EP2929549A1 - Correction of angle errors in permanent magnets - Google Patents

Abstract

Disclosed is a magnet arrangement (1), comprising at least two partial magnets (2, 3) that are mechanically connected to each other, wherein the length (12) of each partial magnet (2, 3) runs in the main magnetisation direction (4) of each partial magnet (2, 3) and/or in the main direction (4) in which a partial magnet (2, 3) can be magnetised or in which its magnetisation is intended, and defines a first side (5) and a second side (6) as opposed regions at the ends of the partial magnet (2, 3) in respect of its length (12), and wherein the at least two partial magnets (2, 3) are arranged in sequence in respect of their lengths (12) and connected to each other, wherein the at least two partial magnets (2, 3) are aligned towards each other in respect of their magnetisation and/or magnetisability such that deviations in the direction of the magnetisation and/or magnetisability of the first partial magnet (2) deviating from the main magnetisation direction (4) and/or main direction (4) of magnetisability reduce and/or substantially compensate for the deviations in the direction of the magnetisation and/or magnetisability of the other or of the adjacent partial magnet (3) deviating from the main magnetisation direction (4) and/or main direction (4) of magnetisability, in particular relative to the magnetisation and/or magnetisability of the entire magnet arrangement.

Description

Correction of angular errors of permanent magnets

The invention relates to a magnet arrangement and to a method for producing a magnet arrangement.

In the production of permanent magnets or permanent magnets, in particular anisotropic permanent magnets, angle errors of the magnetization and / or orientation of the magnetic material often occur. Keeping them as low as possible or avoiding them is relatively complex and can lead to relatively high costs, depending on the degree of the desired precision of the magnetization direction or orientation of the magnetic material.

The object of the invention has been found to propose a magnet arrangement and a method for producing a magnet arrangement, which is relatively inexpensive and / or simple and / or a relatively high precision of magnetization and / or magnetization with respect to a main magnetization direction and / or main direction of magnetizability entire magnet arrangement allows.

This object is achieved according to the invention by the magnet arrangement according to claim 1 as well as the method according to claim 8. Under the formulation substantially balanced is preferably the formulation at least partially compensated and / or reduced and / or understood at least partially compensated. The term length of the partial magnet is alternatively understood as meaning preferably a mechanical axis of symmetry and / or a length and / or longitudinal direction of the body geometry of the partial magnet. With the formulation direction and / or main direction of the

Magnetizability or magnetisable is expediently the direction or main direction in which the magnetic material or the magnetic particles are aligned, in particular special in terms of a preferred direction of their orientation.

It is preferred that the entire magnetic field of the magnet assembly is formed by the alignment of the at least two partial magnets to each other so that

 Deviations of the magnetic fields generated by the partial magnets, based on magnetic fields, which result exclusively by the magnetization along the main magnetization direction, are at least partially compensated in the interaction of the partial magnets.

The magnet arrangement is preferably designed such that the partial magnets are substantially anisotropic with regard to their magnetic material or the magnetic particles or crystals.

It is expedient that the at least two partial magnets are manufactured with the same tool, in particular with regard to their magnetization and / or magnetizability.

It is preferred that the partial magnets are in each case substantially cylindrical or cylindrical-segment-shaped or hollow-cylindrical or guader-shaped or prism-shaped with a polygon, in particular an equilateral polygon, as the base surface.

The magnet arrangement preferably comprises a plurality of partial magnets, of which in each case adjacent or adjoining partial magnets are mechanically connected to one another.

Each partial magnet is preferably designed in such a way that, relative to its main magnetization direction and / or main direction of its magnetizability, ie in particular with respect to its length, it has magnetization and / or magnetizability essentially orthogonal thereto, which expediently understood as orthogonal direction component of the magnetization or magnetizability is, which in particular as radial angular error of the magnetization or magnetizability is called, wherein

with respect to this orthogonal magnetization and / or magnetizability, one partial magnet is arranged rotated relative to the adjacent other partial magnet by an angle between 140 ° and 220 °, in particular by an angle of substantially 180 °, relative to the length or about the length or Longitudinal axis of the partial magnets. It is preferred that each partial magnet is formed such that its one side has a higher degree of the anisotropic and / or rectified orientation of the magnetic particles and / or the corresponding magnetic material arranged in this side and / or in the region than its other side , which is particularly referred to as north-south fault, wherein the side with the higher degree of anisotropic and / or rectified orientation of the magnetic particles and / or the corresponding magnetic material is defined as a strong pole of the partial magnet and corresponding to the side with the lower degree of anisotropic and / or rectified alignment of the

Magnetic particles and / or the corresponding magnetic material is defined as a weak pole of the partial magnet, wherein the magnet assembly is formed so that adjacent partial magnets are aligned and arranged such that two weak poles or two strong poles of the two partial magnets adjoin one another and connected to each other.

