DE1224360B - Electronic distribution chain like a ring counter - Google Patents

Description

Electronic distribution chain in the manner of a ring counter. They are electronic Distribution chains in the manner of a ring counter are known, their individual stages in each case Contain transistor flip-flops or transistor oscillators. Are disadvantageous in addition to the circuitry complexity, the relatively high power consumption and the loss of the currently set identification in the event of a failure of the operating voltage. Furthermore, there are generally special requirements for the duration of the counting pulses on the other hand, in many cases without a relatively large amount of additional effort only short output pulses can be emitted from the distribution chain outputs.

Electronic counters are also known ("Electronics", 1961, No. 24, pp. 62 to 64, "Electronic Rundschau", 1963, No. 2, pp. 67 and 68), the consist of a chain connection of individual transfluxor stages. Here contains a transfluxor stage z. B. two transfluxors and one transistor. at the counting process is based on an extended principle of pulse division according to a specific counting code from the counting pulses applied on the input side a partial pulse series is selected and passed on to the next transfluxor stage will. Here, all transfluxor stages are according to the size of each stored number may be marked at the same time.

Furthermore, it has already been proposed (German Auslegeschrift 1168 486) to build a distribution chain from a series of magnetic cores with a rectangular hysteresis loop, each core being provided with windings for switching the magnetic saturation between two states by alternately applied reset and shift pulses. Depending on the setting of the distribution chain, any number of output pulses can be output on one of several control lines. For this purpose, each magnetic core is assigned a transfluxor core with a read winding, via which, when the transfluxor is set, driver pulses are fed to a downstream transistor amplifier and, after amplification, are passed on to the relevant control line and then finally to a load resistor. A parallel connection of several series circuits, each consisting of the blocking winding, a magnetic core, a blocking rectifier, a blocking winding of the associated transfluxor and an adjustment winding of the subsequent transfluxor, is connected in series with the shifting windings of all magnetic cores to a displacement pulse generator. The set transfluxor is blocked by the individual shift pulses and the following set is set so that the driver pulses are fed to the control line of the next following magnetic core after this switchover. The potential control of the individual blocking rectifiers is designed in such a way that current flows through only that series line which contains the blocking winding of the transfluxor that has just been set and the setting winding of the next following transfluxor.

An electronic distribution chain that avoids the disadvantages mentioned in the manner of a ring counter, in which the individual stages each contain transfluxors, is characterized according to the invention that the transfluxors with parallel fed, output windings connected as a choke are provided, with the large output current a blocked transfluxor is used to identify a distribution chain exit, and that each transfluxor has a reversing circuit which is activated in the blocked state is assigned to an incoming counting pulse for setting the transfluxor and at the same time evaluates to block the next one.

In the following, on the basis of FIG. 1 and 2 explain the symbolism used in more detail using the known example of a two-hole transfluxor. On the leg S1 made of magnetic material surrounding the large transfluxor hole, according to FIG. 1 a blocking winding 1 is provided, which generates a blocking flow B when a current flows in the direction of the arrow. By means of an adjusting winding 2, an oppositely directed adjusting flux E is produced in an analogous manner. The exit hole A is surrounded by the legs S2 and S3. The windings 3 and 4, which are arranged on S2 and S3, can generate alternately opposing magnetic fluxes running around A when current passes in the direction of the arrow, which in S2 and S3 each run in the direction of B.

Corresponding to the mirror symbols for Toroidal cores is now shown in FIG. 2 of the leg S 1 shown as a horizontal bar, which is to be interpreted as a closed toroidal core. The legs S2 and S3 are also symbolized by horizontal bars and by vertical bars in the way that the exit hole A also appears in the symbolic representation of is enclosed within them. Each of the windings 1 through 4 is indicated by a slash marked, which is inclined at 45 ° to the beam in question. The connecting cables of the windings are indicated by vertical line lines, which respectively go through the intersection of the slashes with the bars. Will the directions of the currents indicated by corresponding arrows at the lines of the line, this results the direction of magnetic flux in the legs in such a way that the magnetizing current is understood as a ray of light, which is symbolized by a slash Mirror - is deflected into the beam axis in the direction of flow. The direction of the blockage flow B is in FIG. 2 drawn in at winding 1, the direction of the adjustment flux E for winding 2. The windings 3 and 4 generate in the legs S2 and S3 with current passage in the specified current direction, magnetic fluxes that coincide in terms of direction with the partial flows of B running in S2 and S3.

