no 161 and then the no 162 are gradually reversed. The operation of a counter with cores 161 and 162 is similar to the operations described above. A detailed description therefore does not appear to be necessary. With the last pulse the maximum magnetic flux 0 is generated in both cores; when the last impulse ceases, the flow in both nuclei decreases. The sum of the declines at the end of the last pulse is significantly greater than the sum of the declines of the penultimate pulse, so that the reset device is always actuated, both of which are returned to the state of negative saturation.

In this embodiment, too, there can be more than two none with different large cross-sections are used, so that a larger number of pulses to be counted is achieved.

F i g. 20 is a table showing the values of the individual parts of a counter of FIG . 16 indicates when the number of pulses to be counted is thirty.

Another embodiment of the invention is shown in FIG. 21 and 22 shown. As in the other embodiments, only the input winding 116 is shown. The lines 171 and 172 have different magnetic lengths and a different cross-section, as best shown in FIG. 22 can be seen.

It is assumed that both cores 171 and 172 consist of the material "ortlionics". The hysteresis loops of cores 171 and 172 will therefore look similar to those in FIG. 19 shown hysteresis loops of the none 161 and 162. The operation is therefore essentially the same.

First, the core 171 and then the core 172 are gradually remagnetized until both cores reach the state of positive magnetic saturation at the last pulse and are returned to the state of negative magnetic saturation after this pulse has ceased.

Another embodiment is shown in FIG. 23 and 24 shown. Here, a single No 181 is used, which is formed separately and consists of the two parts 181 a and 181 b . Both parts have different magnetic lengths. Only input winding 116 is shown; it is understood that windings 117 to 119 are also present. The hysteresis loops for the core parts 181 a and 181 b are similar to the embodiment described above and as in FIG. 19 shown. The way of working is therefore the same.

Another embodiment of a meter according to the invention is shown in FIG. 25 shown. Two cores 191 and 192 are used. The none 192 is disposed within the core 191 so that it has a smaller magnetic length. The width of the hysteresis loop is directly proportional to the magnetic length of the core; the hysteresis loop of core 191 will therefore be wider than that of core 192. If both cores are made of the same material and have the same cross-section, their hysteresis loops will be the same height and differ only in width. These hysteresis loops therefore take the shape of FIG. 27 at.

The operation of the counter according to FIG . 25 is similar to that of the counters according to FIG. 5 and 11. A detailed description of the mode of operation therefore does not appear to be necessary.

Another embodiment of a meter according to the invention is shown in FIG. 26 shown. Two no 201 and 202 are used here, which have the same dimensions but differ in material. The first none, for example, consists of "Molybdenum Permalloy" and the second of "Orthonics". Here, too, only the input winding 116 is shown. From what has been said above it can be seen that the hysteresis loop for the material "orthonics" is significantly wider and higher than the hysteresis loop for molybdenum "permalloy". The counter therefore works similarly to the counter according to FIG. 1 described above. 5 and 11.

It has been found through experiments that the permissible temperature range within which the counter works reliably becomes larger if different materials are used for the two cores, as in the embodiments according to FIG. 5 and 26. If the material "Ortlionics" is used for a core, the square ratio of the hysteresis loop increases with decreasing temperature, while the number of pulses increases with increasing temperature. If, on the other hand, »molybdenum permalloy« is used for a none, the square ratio increases with increasing temperature, while the number of pulses decreases with increasing temperature. If combined cores containing these two materials are used, the effects of the temperature changes more or less cancel each other out within a wide range, so that the meter remains stable and works accurately over a larger temperature range. Experiments have found that a counter according to FIG. 5 or 26, in which different magnetic materials, namely "Ortlionics" and "Molybdenum Permalloy" are used, remain stable up to a temperature of well over 1001 C and work reliably. If the same materials are used for the two cores, however, a temperature of about 601 C must not be exceeded.

It is understood that the embodiments illustrated and described above can also be combined and modified with each other. Likewise, of course the state of rest also be the positive, saturation from which the nucleus progressively is brought into the state of negative saturation, to then through the reset winding to be returned to the state of positive saturation.

Claims (2)

Claims: 1. A magnetic pulse counter whose core has a substantially rectangular hysteresis loop (characteristic) and is driven by a predetermined plurality of input pulses from a first state of magnetic saturation in a plurality of steps into the state of opposite magnetic saturation, whereupon an output pulse is generated, characterized in that at least two none or core parts are used, which have a different characteristic and which are acted upon by the input pulses at the same time, the characteristics are selected such that the steep rise of the individual curves takes place at different points, so that first one and then the other nucleus is gradually driven to saturation. 2. Pulse counter according to claim 1, characterized in that the none have different number of ampere turns. 3. Pulse counter according to claim 2, characterized in that the cores have different magnetic saturation ampere turns. 4. Pulse counter according to claim 1, characterized in that the cores have different magnetic saturation fluxes. 5. Pulse counter according to claim 1, - characterized in that the cores have both different number of ampere turns and different saturation flows. 6. hnpulszähler according to claim 1, characterized indicates overall that the various No pre- sent measurements, so that their characteristics are different from each other. 7. Pulse counter according spoke 6, characterized in that the cores are made of different magnetic materials. 8. Pulse counter according to claim 6, characterized in that the cores have different mean magnetic lengths. 9. Pulse counter according spoke 6, characterized in that the none have different magnetic field strengths. 10. Pulse counter according to claim 6, characterized in that the none have different sized cross-sections. 11. Pulse counter according to claim 6, characterized in that the none have both different cross-sections and different magnetic lengths. Older patents considered: German Patent No. 1 165 662.