DE1174841B - Transfluxor - Google Patents

Description

Transfluxor Transfluxors are magnetic core arrangements, in which a magnetic core has a plurality of openings and through the main opening of the core, the setting winding and the quenching winding are performed and through the Exit opening of the core, the query winding and the reading winding are performed. The output signal of the transfluxor resulting in the reading winding is dependent the extent of the magnetic adjustment of the transfluxor through the main opening enforcing adjustment winding is effected.

Transfluxor arrangements can be used to remotely control electrical devices be used, with the transfluxor arrangement arranged on the device to be remotely controlled is and the remote control device for triggering various control processes on the remote controlled Device generates signals of different signal amplitudes. You can do this in the transfluxor arrangement the state of extinction, the quarter setting of the magnetic flux, utilize the half-setting, and accordingly these magnetic flux settings The transfluxor output signals are generated in various ways act on the device to be remotely controlled. It is in the nature of the remote control that the control pulses fed to the remote-controlled device are not precisely metered occur at the same.

But if the setting impulses of a transfluxor are not precisely dosed If the setting current tolerances are too large, it can easily lead to a match of the transfluxor, which then leads to incorrect results when queried. For example, the control pulse intended to generate a half-setting performs due to too high amplitude to a three-quarter adjustment of the magnetic flux of the Transfluxor cores, an incorrect control process results because the output signal of a Breiviertel adjusted transfluxor core is the same as it is with would result in a one-quarter adjustment of the magnetic flux of the transfluxor core.

The aim of the invention is to resolve ambiguities of this type caused by a Adjustment of the transfluxor may result.

A transfluxor whose output signal depends on the extent of its Setting and having a plurality of openings in such a way that through the Main opening, the setting winding and the quenching winding are guided and through the Exit opening, the query winding and the reading winding are performed, identifies according to the invention in that a short-circuit winding by another Opening of the transfluxor core is performed, which is an alignment of the transfluxor core due to switching of the magnetic flux in the one enclosed by the mentioned winding Magnetic core leg prevented.

The transfluxor cores used in the context of the invention consist in the usual way of a magnetic material, which is a rectangular Has hysteresis loop; the generally ring-shaped core usually consists made of ferrite, although a proposal has already been made, rolled steel strip to be used for the production of transfluxor cores.

An embodiment of the invention is related in the description discussed with the figures. Of the figures, FIG. 1 to 3 magnetic cores whose Magnetic flux is set so that it is in the state of extinction or the quarter setting or the three-quarter setting, F i g. 4 a transfluxor circuit according to the invention, F i g. 5 a transfluxor magnet core, which is in the state of one-half adjustment is located.

The in the F i g. Magnetic core 30 shown in FIGS. 1 to 3 has a central opening 10, also called the main opening, through which a not shown in the figures Turn can be performed; which serves the purpose of maintaining the magnetic state of the core to influence. Such a winding can, for example, be a quenching winding and excited by a pulsed current so that the magnetic flux around the core is polarized in one direction, for example polarized in the clockwise direction will. Another winding called the setting winding can serve the purpose of creating a polarization of the when pulsed currents are supplied To effect magnetic flux in the reverse direction. The strength of the magnetic flux, whose polarization direction is reversed depends on the amplitude of the signal which is fed to the setting winding. To determine this amplitude value, d. H. in order to generate an output signal which provides an indication for this an alternating current that can reverse the polarization of the magnetic flux, one in Inquiry winding, not shown in the figures, is supplied, the inquiry winding extends through a smaller opening 34, commonly referred to as the exit opening of the nucleus. The query winding is magnetic due to the material of the The core is coupled to the output winding, which is also not shown in the drawings is shown and extends through the opening 34 so that the reverse of the Polarization of the magnetic flux caused by the alternating current in the part of the core, which lies between the outer edge and the opening 34, is brought about Alternating current is generated in the output winding, this current having an amplitude which is proportional to the strength of the switched magnetic flux. This quantity of the magnetic flux corresponds to that part whose polarization direction thereby was reversed, that a signal was fed to the setting winding, and hangs therefore depends on the signal.

In Fig. 1, the core 30 is in the quenching state, in which the entire flow around the opening 10 is polarized in a clockwise direction, as indicated by the arrows 32. In the quenching state, no magnetic flux can be switched around the opening 34 by an alternating interrogation current, since the polarization has the same direction on the inside and on the outside of the opening 34.

F i g. 2 shows the core 30 in a state in which e.g. B. a quarter of the magnetic flux surrounding the opening 10 is polarized in the opposite direction. This state will be called the quarter excitation state in the following. In this condition three quarters of the magnetic flux is polarized in the clockwise direction as indicated by arrows 32 and one fourth is polarized in the counterclockwise direction as indicated by arrows 36. For this reason, the alternating current used for interrogation can do a quarter of the flow to switch the opening 34 around. The same magnetic raft can also be switched when the core 30 is in a state in which three quarters of the magnetic flux, as shown in FIG. 3 shows is polarized in the reverse direction; this polarization state is called three-quarter excitation. The output obtained in the three-quarter excitation condition is the same as that in the quarter-excitation condition. This results in an ambiguity when an output signal is received which is due to the switching of a quarter of the magnetic flux.

The mode of operation of an arrangement according to the invention is shown in FIG. 4 and 5 explained.

The in F i g. 4 shown memory arrangement allows one of to store several different signal amplitudes. One core with several Openings is shown in perspective. F i g. 5 shows the in FIG. 4 shown Core in its magnetic state.

