DE19753064A1 - Method for testing multipolar magnetic rings - Google Patents

Abstract

The method involves rotating the ring in conjunction with a holder. An angle taker (3) assigned to the holder produces a signal at the beginning and at the end of a complete revolution of the holder. A magnetic field pickup (2) is spaced from the outer periphery of the ring, and produces an electric signal (U) when passing each pole. The signal (U) is supplied to a circuit (7) for maximum value determination. The output signal from the circuit is supplied to a circuit (10) for computing the scale faults. The signal of the magnetic field pickup is supplied at the same time to a trigger circuit (8), and its output signal is supplied to a pulse counter (9) and also to the output signal of the angle taker.

Description

The present invention relates to a method for Testing of a variety of magnetic poles the rings and a suitable device for this.

Magnetic rings made from a variety of opposed to set polarity side by side magnetic Poles exist or a large number on their outer circumference have such magnetic poles, are often used Detection of speeds of rotating bodies such as B. Turbines used in automotive transmissions. To be reliable to get some results regarding the speed it is necessary to have the magnetic poles Rings before their installation regarding magnetization, part Check errors and geometry deviations.

Previous methods, as described by the applicant fir used internally to test such rings, only record the sum of the magnetization over the entire scope, d. H. that the determination of the whole magnetic flux of the rings is determined, but with what it is not possible to test individual poles and also geomes deviations and division errors are not recognized can. In particular, the measurement of the division error is however desirable. With this known measuring method the amounts of the field shares per pole are summed up and the entire river compared to the relevant value; this However, the procedure is only for rings with a small number of poles (n <10) sufficiently accurate.  

Another measurement method is the magneti cal flux density B and the corresponding Flußaufnehmerpo sition ϕ to be recorded in a diagram. The zero crossing ge of the B-ϕ characteristic are used in this measuring method Determination of the division error. However, this refers to the division error is not based on the value B = 0, but on the switching point of the magnetic field sensor, which is usually is a half element (e.g. B = 3.2 mT). A capture of Geometry deviations are only possible with egg in this arrangement Functional distance measurement.

However, it was found that this measuring ver driving is associated with great inaccuracies as a Correlation between angle measurement and field measurement only very much difficult to realize. Such a presumptuous one After this measurement, the magnetic ring fulfills the required speci not for the division accuracy Δϕ <0.2 °.

The object of the present invention is a method ren and a device for testing a variety of to create magnetic poles having rings that are suitable for series testing of the rings and only by measuring the magnetic field in a given Functional distance from the outer circumference of the ring one test of magnetization, pitch errors and geometry deviations enable gene.

This problem is solved with the in the kenn Drawing parts of claims 1 and 3 specified note to paint; advantageous embodiments are in the associated Subclaims described.  

The invention is used in the testing of arbitrary, equidistant magnetically polarized rings and is not just limited to automotive engineering.

The method according to the invention therefore beats at its core before that every single magnetic field of the magnetic poles an electrical voltage in a magnetic field sensor signal that is fed to a trigger, an output when a predetermined threshold is reached signal feeds a pulse counter as well as a switch circuit for maximum value determination is fed, its off output signal a circuit for calculating the division error for all magnetic poles. This Measurements take place during a complete revolution of the Magnetic rings instead, with an angle sensor at the beginning and at the end of this complete revolution one reef renzsignal delivers, which also to the pulse counter to be led. After completion of the measurement, d. H. one complete rotation of the magnetic ring, the Pulse counter read out, with a whole as test result numerical value is obtained which easily corresponds to the according to the number of magnetic poles required number impulses can be compared. The determination of the part accuracy with the help of the circuit for the maxi The determination of malwert offers the advantage that this division accuracy without measuring the angle ϕ of the position of the individual magnetic poles can be made.

By calculating the pitch errors per pole speaking of the technical boundary conditions, one wins Good-bad statement about the ring to be checked by Ver equal to the calculated value with the permissible limits.  

The test limits are for the special requirements the ring can be calculated.

In the following the invention with reference to the drawing explained in more detail in the an advantageous embodiment game is shown.

Show it:

Fig. 1 shows schematically a Vorrich device and

Fig. 2 is a block diagram as a principle of signal processing.

In Fig. 1, 1 denotes a ring to be tested, which is composed of a plurality of magnetic poles of alternating polarity. Such a ring is particularly suitable for installation on rotating parts of a motor vehicle transmission in order to detect their speed using the magnetic poles.

To carry out the method according to the invention, the ring 1 is now placed on a holder 4 which is mounted on an axis 6 which is rotatably inserted in two bearings 5 , as indicated by the arrow f, and which is shown in FIG Rotations can be offset. 3 with a Winkelauf subscriber is referred to, which is integrated in the holder 4 and which delivers a reference signal at the beginning and at the end of each complete rotation of the ring 1 . A constant speed of rotation is not required, so that manual operation is possible. The angle sensor only serves as a reference for the start and end point of the measurement (measuring angle = 360 °). He can e.g. B. consist of a slotted disc with optical scanning, which provides this 360 ° reference error without division.

With 2 , a magnetic field sensor is designated, which is arranged at a predetermined distance from the outer circumference of the ring 1 and generates an electrical signal U each time one of the magnetic poles passes; the magnetic field sensor is designed as an electromagnetic transducer, and in particular a calibrated Hall sensor, the z. B. is positioned at a functional distance of 6 mm from the outer circumference.

When checking the magnetization should secure be that each pole on the circumference of the magnetic ring has the required minimum magnetization. When measuring are arranged by the arrangement of the magnetic field sensor two, in the functional distance of z. B. 6 mm of the magnetic ring surface surface, geometry deviations of the magnetic ring (concentricity, ova quality etc.) is taken into account.