It is known that a transfluxor, initially by application a blocking flow B and then by applying a smaller, oppositely directed adjustment flow E enters the "adjusted" state is alternately remagnetizable by the windings 3 and 4 in the area of the exit hole is. So the windings 3 and 4 alternate pulses in each sent specified current direction, then results from the continuous reversal of magnetization the transfluxor has a throttling effect on the output current. In the set The state of the transfluxor is the output current flowing through the windings 3 and 4 reduced to a small residual current due to the throttling effect. Will however leave the transfluxor in the blocked state, as a result of the saturation of the Legs S 2 and S 3 are not remagnetized in the manner described, so that no throttling effect can arise. In this case the output current only slightly dampened by the Transfluxor. The invention now applies this Recognition in such a way that the contained in the individual stages of the distribution chain Transfluxors to identify the assigned distribution chain output be brought into the blocked state and thus a large output current give off, while the other, unmarked exits assigned to transfluxors can be left in the set state, in which they only have a very small Release residual current.

The in Fig. The preferred embodiment of the invention shown in FIG. 3 shows a three-stage distribution chain, the stages of which contain the transfluxors 5, 6 and 7, respectively. The blocking winding of 5 is denoted by B 5, the setting winding by E5. The same applies to the transfluxors 6 and 7. The magnetically opposing output windings 5 ', 5 ";6',6" and 7 ', 7 "of the individual transfluxors are on the one hand via decoupling diodes 8, 9; 10, 11 and 12, 13 Connected to the two outputs of a semiconductor switch U, which is at ground potential and constantly switches at a sufficiently high frequency, in such a way that a multiple circuit of corresponding windings of the individual transfluxors is created, and on the other hand, low-ohmic resistors 14, 15 and 16 as well as assigned to the individual transfluxors via relatively high-resistance resistors 17, 18 and 19 to the operating voltage - U. The resistors 17, 18 and 19 represent the output or load resistances of the individual stages, with the distribution chain output marked by a blocked transfluxor from a large output current is traversed.

In the illustrated embodiment, there is therefore a parallel feed of all transfluxor output circuits, with the one in each of the parallel branches flowing current depending on the blocking or setting of each associated transfluxor has a large or small amplitude value. the Switching from one distribution chain level to the next when receiving a counting pulse 20 takes place in such a way that the respectively blocked Transflnxor is brought into the set state by this counting pulse, during the the next following Transfluxor is blocked at the same time.

In the following, a reversing circuit will be explained in more detail with reference to the first distribution chain stage containing the transfluxor 5, which is assigned to this and which causes the switching of the distribution chain from the transfluxor 5 to the transfluxor 6 when a counting pulse 20 occurs. This reversing circuit comprises a current branch which contains the setting winding E5 and the resistor 21 arranged in series therewith, as well as a second current branch which has the blocking winding B 6 and the resistor 22 situated in series with it. These parallel-connected current branches are routed to the ground point via a rectifier 23 and a capacitor 24 on the one hand and to the circuit point 25 on the other hand. When the transfluxor 5 is blocked, the anode 26 of the rectifier 23 has only a weakly negative potential due to the low alternating current resistance of the transfluxor, while the cathode of the rectifier 23 is connected to ground potential via the resistors 21, 22 and 27. Thus, the rectifier 23 is controlled in the pass band, so that an incoming counting pulse 20, which is fed to a switching transistor 28 via a transformer 29 and switches this to the low-resistance state, a current flow from the ground point via the capacitor 24, the rectifier 23, the windings E 5 and B 6, the resistors 21 and 22 and the transistor 28 to the pole - U of the operating voltage causes. As a result, the Transfluxor 5 is set and the Transfluxor 6 is blocked at the same time. The relatively large output current of the transfluxor 5 is significantly reduced, while the small output current of the transfluxor 6 is greatly increased. The distribution chain is now switched one step further.

