Magnetics Business & Technology - Summer 2016 - (Page 20)
GUEST COLUMN
New Measurement Technique Characterizes
Permanent Magnets
By Rocco Holzhey | Innovent e.V.
Permanent magnets are widely used for
sensor and motor applications. Besides
these, magnetic fields are also used for applications such as storage of information
and fraud protection on documents. With
the number of critical applications continuing to rise, developers
and producers are increasingly forced to meet safety requirements,
as well as increase the technology's overall efficiency. In order to
ensure the high quality that the end user demands, comprehensive
quality control is necessary.
Depending on the application, it is possible and often necessary
to measure magnets in the far and in the near field.
In this column, I will describe a new innovative measuring technique to characterize magnets in the far field with a stray field
measurement and a dipole approximation.
For the so called far field measurements, there is a large distance between the source object and the measurement position.
A large distance in this sense means a distance from at least five
times the biggest dimension of the object. In this distance the
magnetic stray field of a permanent magnet is a dipole. With this
assumption it is possible to characterize a permanent magnet
based on the measurement with an array magnetoresistiv sensor
elements. Similar to helmholtz coil fluxmeter combinations this
method provide the magnetization error (angle of magnetization)
and the open remanence of the magnet in a very easy, fast and
precise way. Compared with helmholtz coils a build up of an automated inline measuring system is possible. With such a fast measurement the magnets for motor application can be measured,
sorted and screened very fast. It seems with such a measuring
and sorting a reduction of the magnet material in a motor and a
prevention of cogging effects are possible.
Theoretical Background "Magnetic Monitoring"
Within the magnetic monitoring technique, an array of magnetic field-sensitive sensors is used to track small dipolar permanent
magnets. At the same time the characteristics of the specimen itself can be measured. For the localization algorithm, the position
and orientation of the magnetic dipole constitute five independent
parameters. If the magnitude of the magnetic dipole moment of
the specimen is not known or is subject to variation during the
measurement, this quantity constitutes a sixth parameter, which
Figure 1. Principle Scheme "Magnetic Monitoring"
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Magnetics Business & Technology * Summer 2016
must be determined. Mathematically, it would be sufficient to use
six magnetic field sensors in order to determine the six unknown
parameters. In practice, more sensors are used for three reasons:
Additional information is needed to determine and compensate for
disturbing fields, additional magnetic sensors can provide homogeneous localization sensitivity within the desired measurement volume almost independent of the orientation of the specimen, and
statistical deviations of the field values measured by the individual
sensors, e.g. due to noise, are strongly reduced.
Figure 1 shows the principle of the magnetic monitoring technique. In a sufficiently large distance from a permanent magnet
with magnetisation M (vector: strength and direction) and volume
V, only the contribution of its magnetic dipole moment µ = M · V
to the total magnetic field can be measured.
The magnetic flux density generated by a magnetic dipole is
with r and r = |r|, being position vector and distance with respect
to the position of the magnetic dipole. Since more sensors than
unknown dipole parameters are used, the localization is performed
by a least squares optimum search algorithm. The dipole moment
µ and position rm of a dipole are determined such, that the field
generated by the dipole fits best the fields measured at the sensor
positions rs. A measure for the quality of the localization is determined by the quality function Q:
Suppression of Disturbing Fields
The field of the magnetic marker is overlaid with steady and
time varying fields of different shape. Steady fields result from the
earth magnetic field and its deformations by iron structures (e.g.
concrete reinforcement). If such structures move (cars, elevators,
hospital beds), the respective fields change in time. Slowly varying
fields may also origin from tramways, which work with DC current
and poses a large coil between rails and overhead wire, with changing length and current. The homogeneity of the disturbing fields
depends on the distance of the field source; near sources produce
more inhomogeneous fields.
Distortions due to steady fields can be suppressed by taking a
baseline prior to the measurement. Homogeneous time varying
fields are handled by a homogeneous field suppression algorithm.
If size and shape of the sensor field provide enough information,
also inhomogeneous time varying field sources may be separated
by adaptation of the multipole expansion method.
Magnet Characterization Systems Based on
"Magnetic Monitoring"
Based on the described algorithm in combination with a sensitive array of magnetic field sensors it is possible to build up sensitive measuring devices to characterize permanent magnets. Figure
2. shows a measurement system, which is developed to measure
the magnitude and orientation of the magnetic dipole moment
very precisely in a QM environment. This system is developed to
probe single magnets with a hand feeding of the specimen on
a human working place. In principle the measuring frequency is
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