DE1673670C - Electric clock with magnetic drive of a pole wheel - Google Patents

Description

The invention relates to an electric clock with a time-determining mechanical oscillator that is excited to oscillate in its natural frequency, which carries a magnet system to drive the clock, the poles of which are essentially diametrically opposed to each other Facing a non-magnetized, ferromagnetic pole wheel, and the these poles are moved essentially radially to the pole wheel, which is caused by the movements of the magnet system in rotations that are synchronous with the movements of the oscillator.

Such clocks are for example from the Swiss patent 421 830, the French Patent documents 1351427 and 1372 513 and the U.S. Patent 3,212,252. In these known clocks, the pole wheel consists of a punched out Disc made of sheet iron, which has radially protruding teeth on its circumference and also a wreath of radial webs that are offset from the teeth and cut from each other through recesses are separated. There are therefore two concentric rings of poles in the known pole discs provided, which are arranged on a gap. The production of such discs is relatively difficult, because the punching tools have a large number of needles and corresponding openings in the die need, which are difficult to manufacture, especially given the required trapezoidal shape are. There is also the risk that the needles of such tools because of their small cross-sections break off easily.

Another clock known from British patent specification 1033 342 also has two Wreaths of mutually offset poles are provided, which can be seen from the elevations of a disk from a magnet High permeability material can be formed. Such a disk is also being manufactured very difficult.

The pole is on another clock known from Swiss patent specification 362441 of a magnet opposite the sinusoidally corrugated edge of a ferromagnetic disc and is moved perpendicular to the Schcibcnebcnc with the help of a plate oscillator. Since there are no pronounced

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Poles are present, the synchronization forces are only driven pole wheel, the one with two concenches is very small, so that the disk can easily fall out of step with fresh wreaths of mutually offset poles and additional means for stabilizing len are considered to be the simplest. In the case of the known clock, a flywheel has to be provided for this purpose and the other of the known devices. Of 5 voltages are also preferable because they have a particular disadvantage, however, that the magnet does not alternate on the disk and its bearing - The invention is based on the object, the Herbenwelle can guide and to simplify the bearings for this shaft position of the pole wheel, to a considerable extent unilaterally loaded, so that ίο without affecting the favorable properties of the pole a special design of the bearing is required wheels with two concentric wreaths against each other-Nevertheless this influences changing and one-sided the offset poles to have to do without,
Directional bearing friction the speed of the known This task is disadvantageous according to the invention and leads to a quick release that the pole wheel in itself from magnetic wear. i ₅ escapements in a known manner on its circumference. Furthermore, the German patent specification has only one pole ring and that the poles of the 1 199 703 a clock is known in which a .Stabmagnet magnet system are arranged so that it oscillates perpendicular to the edge of a disc , the one point of the pole wheel between two poles of the self is magnetized in such a way that they stand along their pole wheel when they alternate opposite poles at the diametrical point on the circumference. The 20 face one pole of the pole wheel.
The manufacture of polarized disks of this kind is relatively expensive and requires disks of considerable thickness, which only have a ring of poles with a greater thickness, so that magnetization is transverse to the disk, and is therefore much easier to manufacture is possible. Furthermore, the magnet, which has been used up to now in electrical clocks, is radially directed onto the disk as the magnet.

one-sided forces, which with regard to the position, nevertheless the required drive torque is

tion of the discs aims at the above disadvantages because of the arrangement according to the invention

to have. of the magnet system here too at the same time

Pole disks of the known type described above, the distance between the magnet system and

th type, the two wreaths offset from one another 30 the one pole is enlarged, the distance to the

Have poles, except for clockwork drives, the next pole is reduced and therefore the next

which are attracted to the following pole by the oscillating magnet. As a result, will

Pole disk a drive torque is exerted, also by the invention without impairing the

known from magnetic escapements, a significant simplification in terms of accuracy

which the pole discs are driven, while the 35 is aiming.