Although the transfluxors 6 and 7 are also reversing circuits of the same type are assigned to which, via point 25, a strong negative potential is simultaneously supplied is not caused by this reversal process, provided that the transfluxors 6 and 7 are in the set state and by the in this case occurring, even more negative potential at the resistors 15 and 16 of the associated rectifier lock. Thus, only the reversing circuit 21 to 26, the blocked transfluxor 6 is assigned, switched to effective when the rectifier 23 is open and evaluates the incoming counting pulse 20 to switch to the next following transfluxor 6 off. The resistors 21 and 22 are used for mutual decoupling of the Setting winding E5 and the blocking winding B 6, while the capacitor 24 next its function within the reversing circuit at the same time a screening of the output current of the transfluxor 5 causes.

The semiconductor switch U is in an advantageous manner as a self-oscillating Transistor push-pull generator formed, for example, a switching frequency of about 100 kHz. In case the changeover switch U by an alternator is replaced, the throttling effect of the transfluxors in the context of the invention can also with an alternating current supply only one output winding, e.g. B. 5 ', 6' and 7 ', can be used.

A major advantage of the distribution chain according to the invention is It can be seen in the fact that short counting pulses are also used for incremental switching can that do not meet the time conditions to be set in the known distribution chains need to suffice. In the event of an impermissible drop in the operating voltage - U can through Insertion of simple monitoring circuits known per se for electromechanical selectors, which in this case cause a suppression of further counting pulses, advantageously Way can be achieved that the respective marked distribution chain output is energized remain.

An advantageous application of the distribution chain according to the invention In so far as it is possible, it arises not just one, but simultaneously several marked distribution chain outputs at the same time to the next one To switch chain outputs further (shift register). In the event that the resistances of the circuits for the setting winding and the blocking winding of the same Transfluxor are coordinated so that at the same time Continuity of the current the existing state of the transfluxor remains unchanged, also two or more juxtaposed distributor chain outputs at the same time to be marked. For example, is the Transfluxor 5 and at the same time the Transfluxor 6 blocked, an incoming counting pulse 20 causes the setting on the one hand of the transfluxor 5 and on the other hand the blocking of the transfluxor 7, while the Transfluxor 6 is influenced both via B 6 and E 6 and thus in the state before the counting pulse arrived, d. H. so in the blocking, remains.

When using such a trained distribution chain as With a parallel input, shift registers become the transfluxors of all to be labeled Blocked distribution chain stages, the series output at the load resistance of a certain level takes place, while with a serial entry the Transfluxor a set and blocked one after the other at a certain level in a certain sequence and the parallel output takes place at the load resistors of all stages.

With particular advantage, a distribution chain according to the invention used in monitoring systems of the monitoring technology, where it is on a regular scanning of different lines, for example for the purpose of pilot monitoring, arrives. Here, the individual lines are each assigned individually Distribution chain outputs queried.

Claims (2)

Claims: 1. Electronic distribution chain in the manner of a ring counter, in which the individual stages each contain transfluxors, d a d u r c h g e k e n n -z e i c h n e t that the transfluxors (5, 6, 7) with parallel fed, output windings (5 ', 5 ", 6', 6", 7 ', 7 ") connected as chokes are provided, where the large output current of a blocked transfluxor is used to identify a Distribution chain output (17, 18, 19) is used, and that each Transfluxor one blocked in the State activated reversing circuit is assigned to the incoming one Counting pulse (20) for setting the transfluxor and at the same time for blocking of the next one evaluates. 2. Distribution chain according to claim 1, characterized in that that the reversing circuit in each case circuits for the setting winding (E 5) of the assigned and contains the blocking winding (B 6) of the next following transfluxor, which via a rectifier controllable from the output potential of the transfluxor (23) are performed. 3. Distribution chain according to claim 1 or 2, characterized in that that the transfluxor outputs with two each operated in push-pull, magnetically counteracting inductor windings (5, 5 ', 6, 6', 7, 7 ') are provided. 4th Distribution chain according to Claim 3, characterized in that the two inductor windings all transfluxors, preferably with the interposition of decoupling diodes (8, 9, 10, 11, 12, 13) parallel to each other at the outputs of one constantly with sufficient high frequency switching switch (U) are switched. 5. Distribution chain according to one of the preceding claims, characterized by the use as Shift register, the dimensioning of the reversing circuit being selected such that the simultaneous flow of current in the control windings (B 6, E 6) of a transfluxor (6) does not change the state. Publications Considered: Electronic Rundschau, 1963, no. 2, pp. 67/68; Electronics, vol 34, 1961, No. 24, pages 62 to 64. Contemplated prior patents. German patent no. 1168 486th.