DE1208255B - Contactless self-controlled oscillator or motor arrangement, especially for time-keeping devices - Google Patents

Description

Contactless self-controlled oscillator or motor arrangement, in particular for time-keeping devices The invention relates to a contactless, in particular over a transistor circuit self-controlled oscillator or motor arrangement, in particular for time-keeping devices, with a magnet arrangement moved relative to a drive coil and a synchronous with this permanent magnet arrangement relatively moved to the coil, at the moment of the drive impulse to the permanent arrangement two coils in and Output circuit of the electronic circuit, in particular the transistor circuit, coupling damping body that decouples in the remaining movement phases made of electrically conductive material.

An electric timepiece is known in which an LC oscillating circuit generator is provided, the coil lying in the input and output circuit of the amplifier are arranged parallel to one another, forming an air gap, through the air gap an electrically conductive disc with a Opening is moved, which when swinging through the air gap between the Coils causes a brief coupling between the coils. In series with the output coil a drive coil with an iron core is connected, which is connected to the aisle folder connected soft iron anchor acts. The known arrangement allows one Auto-start from standstill, however, this is very precisely coordinated of the individual circuit sizes on each other required. The intended soft iron anchor incidentally causes an unfavorable mode of operation, since a drive pulse only passes through magnetic attraction can take place, at least in one direction of oscillation significant braking forces occur. Also there is the coupling between the coils reduced by the air gap, which requires relatively large coils. Even the arrangement of a special drive coil requires a complex and extensive Construction.

An improved transducer arrangement is also already known which carries the pendulum a permanent magnet, which with a single control and the coil representing the drive coil cooperates. Input and output circuit of the electronic amplifiers are connected to each other by an iron core transformer coupled, whose magnetic flux path is interrupted, with by the interruption point a copper disk provided with a radial slot is moved, through which the magnetic circuit is periodically closed and interrupted. These Arrangement is relatively expensive due to the transformer required. Here, too, a precise coordination of the gearshift parameters is essential for a flawless gear each other and a precise adjustment between magnet, damping disc and coils necessary. The known arrangement requires a spatially proportionate one extensive structure.

In a similar circuit arrangement is an electrical oscillator provided, which is periodically moved by a damping disk moved by a pendulum is switched on and off. The generated vibrations are used to control a Flip-flop used, whose output pulses match the oscillating trains of the oscillator are brought to superimposition. These generated impulses become one on the pendulum acting electromagnet supplied.

With this arrangement, which is very complex in terms of circuitry, the above-mentioned Disadvantages not avoided.

In another known oscillator arrangement with relative to one another moving magnet and coil arrangements with iron core is used to generate the drive pulses a magnetic field-dependent resistor influenced by the magnet arrangement is provided. In this arrangement, the disadvantages which are generally known in the case of iron core coils occur Withdrawal forces on. In addition, it requires considerable effort, steep-sided Generate drive pulses. At a standstill there are no impulses at all, but rather only a continuous current can be generated. A self-start is therefore due to the occurring magnetic braking forces hardly possible. It is also a rotary transducer arrangement known, in which a fixed permanent magnet, also a fixed one Coil arrangement and a two-part soft iron armature arranged on the rotary oscillator shaft are provided. The two parts of the soft iron armature are through a magnetic Connection connected to each other, which penetrates the two coils of the coil arrangement. The soft iron armature is provided to allow a magnetic flux passing through the coils to effect and thus a control voltage in the control coil and in the drive coil to cause a drive current. A periodic coupling and decoupling can through the soft iron armature is not carried out, as the concentric to the torsional oscillator shaft Coils are always evenly covered by the iron parts, any different So influencing does not occur. A self-start is thus with such a Arrangement not possible.

In another known arrangement, the drive coil carried by the transducer carries a deflector harness. This shield prevents coupling between the control coil and the drive coil of the circuit arrangement in any case. The screen is only used to change the magnetic flux passing through the control coil. This is done in that the screen short-circuits the magnetic path through the control coil. The known arrangement allows neither a self-starting measurements still a construction with small dimensions.