Conveniently, the magnet arrangement is designed so that the two aforementioned formations or arrangements of the partial magnets are combined, so that both the radial

Angular error, as well as the north-south error compensated or reduced or substantially balanced.

Advantageously, the partial magnets consist of sintered powder or plastic-injected or plastic-bonded magnetic material.

In particular, each partial magnet is formed so that its first or second side a higher degree of anisotropic or Having substantially parallel or rectified orientation of the arranged on this side or in the region of this page magnetic particles, as in the second or first side, ie in the other side. The side with the higher degree of the anisotropic or rectified orientation of the magnetic particles is particularly preferably referred to as the strong pole of the partial magnets and correspondingly the side with the lower degree of the anisotropic or rectified orientation of the magnetic particles is particularly preferably referred to as the weak pole of the partial magnet. Under this degree of orientation of the magnetic particles is very particularly preferably understood a measure of the anisotropy of the magnetic particles with respect to their similar or rectified alignment. It is preferred that the magnet arrangement is designed so that the two strong poles or the two weak poles of the two partial magnets or adjacent or respectively all of the adjacent partial magnets adjoin one another. In this way, in particular the north-south fault of the magnet arrangement can be avoided or reduced or. be substantially balanced.

Each partial magnet is in particular designed in such a way that, with respect to its length or longitudinal extent, it has an essentially orthogonal or a radial magnetization or radial magnetizability or a radial angular error with respect to its magnetization or magnetizability.

It is preferred that with respect to this radial magnetization or radial magnetization or this radial angular error of a partial magnet relative to the adjacent other partial magnet by an angle between 140 ° and 220 ° or by an angle between 170 ° and 190 ° or to a Angle of substantially 180 ° twisted, in particular twisted about the length or longitudinal axis of the partial magnet as the axis of rotation, is arranged. In this way, in particular, an angle error or radial angle error of the magnet arrangement can be avoided or reduced. It is preferable that the magnet assembly is formed so that

both the two strong poles or the two weak poles of the two partial magnets or adjacent partial magnets adjoin one another and

that as well as with respect to this / the radial magnetization or radial magnetization or this radial angle error of a partial magnet relative to the adjacent other partial magnet by an angle between 140 ° and 220 ° or at an angle between 170 ° and 190 ° or at an angle of in the

Essentially rotated by 180 °, in particular twisted about the length or longitudinal axis of the partial magnet as the axis of rotation, is arranged.

It is expedient that the partial magnets of the magnet arrangement are arranged substantially centered one behind the other with respect to their central axis in the longitudinal direction or in the direction of their length.

The at least two partial magnets of the magnet arrangement are preferably connected to one another by an adhesive or adhesive bonding.

The magnet arrangement is expediently bipolar, thus comprises two magnetic poles.

The method for producing the magnet arrangement is preferably so pronounced

the at least two partial magnets are produced in the same part magnet manufacturing tool.

The method is expediently designed such that the impressing and / or strengthening of the orientation of the magnetic particles and / or of the magnetic material takes place by being pressed and / or sintered and / or baked and / or heat-treated and / or cured and / or is cooled.

It is preferred in terms of the method that after the production of at least a first and a second Partial magnets, as adjacent partial magnets in the magnet assembly, the first and the second partial magnet are arranged with respect to their alignment in Teilmagnet-HerStellungswerkzeug and with respect to their longitudinal direction one behind the other, each partial magnet is formed so that its one side a higher degree of anisotropic and / or rectified Alignment of arranged in this side and / or in the region of this side magnetic particles and / or the corresponding magnetic material, as its other side, wherein the side with the higher degree of anisotropic and / or rectified alignment of the magnetic particles and / or the corresponding magnetic material as is defined strong pole of the partial magnet and, accordingly, the side with the lower degree of anisotropic and / or rectified orientation of the magnetic particles and / or the corresponding magnetic material is defined as a weak pole of the partial magnet, wherein the magnet assembly thus formed et, that adjacent partial magnets are aligned and arranged to each other, that two weak poles or two strong poles of the two partial magnets adjoin and connected to each other, and / or each partial magnet is formed so that it relative to its Hauptmagnetisierungsrichtung and / or main direction its magnetizability, ie in particular with respect to its longitudinal direction, has a substantially orthogonal magnetization and / or magnetizability, with respect to this orthogonal magnetization and / or magnetizability of a partial magnet relative to the adjacent other partial magnet by an angle between 140 ° and 220 °, in particular rotated by an angle of substantially 180 °, with respect to the longitudinal direction of the partial magnets.

