DE1236573B - Magnetic core counting circuit with changeable counting ratio - Google Patents

Description

Magnetic core counting circuit with changeable counting ratio Magnetic core counting circuits are known to work on the principle that a magnetic core with an approximately rectangular Hysteresis loop, hereinafter referred to as the counter core, in the rhythm of counting pulses is gradually magnetized until after a certain number of counting pulses the saturation magnetization of the counter core is reached. In this state will by means of an additional circuit, the counter core is triggered by a reset pulse in magnetized back to its original state, whereupon the counting process starts again begins. The reset pulses thus each show the arrival of one to the full Magnetization reversal of the counting core to the required number of counting pulses. In order to the number of counting pulses required to completely reverse the magnetization of the counting core always remains the same, these must be dimensioned the same as one another. Counting pulses of constant magnetizing effect can be achieved with the help of another Magnetkernes "hereinafter referred to as the driver core, et, achieve that with each Input pulse magnetized first in positive, then in negative direction until saturation is, with each of the two magnetic reversal processes in a secondary winding (Induction winding) generates a voltage surge, one of which is fed to the counter core and causes a magnetic reversal there to the desired extent. The one at the subsequent reverse magnetization of the driver core in the induction winding opposing voltage pulse is kept from the counter core by a diode, so no demagnetization occurs there.

Prerequisite for a constant magnetizing effect for everyone Magnetization reversal from the driver core to the counter core is that the transmitted Voltage surges constant time integral of the voltage (voltage-time area) because a certain quantum of a magnetic flux corresponds to in electrical units is the time integral when this magnetic flux changes around this quantum voltage generated in a secondary winding. The transfer the voltage surges from the driver core to the counter core remains flawless as long as than the ratio of the voltages at the counter core and driver core remains constant. This The ratio now changes with the temperature and with the operating voltage, since on the one hand as the temperature rises, the undesired voltage losses in the counting circuit decrease, on the other hand, the driver core is then magnetized more quickly. The latter causes a higher induction voltage at the counter core; in proportion to this take the losses in the counting circle therefore even more sharply than when viewed in absolute terms. Both effects (reduction voltage drops and increases in induction voltage) cause a change of the counting ratio, that is the number of those pulses that result in a one-off complete non-magnetization of the counter core are necessary, in the same sense.

In counting circuits with a constant counting ratio, the the temperature dependence of the switching elements caused the temperature response of the counting ratio keep it relatively easy to keep small. For circuits with a variable counting ratio, however, only the question of the temperature dependence of all possible counting ratios unsatisfactory solution if the switchover is not through mechanical contacts, but rather should be done electronically.

It is already a magnetic Flußzähler with two blocking oscillators, and has ever been a scoop core and Zählkein each counter stage proposed in which the collector of the transistor of the first blocking oscillator, which contains the suction core and serves as a pulse shaper stage, to a winding of serving as Zählkern carry a core of the second blocking oscillator , which forms the actual meter, is connected. In this flow meter, the base of the transistor of the first blocking oscillator is directly connected to the input of the counter stage and its collector is galvanically connected via a diode to the winding of the counter core.

In parallel with the the collector of the transistor galvanically with the winding connecting diode can while a series connection of one Diode and an ohmic resistor for setting the acting on the winding Stromes are arranged. A composition of an induction and / or magnetization winding however, partial windings are not provided.

The invention relates to a magnetic core counting circuit with variable Counting ratio, the at least one via an induction winding of a driver core guided induction and / or at least one via a magnetization winding contains a counter core guided magnetization circuit and in the at least an induction and / or at least one Ma etisierungswindung from mehree gn ren Teilwicklunaen exists.

The object of the invention is to provide the magnetic core Zählschaltuna form such that is a development of the count ratio Verstel- easily ensured, particularly low-temperature response.

According to the invention, the magnetic core counting circuit is the solution this task with at least two connected in parallel, at least partly via different partial windings of one and the same counter or driver core leading diode circuits, at least one of which has a variable resistor has, provided. With this circuit can be changed by changing the resistance the current through the associated diode circuit and thus also the entire current of the change both parallel diode circuits within a certain range. With this arrangement, either the driver core or the counter core or else both cores can also be provided. The switching elements can here with regard to their temperature-dependent properties are designed so that in the two Limit states of that area. within which the resistance can be changed, an optimal temperature compensation is achieved while in the transition states the temperature dependence is stronger. The arrangement according to the invention is thus preferably suitable for those counting circuits that are currently only in the two limit states that area can be operated, i.e. by changing the resistance of one extreme value switched to the other extreme value in their counting ratio will.