The invention is based on the object of creating an electrodynamically driven, contactless, self-controlled oscillator or motor arrangement of the type mentioned at the beginning, which enables a good gait, is easy to manufacture and can be accommodated in a small space. The invention is characterized by the use of said arrangement in systems with coaxial direct, i.e. H. practically without an air gap adjacent coils, one of which is inductively applied by the relatively moving permanent magnet system to generate a control voltage and the other causes the drive pulse to the moving system at the output of the electronic circuit, modified in such a way that the electrically conductive damping body is arranged., that it overshoots the coils lying next to each other practically without air gaps on both sides and is designed in the area of the permanent magnet system moving synchronously with it so that it creates the coupling at the moment when the permanent magnet system overshoots the two directly adjacent coils.

The arrangement according to the invention enables steep-edged drive pulses to be generated in the drive position of the oscillator or of the rotor without the need for substantial adjustment work or special coordination of the circuit elements with one another. In this arrangement, in the i zero position of the gear folder or of the rotor, feedback oscillations which act as a driving force arise, so that the arrangement can be started up from standstill. With increasing amplitude or increasing peripheral speed of the arrangement, the control voltage generated by the permanent magnet becomes more effective, whereby the feedback oscillations are largely suppressed and extremely short and steep-edged drive pulses can be generated.

The invention is explained in more detail below with reference to the drawing of an exemplary embodiment. In the drawing, F i g. 1 shows a longitudinal section through an engine arrangement according to the invention, FIG. 2 shows a section along the line II-II of FIG. 1, FIG. 3 shows a plan view of the arrangement according to FIG. 1, FIG. 4 to 9 representations of the impulses that occur.

In the F i g. 1 to 3 , 10 denotes the rotor shaft to which the disks 11 and 12 made of magnetically highly conductive material are attached. The discs 11 and 12 are mitein other connected by the shaft 10 surrounding means 13 of also magnetically highly conductive material. In the vicinity of the circumference of the disks 11 and 12, which are preferably dovetail-shaped, the permanent magnets 14 and 15 are embedded, which are opposite each other and polarized in the same direction, so that a strongly bundled magnetic flux through the air gap formed by them; runs. The distance of the magnets 14, 15 from the circumference of the disks 11 and 12 preferably corresponds to at least half the thickness of the disks. Counterweights 16 and 17 are arranged opposite the magnets 14 and 15 with respect to the shaft.

The disks 18 and 19 are also firmly connected to the shaft 10 and are made of a material with good electrical conductivity, for example copper or aluminum. The disks 18 and 19 contain radially extending slots 20 and 21 through which the magnetic flux of the permanent magnets 14 and 15 passes. In the illustrated embodiment, the poles of the magnets 14 and 15 pass through the slots 20 and 21 in which the discs 18 and 19 and the Magneten14 and 15 air gap formed are the coils 22 and 23 which is not shown in the input and output circuit of an electronic Amplifier are arranged. The coils are preferably arranged closely adjacent and coaxially.

Instead of the counterweights 16 and 17 , permanent magnets can also be provided, in which case the disks 18 and 19 also have slots at these points. The magnetically highly conductive connection 13 between the disks 11 and 12 is then omitted.

The discs 11 and 12 can also be multi-channel, for. B. three-armed or four-armed, each arm or each pair of arms are assigned one or two Pennanentmagneten. The electrically highly conductive disks 18 and 19 can also contain points of reduced conductivity instead of the slots 20 and 21. For example, they can be reduced in cross section at the locations occupied by the slots.

The mode of operation of the arrangement is as follows: The coils 22 and 23, which are located in the input and output circuit of an electronic amplifier circuit (not shown), are so strongly coupled to one another that a feedback oscillation arises. This feedback oscillation is dampened to such an extent by the electronically highly conductive disks 18 and 19 that it breaks off when the slots 20 and 21 are outside the range of the coils 22 and 23 . In the position shown in the figures, the slots 20 and 21 are located in the immediate vicinity of the coils 22 and 23, so that the feedback oscillations set in, which in conjunction with the permanent magnets 14 and 15 on the rotor cause a drive pulse through which, for example, the The rotor is rotated through the angle cc ( FIG. 2). The slots 20 and 21 move out of the area of the coils 22 and 23, as a result of which the feedback oscillations are broken off. The permanent magnet system is now moved in the opposite direction by the spiral spring, not shown, of the torsional vibrator, whereby the slots 20 and 21 in turn reach the area of the coils 22 and 23 . The resulting feedback oscillations now cause a further drive pulse, which deflects the oscillator in the opposite direction.

With increasing amplitude or with increasing peripheral speed of the oscillator, an increasing control voltage is generated in the control coil 22 by the magnetic flux generated by the permanent magnets 14 and 15 , which suppresses the feedback vibrations to an ever greater extent. With full oscillation amplitude, this results in very brief and steep-edged drive pulses, as are desired to maintain isochronism.