According to the block diagram shown in FIG. 2, the output signal U of the magnetic field sensor leads a circuit 7 for determining the maximum value of the signal U, the output signal of which is fed to a circuit 10 for calculating division errors for all magnetic poles; at the same time the electrical signal is of U 2 Magnetfeldaufnehmers a trigger circuit 8 is supplied, the predetermined threshold corresponds to the specified value of the func onskritischen pickoff U _to1. The output signal of the trigger circuit 8 is fed to a pulse counter 9 , the number n being equal to the sum of the pulses I with U <U _zu1 and the pulses with U <-U _zu1 .

The trigger circuit 8 is used for the measurement to the required limit for the magnetization B is inserted _to1. The signal is shaped into rectangular pulses and summed by the counter 9 ; after completion of the measurement solution, ie when the end signal from the angle pickup 3 occurs , the pulse counter is read out; the magnetic ring meets the specification if the value read out corresponds to the number of poles on the circumference of the magnetic ring.

The division errors for all magnetic poles are determined

With:
U = _switching voltage of the switching and Magnetfeldaufnehmers
U _{max (i)} = maximum value.

The angle sensor 3 provides for the measurement Lich only a reference signal at the beginning and at the beginning of a full continuous rotation of the ring 1 , so that no angle measurement is necessary for the individual magnetic poles.

The calibrated magnetic field sensor 2 can be arranged at a predetermined functional distance from the outer circumference of the ring 1 and is therefore suitable for series testing of a large number of rings. The magnetization process including the geometrical deviations of the ring can thus be detected.

The trigger circuit 8 performs a targeted digitization of the output signal U originating from the magnetic field sensor 2 , with only signals being digitized who meet the minimum requirements with regard to magnetization and concentricity.

The pulse counter 9 is read out for each ring after the end of the measurement, the test result being an integer value which can easily be compared with the required number of pulses.

The circuit 7 for determining the maximum value determines the individual maximum values of the plurality of output signals of the magnetic field sensor 2 for a complete rotation of the ring and, in the case of known signal shapes, allows statements to be made about the division accuracy without the individual angles ϕ having to be measured for the magnetic poles .

The circuit 10 for the calculation of the division errors per pole according to the technical boundary conditions and according to the formula

enables a good-bad statement to be obtained for the Ring by comparing the calculated value with permissible Limits.  

The test limits are for special magnetic ring requirements determinations arithmetically; in any case an exam carried out with a good-bad statement.  

Reference list

1

Ring with magnetic poles

2nd

Magnetic field sensor

3rd

Angle sensor

4th

bracket

5

storage

6

axis

7

Circuit for maximum value determination

8th

Trigger circuit

9

Pulse counter

10th

Circuit for calculating division errors

Claims (6)

1. Method for testing a large number of magnetic poles with rings, characterized by the following method steps:

• - The ring ( 1 ) is placed on a rotatably mounted holding tion ( 4 ),
• a rotary drive rotates the holder ( 4 ) with the ring ( 1 ),
• - One of the bracket ( 4 ) associated angle sensor ( 3 ) generates a signal at the beginning and at the end of a complete rotation of the bracket ( 4 ),
• - A spaced from the outer periphery of the ring ( 1 ) arranged magnetic field sensor ( 2 ) generates an electrical signal (U) when each pole runs past,
• - The electrical signal (U) of the Magnetfeldaufneh mers ( 2 ) is supplied to a circuit ( 7 ) for maximum value determination,
• - The output signal of the circuit for determining the maximum value is fed to a circuit ( 10 ) for calculating division errors,
• - The electrical signal (U) of the magnetic field sensor ( 2 ) is simultaneously fed to a trigger circuit ( 8 ),
• - The output signal of the trigger circuit is fed to a pulse counter and
• - The output signal of the angle sensor ( 3 ) is also fed to the pulse counter ( 9 ).

2. The method according to claim 1, characterized in that the trigger circuit ( 8 ) digitizes the signal supplied to it (U). 3. The method according to claims 1 and 2, characterized in that the pulse counter ( 9 ) determines the number (s) of the pulses according to the following formula:
With:
I = sum of the pulses with U <U _zu1 and the pulses with U <-U _zu1 . 4. The method according to claim 1, characterized in that the circuit ( 10 ) calculates the division error for all magnetic poles according to the following formula:
With:
U = _switching voltage of the switching Magnetfeldaufnehmers and U _{max (i)} = maximum value. 5. A device for testing a plurality of rings having magnetic poles for performing the method according to one or more of claims 1 to 4, characterized by

• a holder ( 4 ) which receives the ring ( 1 ) and is arranged on a rotatably mounted axis ( 6 ),
• - a rotary drive for the axis,
• - a magnetic field sensor (2) which is arranged at a distance from the outer periphery of the ring (1),
• - An angle sensor ( 3 ) and
• - A circuit for processing the magnetic field sensor ( 2 ) and from the angle sensor ( 3 ) originating signals, the circuit having a circuit ( 7 ) for determining the maximum value of the output signals of the magnetic field sensor, a circuit ( 10 ) for calculating pitch errors of the magnetic poles , A trigger circuit ( 8 ) for determining the minimum value of the output signal (U) of the magnetic field sensor ( 2 ) and egg NEN pulse counter ( 9 ).

6. The device according to claim 5, characterized ge indicates that the magnetic field sensor is an electromagnetic transducer whose electrical Output signal (U) z. B. is a voltage.