For electronically switchable counting devices it turns out to be advantageous, as a variable resistor one with its emitter-collector path to use a transistor switched on in one of the diode circuits, its emitter-base path a transformer winding connected in parallel to feed switching pulses is.

Optionally, the variable resistor can also be a transformer via a pulse of sufficiently high inductance transformer coupled, since the output voltage of the drive core is me of short pulses, with no DC voltage must be transmitted j.

Embodiments of the invention are shown in the drawing. F i g. 1 shows a magnetic core counting circuit with a counting core 1, which is provided with a magnetization winding 2, to which the counting pulses for the gradual magnetization of the counting core are fed. To generate these counting pulses, a driver core 3 is used, which when a pulse contact 4 is closed by the current of a winding 5 connected in series with the contact 4 in one direction and when the contact 4 is opened by the current of an opposing winding 6 in the other direction is magnetized to saturation. By reversing the magnetization of the driver core 3 , voltage surges are generated in two induction windings 7 and 7 '. The windings 7 and 7 ' are connected to one another with one winding end each, in such a way that the voltages induced in both windings add up. From the common connection point of the two windings, a current path through a diode 8 results in the magnetizing winding 2 of the Zählkernes 1. About this current path reach the voltage pulses alone produced in the induction coil 7 to the magnetizing winding 2. With 8 'is one of the induction coil 7' designates downstream diode; this diode 8 'as well as a connected downstream v eri ilnderbaren resistor 9 arrive in two Induktionswicklungen7 and 7' voltage pulses generated at the magnetizing winding 2. The voltage pulses mentioned, in the two diode circuits (7, 8 and 7, 7 ', 8 ', 9) are triggered in the direction of passage of the relevant diodes, serve as counting pulses through which the counting core 1 is gradually magnetized. The voltage surges generated with the opposite magnetization of the driver core 3 are kept away from the magnetization winding 2 by the diodes 8, 8 '.

The counting core 1 is provided with a further winding 10 which is used to reverse magnetize the counting core 1 as soon as it has been magnetically saturated by the counting pulses of a counting period. For this purpose, a transistor 11 is provided which is connected in series with the winding 10 and has a resistor 12 which is connected to the base-emitter circuit and which is in series with the magnetizing winding 2. As long as the counter core 1 is not saturated, in the event of a voltage surge in the induction windings 7 or 7, 7 'due to the relatively high inductance of the winding 2, a relatively low current flows through the resistor 12, which is too low to make the transistor 11 conductive . However, as soon as the counter core 1 has been saturated after a counting period, the inductance of the winding 2 is reduced and the magnetizing current increased accordingly that the voltage drop across the resistor 12 makes the transistor 11 conductive and that its collector current flowing through the reverse magnetization winding 10 returns the counter core 1 returned to its initial state.

The setting of the counting ratio is done by changing the resistor 9. If the resistance value is high, the circuit leading through the diode 8 'is almost blocked, so that practically only the voltage generated in the winding 7 reaches the magnetizing winding 2 of the counting core. When the resistor 5 9 is set to its lowest resistance value, the voltage induced in the winding 7 ' , together with the voltage generated in the winding 7 , also reaches the magnetizing winding 2. The diode 8 is then blocked by the voltage induced in the winding 7'. The resulting voltage reaching the magnetizing winding 2 and thus also the voltage-time area of the counting pulses are dependent on the setting of the resistor 9. In the same direction as the voltage-time area of the individual counting pulses, their magnetizing effect changes and, in the opposite sense, the counting ratio.