The magnetic material, in particular formed as a powder, is expediently compressed after the alignment of the magnetic material or the magnetic particles by an externally applied magnetic field or pressed into shape, in particular by mechanical force. Subsequently, such a pressed blank magnet is preferably sintered or heat-treated. It is expedient that after the production of at least a first and a second partial magnet, the first and the second partial magnet with respect to their orientation in the partial magnet manufacturing tool and with respect to their length or

Longitudinal axis are arranged one behind the other, wherein

the first or second partial magnet is reversed in its longitudinal direction with respect to its two ends, so that, for example, its lower end is rotated at the top or the other way round, and / or the first and / or second partial magnet are rotated and / or aligned relative to one another with respect to their longitudinal axis or longitudinal axis Length or substantially more common

Longitudinal axis, wherein this relative rotation and / or orientation, in particular the lateral surface is rotated or aligned rotationally by an angle between 140 ° and 220 ° or at an angle between 170 ° and 190 ° or at an angle of substantially 180 ° is performed.

Thereafter, the at least two partial magnets are usefully connected together.

Alternatively, preferably, the at least two partial magnets are each produced by compression or in the form of pressing, after which the relative arrangement between at least the first and second partial magnet is carried out and then particularly preferably the at least two partial magnets are baked together or sintered to be permanently connected to each other ,

It is preferred that the radial angle error and / or north-south error of each partial magnet in the course of manufacture after the alignment of the particles or the magnetic material is formed and / or changes and / or amplified or attenuated by pressing during pressing and / or sintering and / or baking and / or cooling the respective partial magnet mechanically deformed.

It is expedient that the component of the main magnetization direction or the main direction of the magnetizability of one or each partial magnet is stronger than in other directions, in particular as in the orthogonal or radial direction, particularly preferred is the ratio of the magnetization strength or strength of the magnetizability or the magnetic remanence or the magnetic remanence due to a magnetization along the main magnetization direction, the component in the main direction to the component in the orthogonal or radial direction at least 95 to 5.

The magnet arrangement is expediently designed as a permanent magnet or permanent magnet.

The radial angle error is alternatively or alternatively referred to as axial angle error.

The invention also relates to the use of the magnet arrangement in motor vehicles, in particular in position sensor arrangements.

LIST OF REFERENCE NUMBERS

1 magnet arrangement

 2 first part magnet

3 second part magnet

 4 main magnetization direction or main direction, in

 which part magnet is magnetizable

 5 first side of the partial magnet or strong pole

 6 second side of the partial magnet or weak pole

7 magnetic field of the partial magnet or the two

 part magnets

 8 tool, in particular pressing tool or part magnet production tool

 9 orthogonal magnetization or magnetization or

 Component of the radial angle error

 10 stamps

 11 field coils of the tool

 12 length of the partial magnet or longitudinal direction of the partial magnet

13 field lines of the magnetization field or the magnetic field for aligning the magnetic material or. the magnetic particle of a partial magnet

In a schematic representation, the exemplary production of a partial magnet in a tool according to the prior art, in which a north-south fault is generated,

2 shows the occurrence of an angle error or a magnetization or orientation deviation of the magnetic material in such an exemplary production, in addition to a north-south error,

Fig. 3 shows an exemplary magnet arrangement, with a compensated or reduced north-south fault, and

Fig. 4 shows an example of a magnet arrangement, with a

 compensated or reduced orthogonal or radial or axial angle error. Background Art, by Way of Exemplary Background Explanation: Many metering applications are performed with magnetic sensors. For this, the actual sensor and a permanent magnet are used. The sensor detects the magnetic field emanating from the magnet, for example by means of a

Hall-effect sensor, the direction of the magnetic field, for example by means of an AMR sensor, or exploits the magnetizing effect, for example by means of a "flux gate sensor" or an inductive sensor from often rotationally symmetric magnetic fields are required by Permanent magnets in the form of blanks or rings or

Cylinders are generated. These rings or blanks or cylinders are axially, ie magnetized in their longitudinal direction. Desired or necessary is that the mechanical and the magnetic axis of symmetry or longitudinal or main direction are congruent or rectified. Unfortunately, due to the manufacturing process, it is often not possible for the magnetic and mechanical axes of symmetry to be rectified or identical, as exemplified with reference to FIG. 2.

