DE2853813A1 - Electricity meter pulse generator - controls tariff unit or remote reading and uses magnetic transmitter, rotating with meter disc, and fixed receiver - Google Patents

Abstract

The pulse generator provides a number of pulses corresponding to the number of rotations of the meter disc. It employs a magnetic transmitter (3) rotating in conjunction with the rotation of the meter disc, cooperating with a fixed magnetic receiver (6). At least one conductor (5) is incorporated in the transmitter (3) or receiver (6), responsive to the relative rotation of permanent magnets incorporated in the receiver (6) or source (3) to exhibit a spontaneous magnetisation. This is detected by a measuring coil incorporated in the receiver (6). Pref. the transmitter comprises a drum mounted on a shaft (2) of the meter disc and with a number of short conductors (5), each running axially, and wound in spaced manner round its periphery with equal distances from one another. The receiver comprises a pick-up head with two bar magnets arranged one on either side of the measuring coil, all these extending parallel to the shaft of the meter disc.

Description

Pulse scanning device for an electricity meter

The invention relates to a pulsing device for one Electricity meter for the delivery of electrical pulses, the number of which is proportional is for the number of revolutions of the electricity meter rotor, with one with The rotor co-rotating magnetic transmitter and with a spatially fixed magnetic Receiver, whereby the transmitter acts magnetically on the receiver when it rotates.

For controlling tariff devices inside or outside a Electricity meters or for remote counters, pulse generating devices are required. The number of pulses emitted should be proportional to the number of rotor revolutions of the electricity meter and thus a measure of the electrical work.

Up to now, pulse-generating devices have been used that have either the magneto-galvanic, the'opto-electronic or the inductive principle. All these impulse devices require a power supply, d. H. a power supply, which means some effort and accommodation difficulties can lead.

In addition, the heat loss that occurs during operation is undesirable.

It is already known per se, a so-called Wiegand wire or Wiegand ladder as a threshold sensor for a relatively weak magnetic field to use.

A Wiegand conductor is a ferromagnetic one Material in the form of a wire that has memory properties. By cold forming a screwdriver-shaped magnetization is introduced into the wire, whose Longitudinal component in the outer part of the wire antiparallel to that in the inner Part runs. The wire diameter is a few 100 micrometers and the length a few inches. A magnetic field in a suitable direction acts on the wire from outside the inner area is spontaneously remagnetized. This does so at the ends an adjacent measuring coil, the z. B. has 1000 turns, a voltage pulse, the z. B. has a height of 2 volts and a duration of 20 microseconds. the Pulse duration is independent of the change in the magnetic field. The component is Can be used from - 1960 C to + 3000 C. More details about the Wiegand ladder per se are given in the magazine "Electronicsn, on July 10, 1975, Pages 100 to 105, from April 14, 1977, pages 39 and 40, and from April 29, 1977, Pages 85 and 86.

From the magazine "Electronicsn" just mentioned of July 10, 1975, in particular FIG. 9 on page 104, a measuring arrangement is already known in which a Wiegand ladder is moved linearly over a receiver arrangement consisting of two Permanent magnets and one in between arranged measuring coil consists. The measuring coil is wound on a core made of soft iron, and the two rod-shaped Permanent magnets are aligned parallel to the Wiegand conductor and in opposite directions magnetized. If the Wiegand ladder is moved over this receiver, kick two voltage pulses of opposite directions in succession on the measuring coil as a measuring signal Polarity on.

From the publication "The Wiegand Effect from Echlin" by The Echlin Manufacturing Company, Branford, Connecticut, particularly Figure 7b a measuring arrangement has already become known in which several Wiegand conductors on the circumference of a rotating cylinder and are aligned parallel to its axis. These Wiegand conductors are moved past a receiver as they rotate. Of the Receiver contains magnets and a measuring coil.

The present invention is based on the object of a pulse generating device Specify the type mentioned for an electricity meter that does not have a power supply is working.

This task is performed in the case of the impulse generating device mentioned at the beginning according to the invention achieved in that the transmitter or the receiver at least one Wiegand ladder includes, on which at least one on the receiver or The magnet arranged on the transmitter acts in the sense of a spontaneous magnetization reversal, that the receiver has a measuring coil which, under the magnetic action of the Wiegand conductor stands, and that at the ends of the measuring coil between the with a relative movement Wiegand conductor and magnet generated pulses are tapped as a measuring signal.

