DE1497253A1 - Free-floating mount of a runner with a vertical shaft, especially the runner of an induction electricity counter - Google Patents

Description

Free-floating mounting of a rotor with a vertical shaft, in particular of the runner of an induction electricity meter For the runner of an electricity meter and other vertical shaft rotors are magnetic levitators in many Execution forms known. As a rule, they are paranagnetic floating bearings, the magnetic attraction or repulsion force of a permanent magnet on one act on a paramagnetic body. Usually the paramagnetic body is on the rotor shaft and the permanent magnet are fixed - also the reverse Arrangement is possible and known - in such an arrangement that the Part attached to the rotor shaft including the rotor by the magnetic forces in the levitation is held. Guide bearings are used to stabilize the rotor shaft transversely for the wave.

Magnetic levitation bearings are also known to control the levitation state enable without guide bearing (German patents 976 997 and 1 195 861). At. this is on the rotor shaft instead of a paramagnetic float diamagnetic float in ring shape in the magnetic field of a permanent magnet in pot magnet shape arranged. The diamagnetic float is driven by the magnetic field of the stationary Permanent magnets not only pushed upwards, but due to the ring shape of the float and magnetic field at the same time, min centered in all radial directions and thus transversely stabilized. However, diamagnetic forces are compared to paramagnetic Forces extremely small. So if the limbo of a runner is eliminated is to be achieved with diamagnetic forces, the weight of the runner may including the float, can only be very small.

For this reason, there is one known embodiment Induction electricity counter with diamagnetic floating bearing (German Patent specification 1 195 861) the diamagnetic float made of a graphite ring. Since graphite is not only diamagnetic, but also electrically conductive, forms the graphite ring in its case at the same time also the inductively driven rotor of the counter. If the rotor is heavier, however, diamagnetic forces are only in Combination with a paramagnetic levitation bearing applicable by adding a paramagnetic effective floating bearing compensates the weight of the runner, i.e. exclusively exerts a longitudinal force in the axial direction of the rotor, and the diamagnetic Means practically out Finally, for the transverse stabilization of the rotor shaft dic-nen. Even in this case, however, diamagnetic stabilization is required still a considerably large permanent magnet.

A paramagnetic floating bearing has also been proposed (Patent application S 98 330 Ixa / 47i; our sign PLA 65/1475), dei which the transverse stabilization of the rotor shaft is achieved as follows: The weight of the rotor is in turn with compensated for paramagnetic forces, - while at the lower end of the rotor shaft a ninde sisease disk arranged over a small DC-excited pot magnet that pulls the @chei be downwards with little force.

This downward force is only so small that it acts on the means of the paramagnetic Schwebelager has practically no influence. The excitation development the pot magnet is preceded by a control device that reacts to changes in the height of the Shaft responds and the force of attraction of the magnet is constantly constant Regulates the height of the runner. For example, one serves as the control means electric field plate in the field of the paramagnetic levitation bearing. At this facility a cross stabilization is established by means of the iron disk at the lower end of the rotor shaft of the rotor shaft is achieved similarly to the above-mentioned diamagnetic ring.

The invention also relates to a free-floating mount a rotor with a vertical shaft, in particular the buyer of an induction electricity meter. with a magnetic floating bearing holding the rotor in the balance and with stabilizing means to maintain the floating rotor in its vertical position. she solves but the problem of transverse stabilization according to the invention through the use of Stabilizing agents acting in a manner known per se by Thomson force. to The following considerations have led to this solution: As Thomson force is. appearance known that an inhomogeneous magnetic field is electrically conductive, non-magnetic body pushes away from you. In the case of induction electricity meters, for example, the magnetic field exerts itself of the drive systems, that of the generation of the drive torque of the roller disc of the counter is used on this carrier plate both in the vertical and in the horizontal Direction Thomson forces, and it is already known to have a counter with special To provide means that compensate for these undesirable Thomson forces.

For the obvious demonstration of the Thomson effect, it is known to use a Pot-shaped electromagnet with high-frequency magnetic poles pointing upwards to excite and in the ring-shaped high frequency field of the magnet a small ring from e.g. To make aluminum or copper float. You have to use high frequency apply, since the Thomson force depends on the sequence, and there is a network frequency from Z. r. 5 50 qz would result in insufficient forces. only suspension bracket for a runner, for example with an electricity meter, so the Thomson force cannot be used, because one sets. u with a meter there is usually no high frequency available, and because, on the other hand, the Thomson force at mains frequency is too small to support the weight of a runner to be able to compensate.

However, the invention is based on the following knowledge: If you, how in the case of one of the known floating bearings mentioned, for floating the rotor magnetic means, in particular a paramagnetic levitation bearing, are used, so a Thomson force can not only stabilize the runner laterally, even at 50 Hz can be used at least as well as in the case of the floating bearing mentioned above diamagnetic forces, but even with a considerable advantage this: The magnetic body can when using the Thomson force instead of a diamagnetic Force can be much smaller, and it can even keep the force constant Elevation of the runner an electricity meter regardless of its load can be achieved without the need for additional funds.

On the basis of an exemplary embodiment shown in FIG. 1 of the drawing the free-floating bracket according to the invention is explained in more detail. In Fig. 2 up to 4 of the drawing are possible modifications and advantageous further developments shown in this bracket.

In Fig. 1, the levitated rotor of an electricity meter is made from the rotor disk 1 and the rotor shaft 2.