The in F i g. Magnetic core 12, shown in FIG. 4 and having a plurality of openings, consists of a material which has a substantially rectangular hysteresis loop. The core 12 has a central opening 14 and an application exit opening 16 and an auxiliary opening 18. Each of the openings 16 and 18 has an axis that is perpendicular to the plane of the core. Each opening lies midway between the inner surface 100 and the outer surface 101 of the core 12, so that a magnetic flux of essentially equal strength can be formed on the inner side and the outer side of the openings 16 and 18 .

The central opening 14 is penetrated by the canceling winding 20 and the setting winding 22. The windings 20 and 22 are energized at given times by current pulses such as those shown in FIG. 4 shown curve shapes correspond. F i g. 4 shows that the erase pulse is positive and lasts longer, but has a lower amplitude than the negative adjustment pulse. These current pulses are referred to below as the erase pulse and the setting pulse. The amplitude and duration of the erase pulse are such that the core 12 is saturated at the end of the erase pulse, with the entire magnetic raft directed around the central opening 14 in a counterclockwise direction. This state of the magnetic flux will be referred to as an erased state of the core 12 hereinafter. A setting pulse which is fed to the winding 22 polarizes part of the magnetic flux in the opposite direction, the amplitude of the setting current pulse characterizing the portion of the magnetic flux which is switched in this way. This reversed part of the magnetic flux will be referred to below as the set magnetic raft. At most, half the magnetic flux can be reversed, as discussed below.

The interrogation output winding 24 extends through the opening 16 and is excited by an alternating current used for interrogation, this current having such an amplitude that the magnetization around the opening 16 is reversed if such a magnetic raft is located there, which can be reversed, ie if the Transfluxor is set. In this case, a corresponding alternating voltage is induced in an output winding 26 which passes through the opening 16, which alternating voltage is proportional to the amount of the tone-switched magnetic flux. The portion of the magnetic flux that can be switched in this way with respect to its polarization direction is referred to as the set magnetic flux.

A current path of low ohmic resistance, which is only a fraction of an ohm under practical conditions, is formed by the short-circuit winding 28, which consists of a short piece of copper wire and extends through the opening 18 and encloses the part 29 of the core which between the Outside 101 and the opening 18 is located.

F i g. Figure 5 shows that the core 12 is fully adjusted because half the magnetic raft is polarized clockwise around the central opening 14 and the other half polarized counterclockwise. The magnetic flux, which is polarized in the clockwise direction, is indicated by the arrows 32 and the magnetic flux polarized in the counterclockwise direction is indicated by the arrows 36. which is still polarized clockwise to reverse, such a sudden reversal of the polarization of the magnetic flux denoted by 32 in part 29 is associated with the occurrence of a strong current impulse in the conductor 28, so that a magnetic field is generated which corresponds to such a reversal Counteracts polarization. Therefore, a setting current pulse, even at its maximum value, cannot reverse the polarization of the magnetic flux in the part 29 , so that at most half the magnetic flux in the core 12 can be polarized in the counterclockwise direction. If the setting current pulse has less than half its peak value, then only correspondingly less magnetic flux is polarized in the counterclockwise direction. Because the state of the core. 12 the half-excited state of the core 30 of FIG. 1 to 3, the ambiguity discussed above cannot arise when reading the core 30.

Since the conductor 28 has a certain ohmic resistance, the Polarization of the entire magnetic flux in the part 29 can thereby be reversed, that a setting current of a sufficiently long duration is brought into effect. Under In practical terms, however, the duration of the setting current pulse is small, and there is no such reversal of polarization. But it can be beneficial a long duration erase pulse may be used for the purpose of removing all of the magnetic flux to redirect in part 29 in the clockwise direction or in this direction keep.

The current induced in conductor 28 is proportional to the change of flux 0 in part 29. If the change in magnetic flux is sufficiently slow, as is the case with the long erase pulse, a small current is induced in conductor 28 and therefore it is not prevented that the entire flux of the part 29 is switched.

Claims (4)

Claims: 1. Transfluxor, whose output signal is dependent on the extent of its adjustment and which has a plurality of openings, whereby the adjustment and extinguishing winding is passed through the main opening and the interrogation and reading winding is passed through the output opening, characterized in that one Short-circuit winding (28) is passed through a further opening (18) of the transfluxor core (12) , which prevents the transfluxor from overlapping as a result of switching the magnetic flux (32) in the magnetic core leg (29) enclosed by the said winding (28). 2. Transfluxor according to claim 1, characterized in that the core (12) is annular and the axes of the output opening (16) and the by the short-circuit winding (28) penetrated additional opening (18) the same distance from the outer surface (101) of the Core (12) . 3. Transfluxor according to claim 1 or 2, characterized in that the output winding (26) and the short-circuit winding (28) each enclose the outer leg between the openings (16, 18) and the outer surface (101) and the query winding (24) The inner leg of the core (12) encloses. 4. Transfluxor according to claim 1 or one of the following, characterized in that in the quenching state the entire magnetic flux (32) of the core is polarized in one direction. 5. Transfluxor according to claim 1 or one of the following, characterized in that the erasing pulse (20) supplied to the core (12) is of greater duration than the setting pulses used for information storage purposes. Considered publications: "Proceedings of the IRE", Vol. 4, issue 3, March 1956, p. 321 to 332; »Frequency«, 1957, issue 1, Pp. 19 to 27.