Oscillators show no self-excitement. Such The desired arrangement of the poles of the magnet arrangements are known, for example, from the German systems with regard to the poles of the wheel can be found in patents 809420, 954944, 1171 824, 1171 825, for example by a corresponding offset of the and 1 231 176. The German patent specification axis of the pole wheel opposite that through the poles 809 420 also shows the application 40 of the Magriet system can be reached, a sinusoidally corrugated disk at its edge. In a preferred embodiment of the invention with a magnetic escapement. It should be noted, however, that such a corrugated edge also forms two rings of poles offset from one another by the axis of the pole wheel, and that it points to the pole wheel The pole wheel has an odd number of poles at the apex of the wave-shaped 45.
In a further embodiment of the invention it is possible to handle the pole wheel with radially protruding poles. Provided from the German Auslegeschrift, the ends of which are angled in the direction of rotation of the pole wheel 1 177 077 and the USA.-Patent 3 132 522. Particularly preferred is a magnetic escapement with a pole embodiment, in which the poles of the pole wheel, which has only one pole rim, approach their ends with a direction of rotation, but approach or move away at these anchors, at right angles protruding approach provided orders the poles of a horseshoe magnet are equal. In this way, a transition from one pole to the other opposite pole of the disk, which is particularly at the same time one or two diametrically opposed to one another, is created. It occurs there so that the wheel runs very smoothly and the interaction that has not yet occurred as is the case with the required, on the shafts of the pole wheels with known drives, namely that centrifugal masses arranged for low friction are dispensed with at the same time how to become the magnetic pole of the Hch. With the correct dimensioning of the removed disc pole, if the opposite end of the pole is approached, it is even possible to approach an offset disc pole and thereby force the self-start-up. Exercises in this possible moment of expulsion. Therefore, this known design is still a particular advantage of arrangements not suitable for a drive of the invention.

moment on the pole disc, and are there- For the shapes of the oscillators and the magnether There are many possibilities only with magnetic escapements, but not arrangements. So In the case of watches with a magnetic drive, for example, a hoof gait can be found on the oscillator described type can be used. iron magnet be attached, which is in a pole-off from the foregoing it follows that the plane extends from all the wheel and its poles denote the known electrical clocks with magnetically positioned diametrically opposed positions of the pole wheel

survive. But it is also possible to attach two horseshoe magnets to the transducer, which each extend in a plane perpendicular to the pole wheel and the poles of which the pole wheel each to the Include diametrically opposed locations between them. The latter arrangement is special advantageous because then, apart from the torque, there are no forces acting on the PoI-i from the magnet system ad be exercised. The magnets can be attached to the end of a vibrating tongue, if necessary from one leg of a tuning fork can be formed, the other leg one carries the corresponding counterweight. But it is also possible to have magnets on the two legs to attach a tuning fork. »5

The pole wheel itself can, for example, consist of a toothed disc made of ferromagnetic material, in particular made of sheet iron. Such a disk can be punched out of sheet metal in a simple manner. Any needles for making ao openings, apart from a central one opening for the hub are then not required. But it is also possible to make the pole wheel from a non-magnetic Manufacture material and provide it with ferromagnetic inserts, for example with radially or axially arranged pins.

Further details of the invention can be found in the following description in which the invention described and explained in more detail with reference to the exemplary embodiments shown in the drawing will. It shows in a schematic representation

F i g. 1 is a plan view of a first embodiment of the invention with a flat magnetic bracket, the ends of which are diametrically opposed to each other on the pole wheel,

F i g. 2 shows a side view of the embodiment according to FIG. 1 in the direction of arrow II,

F i g. 3 is a plan view of a further embodiment of the invention with two horseshoe magnets at the ends of a U-shaped beam,

F i g. 4 shows a side view of the arrangement according to FIG. 3 in the direction of arrow IV,

F i g 5 the arrangement of a magnet system on a blade transducer,

F i g. 6 the arrangement of a magnet at the end of a leg of a tuning fork,

F i g. 7 is a plan view of another embodiment of the invention with horseshoe magnets the ends of both legs of a tuning fork,

F i g. 8 is a side view of the embodiment according to FIG. 7 in the direction of arrow VIII,

F i g. 9 shows a plan view of a further embodiment of the invention with a pole wheel with a right angle angled teeth and

10 shows an embodiment similar to FIG. 9 with obliquely angled teeth.

In the embodiment according to FIGS. 1 and 2 is at the end of a mechanical oscillator 1, the movements in the direction of the double arrow 2 is able to carry out a magnet arrangement, which consists of a short bar magnet 3 and an essentially U-shaped magnet yoke 4, the ends 5 and 6 of which are angled inward so that they are on a direction of oscillation 2 parallel straight lines 7 face at a distance. Between the hands 5 and 6 of the magnet yoke 4 a pole wheel 8 is arranged, which has an even number of radially protruding teeth 9, which are the poles of the Form the wheel. The pole wheel 8, like the magnet yoke 4, can be made of a ferromagnetic sheet metal high permeability be punched out. The arrangement is made so that the yoke 4 and the pole wheel 8 lie in closely adjacent parallel planes and the outer diameter 10 of the pole wheel is slightly larger than the distance between the ends 5 and 6 of the yoke. Furthermore is the axis 11 of the pole wheel offset so far from the center line 7 of the yoke ends S and 6 that one end, z. B. the end 6, is between two teeth 9 of the pole wheel when the other end 5 is a pole 9 facing, or vice versa.