In the F i g. 4 to 9 show the resulting impulses. In the zero position of the oscillator, permanent feedback oscillations arise, as shown in FIG . 4 are shown. Ib is the current in the control coil and 1, the current in the drive coil.

In FIG. 5, the impulses i and i occurring at an amplitude of 301 are shown.

F i g. 6 shows the pulses occurring at an amplitude of 90 '.

As shown in FIGS. 7 and 8 , the duration of the pulses decreases with increasing amplitude, e, and the feedback oscillations are increasingly displaced, so that with a normal oscillation amplitude of 270 ' ( FIG. 8), extremely sharp and short-lived acting impulses result in the zero position.

The arrangement can of course also be designed as a motor arrangement, in which case similar impulse images arise.

If the oscillator according to FIG. 1 to 3 rotated 90 ' from its rest position, the coils 22 and 23 are practically currentless, as shown in FIG. 9 can be seen. The currentless state in the coils begins practically as soon as the deflection angle of the oscillator exceeds 301.

Claims (2)

Claims: 1. Contactless, in particular via a transistor circuit self-controlled oscillator or motor arrangement, in particular for time-keeping devices, with a permanent magnet arrangement moved relative to a drive coil and a synchronous with this permanent magnet arrangement moved relatively to the coil, at the moment of the drive pulse to the permanent magnet arrangement two coils in The input and output circuit of the electronic circuit, in particular the transistor circuit, coupling damping bodies made of electrically conductive material that decouple in the remaining movement phases, g e - characterized by their use in systems with coaxial direct, d. H. practically without an air gap adjacent coils, one of which is inductively applied by the relatively moving permanent magnet system to generate a control voltage and the other causes the drive pulse to the moving system at the output of the electronic circuit, modified in such a way that the electrically conductive damping body is arranged in such a way that it overshoots the coils lying next to one another practically without air gaps on both sides and is designed in the area of the perinent magnet system moving synchronously with it so that it creates the coupling at the moment when the perinent magnet system overshoots the two directly adjacent coils. 2. Arrangement according to claim 1, characterized in that the damping body is designed in each case as a disc (18, 19) adjacent to the coils with good electrical conductivity and has at least one area (20, 21) of reduced conductivity through which the permanent magnetic flux passes. 3. Arrangement according to claim 1 or 2, characterized in that the cross section of the damping body or the disc (18, 19) is reduced in each case in the area traversed by the magnetic flux. 4. Arrangement according to claim 1 or 2, characterized in that the damping body (18, 19) or the damping disk each has a radially extending slot (20, 21) penetrated by the magnetic flux. 5. Arrangement according to claim 4, characterized in that the slot (20, 21) is penetrated by in each case one pole of the permanent magnet (14, 15). 6. Arrangement according to one of the preceding claims, characterized in that the damping body or the damping disc (18, 19) is each formed in the shape of a circular ring. 7. Arrangement according to one of the preceding claims, characterized in that two damping bodies or damping disks (18, 19) forming an air gap and a magnet system containing two oppositely directed cylindrical permanent magnets (14, 15) are provided. 8. Arrangement according to claim 7, characterized in that the Perinanentmagnetsystem consists of two with the oscillator or rotor shaft (10) attached magnetically highly conductive disks (11, 12), which in the vicinity of the shaft (11) by magnetically highly conductive means (13) are connected to one another, and that two opposing, co-polarized permanent magnets (14, 15) are embedded in the magnetically highly conductive discs (11, 12), which the slots (20, 21) in the also on the shaft ( 10) put through the attached damping washers. 9. Arrangement according to claim 8, characterized in that the magnetically highly conductive discs (11, 12) are dovetail-like. 10. Arrangement according to claim 8 or 9, characterized in that the permanent magnets (14, 15) are arranged away from the circumference of the discs by at least half a thickness of the magnetically highly conductive discs (11, 12). 11. The arrangement according to claim 8 to 10, characterized in that a plurality of mutually offset permanent systems are provided. Considered publications: German Auslegeschriften No. 1 049 788, 1108 313; Swiss patents Nos. 339 880, 345 831; French Patent Nos. 1187 982, 1 240 208, 1267 353; French additional patent specification No. 70 016 (addition to French patent No. 1 090 564); USA. Pat. No. 2,829,324.