According to a first basic further training form of execution be provided that the rotor axis of the electricity meter with a drum is connected from non-magnetic material that the Wiegand conductor on the circumference of the Drum and the magnet is arranged on the receiver that the Wiegand conductor and the Magnet are aligned parallel to the rotor axis, and that when the rotor axis revolves the Wiegand conductor runs closely adjacent to the measuring coil. This embodiment has the advantage that the rotor axis only has a relatively small additional Moment of inertia, which is given by the Wiegand conductor and the drum, loaded will.

According to a second basic further development embodiment, can also be provided that the rotor axis of the electricity meter with a drum made of non-magnetic material that the magnet is connected to the circumference of the drum and the Wiegand conductor is arranged on the receiver, that the magnet and the Wiegand conductor are aligned parallel to the rotor axis, and that the measuring coil closely adjacent is arranged to the Wiegand head. This embodiment has one particular simply structured receiver. However, if you use several Magnets get a relatively large moment of inertia.

A pulse generating device of the type according to the invention with a Wiegand ladder does not need a power supply. Another advantage is independence the voltage pulses emitted in the measurement signal on the level and the change over time of the magnetic field. Compared to conventional pulse generating devices is in particular to record a greater accuracy at low rotational speeds.

Embodiments of the invention are described below with reference to 4 figures explained in more detail. FIG. 1 shows a first basic embodiment a pulse delivery device in a perspective view, Figure 2 the associated magnetic receiver in plan view, Figure 3 shows a second basic embodiment a pulse generating device in a perspective view and FIG. 4 the associated magnetic receiver in plan view.

According to Figure 1, there is the pulse output device for an electricity meter - generally speaking - from a magnetic transmitter rotating with the rotor and a spatially fixed magnetic receiver, the transmitter rotating acts magnetically on the receiver. In detail it is provided that the rotor axis 2 of the electricity meter carries a drum 3 made of non-magnetic material. the Rotor axis 2 is supported on both sides. It rotates in the direction of arrow 4. The Drum 3 is designed as a rotary cylinder. Its axis lies in the direction of Läuterachse 2. On the circumference of the drum 3 are short Wiegand conductors 5 parallel to Rotor axis 2 arranged. There are several Wiegand conductors 5 equidistant Distance provided. If the drum 3 rotates with the rotor axis 2, the Wiegand conductor 5 passed a probe head or receiver 6.

According to Figure 2, the receiver 6 contains two bar magnets 7a and 7b. the the two bar magnets 7a and 7b are aligned parallel to the rotor axis 2. they are opposite permanently magnetized to each other.

A measuring coil 8 is arranged between them. The coil axis lies also parallel to the rotor axis 2.

To increase the magnetic flux that penetrates the measuring coil 8, an iron core 9 with a corresponding pole formation can be used. The terminals the measuring coil are denoted by 10 and 11.

Runs through a Wiegand ladder when it rotates around the rotor axis 2 5 first the magnetic field of the bar magnet 7a, then the magnetization of the Wiegand conductor tilts 5 spontaneously to the other position. This causes spontaneous overturning of magnetization in turn a voltage pulse ul in the measuring coil 9. The Wiegand conductor 5 becomes thus "set" when the bar magnet subsequently passes through the magnetic field 7b, which has the opposite polarity as the bar magnet 7a, takes place Tilting back the magnetization. The relevant Wiegand conductor 5 is "reset", and a voltage pulse u2 of opposite polarity arises in the measuring coil 9. The two voltage pulses ul and u2 are shown in FIG. 2 in the form of a time diagram drawn between the output terminals 10 and 11. Two equal voltage pulses are generated when the next Wiegand conductor 5 passes the receiver 6. The same applies to all other Wiegand leaders 5.

It can be seen that the number of voltage pulses emitted u1 and u2 are proportional to the number of rotor revolutions of the electricity meter and thus a measure of the electrical work.

In Figures 3 and 4 is the second basic embodiment shown. Corresponding components are provided with the same reference numerals as in Figures 1 and 2.

According to FIG. 3, the runner axle 2 also carries an electricity meter a cylindrical drum 3 made of non-magnetic material. There are small bar magnets in these 7 embedded with alternating polarity sequence.

They are also permanent magnets. They are parallel to the Rotor axis 2 aligned.