The pole wheel 8 is located counterclockwise, i.e. in the direction of arrow 12 in Rotation and swings in the moment shown, the oscillator 1 from the communication position to the left, the tooth of the pole wheel located in the area of the left end 5 of the magnet yoke is released, while the tooth tapering towards the right end 6 of the yoke is attracted by this end and is accelerated. If the transducer then swings beyond its central position to the right, so the tooth just attracted by the right end of the pole piece is released again and instead, the following tooth is drawn into the area of the left end of the magnet yoke. In this way, the pole wheel 8 is indexed in synchronism with the oscillating movements of the oscillator 1 and can be used in a known manner to drive a pointer mechanism, which is not detailed in The manner shown is connected to the shaft 13 of the pole wheel.

In this embodiment of the invention, which is characterized by particular simplicity, is the pole wheel is loaded in the axial direction. However, it is possible to avoid this axial load by 7u, that two magnet yokes 4 are used, on both sides of the magnet 3 and at the same time on both sides of the pole wheel 8 are arranged.

The embodiment according to FIGS. 3 and 4 differs from the embodiment according to FIG the F i g. 1 and 2 in that a U-shaped bracket 22 is attached to the free end of the oscillator 21 is, which at its two ends 23 and 24 each carries a horseshoe magnet. These horseshoe magnets lie in a plane perpendicular to the pole wheel 25 and are arranged so that the teeth 26 of the pole wheel between the poles 27 and 28 of the magnets. Furthermore are in this Fall, the poles of the magnets are arranged in a plane 29 which intersects the axis 30 of the pole wheel. So that the poles of the one magnet, in the drawing of the magnet 24, between two The teeth of the pole wheel are in place when the poles of the other magnet are opposite the teeth of the pole wheel, the pole wheel has an odd number of teeth.

The mode of operation of this drive is the same as that of the embodiment according to FIGS. 1 and 2, but the magnetic circuit does not extend diametrically over the pole wheel, but only runs through the teeth of the pole wheel between the poles of each of the two magnets. It would therefore also be possible, instead of a pole wheel made of magnetic material, a pole wheel made of non-magnetic material use, are inserted into the corresponding poles made of magnetic material. With this magnet

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arrangement, there are no radial positions on the pole wheel of the tuning fork, the poles of the or axial forces exerted. The magnets 23 and 41 at the outer ends and the poles of the 24, magnets 42 attached to the U-shaped bracket 22 can be attached to the inner ends of the pins 48 be or immediately from the magnetized ends. This arrangement is necessary so that when -this bracket is formed. S The magnets oscillate against each other and the magnet

As in Fig. 5 indicated schematically, the pole can alternate between the poles of the disk 43 the U-shaped magnet assembly 31 supporting reach or step out of them. The application oscillator 32 is formed by a rod or plate oscillation of a non-magnetic disk with an insert, for example a leaf spring. The pole is particularly advantageous here because then which is clamped at its other end. It is io the right magnet 42 while swinging inside but also possible, as shown in FIG. 6 showing no magnetic material between its poles U-shaped magnet arrangement 31 on the one encloses what would otherwise dampen the moving legs 33 of a “tuning fork”, the movement of which could lead to the pole disc 43. Otherwise other leg 34 with a counterweight, this arrangement also works as it does on hand 35 is provided. In both cases, the FIG. 1 and 2 has been described. excitation of the oscillator in not shown. The arrangements according to F i g. 9 and 10

and in a manner known per se with the help of electromagnetic speak essentially according to the Ausfühningsfonn table arrangements, the components of eleklro- den F i g. 3 and 4, but the pole wheels have one niche vibrators. different tooth shape. In the embodiment

In the embodiment according to FIGS. 7 ao according to FIG. 9, the ends of the teeth 51 of the pole 8 and 8 are provided with lugs 53, similar to the design washer 52, which have right-angled play according to FIGS. 3 and 4, in turn, two hoofs protrude from the teeth 51 and are in the Iron magnets 41 and 42 use, which extend in the direction of rotation 54 of the pole wheel. To this Pole wheel 43 are perpendicular planes and their manner is achieved that when the pole poles 44 and 45 rotate, the pole wheel is sandwiched between them as disk 52 synchronously with the vibrations of the dimensions. In contrast to the embodiment aach gnetsystems 55 in each case the front edge 56 of the Andes F i g. 3 and 4, however, the magnets 41 and 53 are attached to the ends of the legs 46 and 47 of a tuning fork opposite the pole pieces 57 of the magnet system. This arrangement has the stands. This acts on the teeth 51 of the pole wheel Advantage that both legs of the tuning fork do 30 52 exert a driving moment and cause a Sta-rotation of the pole wheel 43 and therefore achieve the bilization of the rotational movement of the pole wheel. Tuning fork is less damped. As a result, there is no need for additional measures, there is a better degree of efficiency here. falling out of step or even standing still

The pole wheel 43 again has an odd tooth rotor in the event of shocks and torsional vibrations number, and the poles 44 and 45 of the magnets 41 and 35 should prevent.