In the embodiment according to FIG. 2, the resistor 9 is replaced by a switching transistor 13 , the base-emitter path of which the secondary winding 14 of a transformer is connected in parallel. The primary coil 15 of this transformer is connected with a contact 16 in the charging or discharging circuit of a capacitor 17. When the contact 16 is closed, when the contact 4 is closed, negative voltage pulses are generated in the secondary winding 14 and, accordingly, the Tran-C p sistor 13 is opened precisely during the remagnetization of the driver core 3 . When the contact 16 is open, the transistor 13 remains blocked. A specific counting ratio corresponds to each of the two states of the transistor 13. For the sake of clarity, FIG. 2 as well as in F i -. 3 the circuit of the counter core is omitted.

In the embodiment according to FIG. 3 , the variable resistance is coupled to the primary winding 18 by means of a transformer via a pulse transformer with a sufficiently high inductance. A switching transistor 20, whose collector-emitter path is connected to the secondary winding 19 of the pulse transformer, serves as a variable resistor. is. A voltage divider consisting of resistors 21 and 22, which can be connected to voltage by means of a contact 23, is used to switch the counting ratio. The resistor 22 is connected in parallel to the base-emitter circuit of the transistor 20. When the switch 23 is closed, the transistor 20 is made conductive by the base current flowing through the resistor 21. The voltage surge delivered by the induction winding 7 'of the driver core 3 to the pulse transmitter 18, 19 during a counting pulse is then short-circuited by the transistor 20; the sum of the induction windings 7 and 7 'is effective for the counting circuit. If, on the other hand, the switch 23 is open, the transistor 20 is reliably blocked by its emitter bias and the resistor 22. If the inductance of the primary winding 18 of the pulse transformer is sufficiently high, the voltage surge emitted by the induction winding 7 ' results in only a small magnetizing current through the winding 18. If this current is less than the magnetizing current of the counting core 1, the diode 8 becomes conductive and is used for the counting circuit only the induction winding 7 is effective. This results in a different counting ratio than when switch 23 is closed.

It is essential for the function of the circuit that the transistor 20, which is connected as a variable resistor to the secondary winding 19 of the pulse transformer, is switched on in such a way that the part of the counting pulse transmitted via the pulse transformer is in blocking direction, on the base-collector path of the transistor 20 works because the transistor does not block in the opposite direction.

F i g. 4 shows a counting circuit in which the counting core 1 is provided with the inventive arrangement of C magnetizing circuits. Here the counter core 1 is equipped with two magnetization windings 2 and 2 ', each of which is preceded by a diode 8 or 8' : - 7 . With the diode 8 is connected in series of veranderbare resistance 9. By varying the resistance 9, makes the "esamte on the Wick Lunaen 2 and 2 'flowing Ma-netisierungsstrom and thus change the count ratio within a certain range and adjust. In the embodiment of 4, only a single induction winding 7 of the driver core is provided.

A corresponding circuit with a transistor 20 for switching over from one counting ratio to the other is shown in FIG . 5. Here, too, the counting core 1 is provided with two magnetizing windings 2 and 2 'with diodes 8 and 8' connected upstream, the circuit of the diode 8 being able to be switched on and off by the transistor 20 depending on the actuation of the contact 23.

Claims (2)

Claims: 1. Magnetic core counting circuit with a variable counting ratio, which contains at least one induction circuit led over an induction winding of a driver core and / or at least one magnetization circuit led over a magnetization winding of a counting core and in which at least one induction and / or at least one magnetization winding is made up of several partial windings is, g e k ennzeich -n c t d urch at least two mutually parallel Cleschaltete, at least in part on different partial windings (7, 7 ') of the same count or driver core (3) leading diode circuits, of which at least one of a variable Has resistor (9) . 2. Arrangement according to claim 1, characterized in that a transistor (13) switched on with its emitter-collector path in one of the diode circuits (7, 7 ', 8', 13) serves as a variable resistor. 3. Arrangement according to claim 2, characterized in that the emitter-base path of the transistor is connected in parallel to a transformer winding for feeding in switching pulses. 4. Arrangement according to claim 1, characterized in that the variable resistance is transformer-coupled via a pulse transformer, in. 5. Anordnuna according to claim 4, characterized in that a switching transistor (20) serves as a variable resistor, which is connected with its emitter-collector path on the secondary side to the pulse transformer in such a way that the transmitted part of the counting pulse in reverse direction to the base-collector -Way of the transistor acts. Older Patents Considered. C German Patent No. 1171 014.