According to Figure 4, the probe head or magnetic receiver 6 includes one Wiegand conductor 5, which is aligned parallel to the rotor axis 2 and the bar magnet 7 is.

The Wiegand conductor 5 is also wrapped with a measuring coil 8 here. Voltage impulses are also applied to output terminals 10 and 11 as a measuring signal u1 and u2 generated.

For the interaction of the magnetic field of the bar magnets 7 and the Wiegand conductor 5 for the purpose of generating voltage pulses ul and u2 applies in principle the description of the first basic embodiment according to Figure 1 and 2. Here Each of the voltage pulses ul and u2 is passed by one of the bar magnets 7 assigned. The number of voltage pulses u1, u2 is in turn proportional to Number of rotor revolutions.

As an advantage of this second over the first embodiment can the simpler structure of the receiver 6 can be called.

10 claims 4 figures

Claims (10)

Patent claims 1.) Pulse generating device for an electricity meter for the delivery of electrical impulses, the: number of which is proportional to the number the revolutions of the rotor of the electricity meter, with one rotating with the rotor magnetic transmitter and with a spatially fixed magnetic receiver, whereby the sender acts magnetically during rotation on the receiver, d u r c h it is noted that the transmitter (3) or the receiver (6) at least comprises a Wiegand ladder (5) on which at least one on the receiver during rotation (6) or on the transmitter (3) arranged magnet (7a, 7b; 7) in the sense of a spontaneous Magnetization reversal has the effect that the receiver (6) has a measuring coil (8) which is under the magnetic action of the Wiegand conductor (5), and that at the ends (10, 11) of the measuring coil (8) during a relative movement between the Wiegand conductor (5) and magnet (7a, 7b; 7) resulting pulses (u1, u2) are tapped as measurement signal (u) are (Figs. 1 to 4). 2. pulse generating device according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the rotor axis (2) of the electricity meter with a Drum (3) made of non-magnetic material is connected that the Wiegand conductor (5) arranged on the circumference of the drum (3) and the magnet (7a, 7b; 7) on the receiver (6) is that the Wiegand conductor (5) and the magnet (7a, 7b) parallel to the rotor axis (2) are aligned and that the Wiegandt ladder as the rotor axis (2) revolves (5) runs closely adjacent to the measuring coil (8) (Fig. 1 and 2). 3. pulse generating device according to claim 2, d a d u r c h g e k e n n z e i c h n e t that several Wiegand ladder (5) evenly over the circumference of the Drum (3) are arranged distributed (Fig. 1 and 2). 4. pulse generating device according to claim 2 or 3, d a -d u r c h g It is evident that the receiver (6) magnetized two oppositely Contains magnets (7a, 7b), between which the measuring coil (8) is arranged (Fig. 1 and 2). 5. pulse generating device according to one of claims 2 to 4, d a d It is indicated that the measuring coil (8) encloses an iron core (9) (Figures 1 and 2). 6. pulse generating device according to one of claims 2 to 5, d a d u r c h e k e n n n z e i c h n e t that the axis of the measuring coil (8) is parallel to the Wiegand head (5) is aligned (Fig. 1 and 2). 7. pulse generating device according to claim 1, d a d u r c h g e k e n nz e i c h n e t that the rotor axis (2) of the electricity meter with a drum (3) made of non-magnetic material connected that the magnet (7) on the circumference of the Drum (3) and the Wiegand conductor (5) on the receiver (6) is arranged that the Magnet (7) and the Wiegand conductor (5) aligned parallel to the rotor axis (2) are, and that the measuring coil (8) is arranged closely adjacent to the Wiegand conductor (5) is (Figs. 3 and 4). 8. pulse generating device according to claim 7, d a -d u r c h g e k e n n z e i h n e t that several magnets (7) with alternating polarity evenly above the circumference of the drum (3) are distributed (Fig. 3 and 4). 9. pulse generating device according to claim 7 or 8, d a -d u r c h g It is clear that the measuring coil (8) surrounds the Wiegand conductor (5) (Figures 3 and 4). 10. pulse generating device according to one of claims 7 to 9, d a d u r c h e k e n n n z e i c h n e t that the axis of the measuring coil (8) is parallel to the Wiegand conductor (5) and parallel to the axis of the rod-shaped magnet (7) is aligned (Figs. 3 and 4).