There is an angle between the two axes, the so-called radial angular error of the magnet or partial magnet 2, 3. Depending on the manufacturing method, there may be a broad distribution of the angular errors occurring in the case of different or multiple magnets. This is the case when the magnets are pressed in large blocks. If the magnets are individually pressed axially, the occurring radial angle error is approximately the same for all magnets. As a further error often occurs the so-called. North-south fault in magnets, which is exemplified with reference to FIG. 1. The north-south fault is the fact that often the strength of the poles of a magnet is different and thus the dividing line between the north and south pole of the magnet is not exactly in the geometric center of the magnet. Both errors, the radial angle error see Fig. 2, and the north-south error see Fig. 1, are based on the defective, that is: not exactly parallel alignment of the magnetic particles during pressing of the magnetic blanks. In order to achieve the highest possible remanences, a strong magnetic field is applied during the pressing of the magnetic powder in order to align the particles of the powder. However, this magnetic field is not homogeneous but slightly divergent. This results in a strong pole on the bottom and a weaker, so weak pole on the top, see Fig. 1. This is the mentioned north-south fault. The radial angle error is also based on a misalignment of the particles of the magnetic powder. Cause here is an angle between the axis of symmetry of the magnetic tool and the aligning magnetic field (Figure 2) Both errors are impressed after sintering in the magnet and not to compensate by a special magnetization.

The following is an example description of an embodiment with integrated variants:

For this purpose, the magnet is replaced for example by two magnets, which have half the height. The second magnet is "turned upside down" so that two similar poles, Regardless of their orientation in the part magnet manufacturing tool, touch (either the weaker ones or the stronger ones). As a result, the north-south fault is compensated, as shown by way of example with reference to FIG. 3. In order to compensate for the radial or axial angle error, as shown in FIG. 4, the upper magnet must still be oriented such that the undesired radial components of the magnetization face in the opposite direction. As a result, these components weaken and virtually extinguish themselves in the "far field".

Exemplary advantages:

 The method presented here or the magnet arrangement makes it possible to drastically reduce the unwanted angular error or radial angle error and / or the north-south error. By way of example, in the axial compression of magnets, the zone in which the magnet is pressed is not in the center of the coil, which aligns the magnetic powder prior to pressing. The result is that the strong pole of the magnet is always stronger than the weak pole of the magnet. Since the

Sintering of the magnets whose magnetization is lost, there are in the subsequent magnetization an equal number of magnets with strong south pole and strong north pole, especially if the magnetization orientation opposite to the other partial magnet is pronounced in one partial magnet.

By way of example presented here, all partial magnets and magnet arrangements are identical. The north-south fault no longer occurs here or is significantly reduced. An otherwise possibly necessary oriented installation with respect to the strong and weak pole of the magnet is not necessary.

1 illustrates the exemplary production of a partial magnet 2, 3, the material of which is arranged in tool 8 in a corresponding cavity. Field coils 11 generate a magnetic field with the field lines 13 to align the magnetic material in the partial magnet 2, 3, which is a main direction 4 have the magnetizability, along which the length 12 of the partial magnet, shown dotted, aligned, which forms a geometric axis of symmetry of the body of the partial magnet 2, 3. After applying the magnetic field 13 for aligning the magnetic particles, the material of the partial magnet 2, 3 is pressed by means of stamp 10. Since the magnetic field 13 has less field density in the upper region 6 of the partial magnet than in the lower region 5, a strong pole 5 of the partial magnet is formed in the lower region and a weak pole 6 in the upper region. The characteristic of these two poles 5, 6 of different strength , caused by the different degree of orientation of the magnetic material at the two ends 5 and 6, is called north-south fault. In the production of a partial magnet 2, 3 by way of example shown in FIG. 2, a radial angle error is additionally produced by a radial or orthogonal component of the magnetic field 13 which is generated by the field coils 11 for aligning the magnetic particles or the magnetic material. This orthogonal or radial component 14 results in a magnetic field having an angular offset α to the main direction of the magnetization and the geometric axis of symmetry of the partial magnet 2, 3 and to its length or longitudinal axis 12. After the alignment of the magnetic particles, the material of the partial magnet 2, 3 is also pressed in the tool 8 by means of stamp 10. The partial magnet 2, 3 now has a north-south fault because of the different field density at its top, and bottom 6, 5 and a radial angle error. With reference to FIGS. 3 a) to c), it will now be explained by way of example how, in the case of a magnet arrangement comprising a first and a second partial magnet, the north-south fault is substantially compensated, at least substantially reduced.