The carrier plate 1 are two drive systems 3 and 3 in a known manner 4 assigned. At the top of the rotor shaft are two small cylindrical permanent magnets 5 and 6 in the field of a fixed annular permanent magnet 7 attached. the Magnets 5 to 7 form a paramagnetic levitation bearing in a known manner. at the Plotted polarity of these magnets is the magnet 5 from Magnet 7 pulled up and magnet 6 pulled down. The size and the strength of the magnet 6 is smaller than that of the magnet 5, so that the upward force prevails and keeps the runner in suspension. The magnet 6 is used to adjust this outward force and is therefore advantageous, e.g. by means of thread, adjustable in height.

A stabilizing body 8 is located at the lower end of the rotor shaft 2 in the form of a disk made of electrically conductive but non-magnetic material, e.g. made of aluminum. This is located a short distance above a pot magnet 9, which is provided with an excitation winding 10. The middle 'core of the pot magnet 9 is widened with an attached pole disc, so that between this Pole disc and the wall edge of the pot magnet an annular magnetic field concentrically forms to the axis of the rotor shaft.

The excitation winding 10 is connected to an alternating current network 11, to the voltage coils of the drive systems 3 and 4 in the illustrated case are connected. In itself, however, the excitation winding 10 could also be connected to an independent one l AC voltage source must be connected.

If the excitation winding 10 is live, the stabilization becomes £ body 8 from the field of the magnet 9 in a known manner according to the Thomson effect upwards pushed. At the same time, however, the annular field exercises on the stabilization body 8 also a transverse stabilization in all radial directions and thus a centering the end. Since that Weight of the runner alone due to the weight of the parts 5 to 7 existing paramagnetic levitation bearings can be compensated the pot magnet 9 only needs to apply the Thomson force required for stabilization, so that it can also be correspondingly small.

In Fig. 2 and 3 are modified in shape stabilizing body 8 shown above a magnet 9. In Fig. 2 the stabilizing body has the shape a disc with a downwardly directed edge bead.

The bead of the hand has a trapezoidal cross-section, as does the ring gap of the IZagneten, into which the edge bead is immersed, which creates a special good lateral stabilization results. For diamagnetic floating bearings, this is the characteristic the trapezoidal shape of a weave body has already been suggested elsewhere. Even in Fig. 3 the Stabilisierungskörpe r 8 has a downwardly directed edge bead on, this is formed here by an attached ring of round cross-section.

Since in Fig. 1, the excitation winding 10 of the magnet 9 on the same The voltage source is like the voltage coils of the drive systems 3 and 4 of the meter ; so is the Thomson stabilization device consisting of parts 8 and 9 always effective as long as the voltage is applied to the meter, i.e. as long as the meter is ready for operation is and counts. The effect of the magnet 9 is only canceled when the voltage fails. Since the Thomson force acting upwards on the runner is reduced - that is the case The parts 5 and 7 bestekende paramagnetic swivel bearings remain voltage independent g effective -so the stabilizing body 8 can under certain circumstances hit the magnet 9 and possibly lead to damage. To prevent this can, according to FIG. 4, a support bearing at a small distance below the rotor 12 can be provided on which the rotor can sit in the event of a power failure.

The drive systems of induction meters consist, as in Fig. 1, from a voltage part and a current part. Usually there is one of these two parts above and the other below the carrier. Which of the two Parts are located above or below, is for that on the carrier of the counter to be exerted drive torque in itself is indifferent. When using a free-floating bracket according to the invention is eo advantageous, the arrangement to meet so that the electromagnet of the stabilization device and the Voltage part of the drive system or systems of the meter on opposite sides Sides of the carrier are located, as is the case in FIG. 1. The ones from the magnets of the tension parts on the armature disk and thus on the armature in the paraxial axis In this case, the Thomson forces acting in the direction are the Thomson forces of the stabilization device in the opposite direction, so that the altitude of the floating runner is largely independent of the voltage is.

The altitude of the hovering runner can, if necessary, also can be made independent of current, as ~ ea in another patent (patent application the applicant of the same days) is described.

All that is required for this is an additional attachment of a cup-shaped Electromagnet coaxial to the rotor shaft required, the one on the opposite one Side of the disc like the current iron of the drive systems is proportional to the current of the counter is excited and on the carrier in the axial direction of the rotor exerts a compensatory force.

4 Figures 7 claims

Claims (7)

Claims: Free floating bracket for a runner with a vertical Shaft, in particular the rotor of an induction electricity meter, with a Magnetic levitation bearings holding the rotor in suspension and with stabilizing means to maintain the floating rotor in its vertical position, marked through the use of Thomson force acting in a manner known per se Stabilizers. 2. Holder according to claim 1, characterized in that the stabilizing means from a stabilizing body (8) attached to the rotor shaft from electrically conductive, non-magnetic material in a coaxial to the axis of the rotor shaft Magnetic field of an electromagnet fixedly arranged under the stabilizing body (8) (9) exist. 3. Holder according to claim 1 and 2, characterized in that the Stabilizing body (8) is a disc. 4. Holder according to claim 1 and 2, characterized in that the Stabilizing body (8) is a ring. 5. Holder according to claim 4, characterized in that the electromagnet (9) is a pot magnet. 6. Holder according to claim 1 to 5 for an induction electricity meter, characterized in that the excitation winding of the electromagnet (9) is connected to the same AC voltage is connected like the voltage coil of the drive system (s) of the counter. 7. Holder according to claim 6, characterized in that the Electromagnet (9) and the voltage part of the drive system or systems (3, 4) of the meter are on opposite sides of the rotor disc (1) of the meter. Blank page