42 move in a plane which is defined by the axis instead of as in the embodiment according to FIG. 9

of the pole wheel goes. In this case, the pole wheel can, as shown in FIG. 10 shown, the teeth 61 of designed as a non-magnetic disc, in which as pole disc 62 at their ends 63 also obliquely in Pole serving radial pins 48 are inserted. Wei- direction of rotation 64 be angled. Also because of this Therhin the pole wheel 43 relative to the central axis 40 is a stabilization of the rotational movement of the Ro-49 of the tuning fork so far laterally offset that achieved in tors.

For this purpose 2 sheets of drawings

909638/23

Claims (13)

Patent claims: 1. Electric clock with one in its natural frequency time-determining mechanical oscillator that is excited to oscillate and carries a magnet system to drive the clock, its Pole two mutually essentially diametrical points of a non-magnetized, ferromagnetic Face the pole wheel, and which moves these poles essentially radially to the pole wheel, which is set in rotations synchronous to the movements of the oscillator by the movements of the magnet system, thereby characterized in that the Poirad (8) is known per se from magnetic escapements Way on its circumference has only one pole ring (9) and that the poles (5 and 6) of the magnet system (3,4) are arranged so that they are at one point of the pole wheel between there are two poles of the pole wheel when they face a pole of the pole wheel at the diametrical point (Figures 1 and 2). 2. Clock according to claim 1, characterized in that the pole wheel (8) is known per se Way has an even number of poles (9) and the axis of the pole wheel opposite the is offset by the poles (5 and 6) of the magnet system going plane (Fig. 1). 3. Clock according to claim 1, characterized in that the poles (27 and 28) of the magnet system (22, 23, 24) in a manner known per se in a through the axis (30) of the pole wheel (25) going plane (29) are arranged and that the pole wheel has an odd number of poles (26) (Figs. 3 and 4). 4. Clock according to one of the preceding claims, characterized in that the pole wheel (62) has radially protruding poles (61), the ends (63) of which in the direction of rotation (64) of the pole wheel are angled (Fig. 10). 5. Clock according to one of claims 1 to 3, characterized in that the poles (Sl) of the pole wheel (52) ai. ^; Their ends are provided with a projection (53) extending in the direction of rotation (54) and protruding at right angles (FIG. 9). 6. Clock according to one of the preceding claims, characterized in that on the Oscillator (1) a horseshoe magnet (3, 4) is attached, which is parallel to the pole wheel (8) Plane extends and its poles are opposite to the diametrical points of the pole wheel (8) (Fig. 1 and 2) 7 o'clock after one de; Claims 1 to 5, characterized in that on the oscillator (21) two horseshoe magnets (23 and 24) are attached, each one facing the pole wheel (25) extend perpendicular plane and their poles (27 and 28) the pole wheel each to each other Include diametrical points between them (Fig. 3 and 4). 8. Clock according to claim 7, characterized in that the magnets (23 and 24) to the Linden a U-shaped carrier (22) are arranged (Fig. 3). 9. Clock according to one of claims 6 to 8, characterized in that the magnet system (31) is attached to the end of an oscillating tongue (32) (Fig. 5). 10. Clock according to claim 9, characterized in that the oscillating tongue of a Leg (33) of a tuning fork is formed, the other leg (34) of which a corresponding one Balance weight (35) carries (Fig. 6). 11. Clock according to claim 7, characterized in that the oscillator of a tuning fork is formed and the magnets (41 and 42) each on a leg (46 or 47) of the tuning fork are attached (Fig. 7). 12. Clock according to one of the preceding claims, characterized in that the pole wheel by a toothed disc made of ferromagnetic material, in particular made of sheet iron, is formed. 13. Clock according to one of claims 1 to 11, characterized in that the pole wheel (43) consists of a non-magnetic material with ferromagnetic inserts (48), in particular radial or ax ^; Al arranged pins, is provided (Figs. 7 and 8).