Fig. 3 a) shows a magnet with north-south fault, the magnetizing field lines in Fig. 3 a) to c) are respectively illustrated with the arrows. In Fig. 3 b) are now two partial magnets 2, 3 shown, which have been produced in the same tool and each have a strong pole 5 and a weak Pol 6 in terms of their magnetizability. The two partial magnets are now joined together by way of example with their weak poles 6 axially and as shown with reference to FIG. 3 c) mechanically interconnected and magnetized together. The resulting magnetic field 7 of the magnet assembly 1, detected at least in a defined minimum distance, no significant north-south fault more.

4 a) to d) exemplifies how the radial angle error in a magnet arrangement consisting of two partial magnets 2, 3 is compensated or at least substantially reduced. In each case, a side view is shown at the top and a top view of the magnet or the magnet arrangement is shown below. In addition to the dominant component of the desired main direction M_axial of the magnetizability, the magnet in FIG. 4 a) has a radial component M_radial of the magnetizability, as a result of which the entire direction of magnetizability M is pronounced, which has just a radial angle error. The orientation direction of the magnetic particles is thus not parallel to the geometric axis of symmetry or longitudinal axis or length of the magnet. In Fig. 4 b) two partial magnets 2 and 3 are shown, which have been produced in the same tool and each have an equally strong or equally pronounced angle error, each with the radial component of the magnetizability M_radial. These two partial magnets 2 and 3 are now arranged one behind the other and aligned with each other or that the radial component of a magnet 2 is rotated by 180 ° to the radial component of the other magnet 3 to the longitudinal axis or main direction of the magnetizability 4. As in Fig. 4 c) by way of example, the two partial magnets are then mechanically connected to one another and, as described with reference to FIG. 4 b), aligned with one another and form magnet arrangement 1. FIG. 4 d) illustrates by way of example at least a minimum distance to Magnetic arrangement 1, the radial angle error is compensated or at least significantly reduced.

Claims

claims

Magnet arrangement (1), comprising at least two partial magnets (2, 3) which are mechanically connected to one another, wherein along the main magnetization direction (4) of each partial magnet (2, 3) and / or the main direction (4), in which a partial magnet (2 3) is magnetizable or whose magnetization is provided, the length (12) of each partial magnet (2, 3) runs, and a first side (5) and a second side (6), as opposed regions at the ends of the partial magnet (2, 3) defined with respect to its length (12), and wherein the at least two partial magnets (2, 3) with respect to their length (12) arranged one behind the other and connected to each other, characterized in that

 the at least two partial magnets (2, 3) are aligned with respect to their magnetization and / or magnetizability to each other such that

 Deviations with respect to the direction of the magnetization and / or magnetizability of the one partial magnet (2) differing from the main magnetization direction (4) and / or main direction (4) of the magnetizability the deviations with respect to the direction of magnetization and / or magnetizability of the other or adjacent partial magnet (3 ) deviating from the main magnetization direction (4) and / or main direction (4) of the magnetizability

 reduce and / or substantially compensate, in particular based on the magnetization and / or magnetizability of the entire magnet assembly.

Magnet arrangement according to claim 1, characterized in that this (1) is formed so that its entire magnetic field (7) by the orientation of the at least two partial magnets (2, 3) to each other is formed so that Deviations of the magnetic fields generated by the partial magnets (2, 3), based on magnetic fields, which result exclusively by the magnetization along the main magnetization direction (4), are at least partially compensated in the cooperation of the partial magnets (2, 3).

Magnet arrangement according to claim 1 or 2, characterized in that the partial magnets (2, 3) are formed substantially anisotropic with respect to their magnetic material.

Magnet arrangement according to at least one of claims 1 to 3, characterized in that the at least two partial magnets (2, 3) with the same tool (8, 10, 11) are made, in particular with regard to their magnetization and / or magnetizability.

Magnet arrangement according to at least one of claims 1 to 4, characterized in that the partial magnets (2, 3) are each substantially cylindrical or cylindrical segment-shaped or hollow cylindrical or guaderförmig or prismatic with a polygon, in particular an equilateral polygon, as a base.

Magnet arrangement according to at least one of claims 1 to 5, characterized in that each partial magnet (2, 3) is designed so that it related to its main magnetization direction (4) and / or main direction (4) its magnetizability, ie in particular based on its length (12) has a substantially orthogonal magnetization (9) and / or magnetizability (9), wherein

with respect to this orthogonal magnetization (9) and / or magnetizability (9) of a partial magnet (2) relative to the adjacent other partial magnet (3) is arranged rotated by an angle between 140 ° and 220 °, in particular by an angle of substantially 180 °, based on the length of the partial magnets (2, 3).

Magnet arrangement according to at least one of claims 1 to 6, characterized in that each partial magnet (2, 3) is formed so that its one side (5) a higher degree of anisotropic and / or rectified alignment of in this page and / or in Magnetic particles arranged on this side and / or the corresponding magnetic material, as its other side (6), wherein the side with the higher degree of anisotropic and / or rectified alignment of the magnetic particles and / or the corresponding magnetic material as strong pole (5) of Partial magnets (2, 3) is defined and correspondingly the side with the lower degree of anisotropic and / or rectified orientation of the magnetic particles and / or the corresponding Magnetma ^¬ terials as a weak pole (6) of the partial magnet (2, 3) is defined, wherein the magnet arrangement (1) is designed such that adjacent partial magnets (2, 3) are aligned and arranged relative to one another so that two weak ones Pole (6) or two strong poles (5) of the two partial magnets (2, 3) adjoin one another and connected to each other.

A method of manufacturing a magnet arrangement (1), in particular a magnet arrangement (1) according to at least one of claims 1 to 7, wherein the magnet assembly from about ^¬ least two part-magnets (2, 3) is assembled, which are mechanically connected to each other, wherein, during or during or before the production of the partial magnets (2, 3) the magnetic particles and / or the magnetic material in a longitudinal direction (12) of the partial magnet, as the main magnetization direction (4) and / or main direction (4) of the magnet magnet be substantially or mainly aligned, after which the orientation of the magnetic particles and / or the magnetic material is impressed, characterized in that

 the at least two partial magnets (2, 3) are aligned and arranged with respect to their magnetization and / or magnetizability to one another such that

 Deviations with respect to the direction of the magnetization and / or magnetizability of the one partial magnet (2) differing from the main magnetization direction (4) and / or main direction (4) of the magnetizability the deviations with respect to the direction of magnetization and / or magnetizability of the other or adjacent partial magnet (3 ) deviating from the main magnetization direction (4) and / or main direction (4) of the magnetizability

 reduce and / or substantially compensate, in particular based on the magnetization and / or magnetizability of the entire magnet assembly (1).

A method according to claim 8, characterized in that the at least two partial magnets (2, 3) are produced in the same partial magnet manufacturing tool (8). 10. The method according to claim 8 or 9, characterized in that the embossing and / or consolidating the alignment of the magnetic particles and / or the magnetic material takes place in that this is pressed and / or sintered and / or baked and / or heat treated and / / or cured and / or cooled.

Method according to at least one of claims 8 to 10, characterized in that after the production of at least a first and a second partial magnet 3), as adjacent partial magnets (2, 3) in the magnet assembly (1), the first and the second partial magnet are arranged with respect to their orientation in the partial magnet manufacturing tool (8) and with respect to their longitudinal direction one behind the other, wherein

each partial magnet (2, 3) is designed such that its one side (5) has a higher degree of the anisotropic and / or rectified alignment of the magnetic particles and / or the corresponding magnetic material arranged in this side and / or in the region of this side its other side (6), wherein the side with the higher degree of anisotropic and / or rectified orientation of the magnetic particles and / or the corresponding magnetic material is defined as a strong pole (5) of the partial magnet (2, 3) and corresponding to the side with the a lower degree of the anisotropic and / or rectified orientation of the magnetic particles and / or of the corresponding magnetic material is defined as a weak pole (6) of the partial magnet (2, 3), wherein the magnet arrangement (1) is formed such that adjacent partial magnets (2, 3 ) are aligned and arranged so that two weak poles (6) or two strong poles (5) of the two partial magnets (2, 3) adjoin one another and with be connected to each other, and / or each partial magnet (2, 3) is formed so that with respect to its main magnetization (4) and / or main direction (4) its magnetizability, ie in particular with respect to its longitudinal direction (12), one in the Substantially orthogonal magnetization (9) and / or magnetizability (9), wherein

with respect to this orthogonal (9) magnetization and / or magnetizability (9) of a partial magnet (2) relative to the adjacent other partial magnet (3) by an angle between 140 ° and 220 °, in particular rotated by an angle of substantially 180 ° is based on the Longitudinal direction (12) of the partial magnets (2, 3).