DE4227503A1 - Permanent magnet system for generating homogeneous field - has single element with variable field direction dependent upon position and produced within controlled field - Google Patents

Abstract

A permanent magnet system is provided with a field direction that varies with position. The magnetic unit can be either ring, cylinder or ball shaped. For a tubular section system the unit is of a single part of isotropic permanently magnetic material, throughout which the field direction varies. The magnetisation is achieved by locating the element in an homogeneous field where the direction is related to the angular position. ADVANTAGE - Allows variable direction field to be produced.

Description

The invention relates to a ring, cylinder or spherical permanent magnet system with a locally varying preferred direction for generating a homogeneous magnetic field in its interior according to the formula gamma = 2 _* phi, where gamma is the angle between the magnetic field direction and the preferred direction and phi is the spatial coordinate .

An annular permanent magnet is known from EP-B 0 161 832 known system for generating homogeneous magnetic fields. This known magnet system is made up of segments and creates a selected magne in its interior table field that is aligned transversely to the magnetic axis. To achieve the desired homogeneous inside the magnet system To achieve a magnetic field, each of the segments is in one magnetized in a certain direction.

A hollow cylinder is from PCT application WO 88/10500 shaped permanent magnet system known that inside also produces a homogeneous magnetic field. This too Magnet system is made up of individual segments, whereby again each segment has a certain magnetization has direction.

In PCT application WO 88/02925 there is also a Permanent magnet system for generating homogeneous magnetic fields described, which has a spherical structure. The System also consists of individual in a certain th direction on magnetized segments.  

The known magnet systems described above are so-called Halbach systems. These magnetic systems create a homogeneous magnetic field inside. For this it is necessary that the preferred direction in the magnetic material varies locally according to the Halbach specification gamma = 2 _* phi, where gamma is the angle between the field direction and the preferred direction and phi is the spatial coordinate.

The known systems are made up of individual segments composed, with each segment a specific Preferred direction. Due to the finite size of the individual segments with a fixed preferred direction result a deviation in the homogeneity of the interior generated field. The magnet system is used only in a few Segments divided, so on the one hand is the effort relatively small to manufacture; on the other hand, they are Deviations in the magnetic field are significant. By a finer segmentation can adversely affect the deviations in the Magnetic field homogeneity can be reduced, however at the same time, the manufacturing effort increases corresponding. Another difficulty is that the individual magnet segments are first magnetized and then in the magnetized state to the magnet system must be put together.

The object of the invention is therefore to provide a ring, tube or spherical Halbach system to indicate that small deviations in the field homogeneity at the same has low manufacturing costs in time. The task is by a permanent magnet system with the characteristics of Claims 1 or 2 solved. It is also a task of the invention, a magnetization process for the Specify above magnet systems. This task will by a method having the features of claim 3 solved.  

The magnet system according to the invention is in one piece or with only a few segments made of isotropic permanent magnet material built up. With the one-piece design ins special ring or tubular magnet systems be put. The magnet system consists of a few seg ment, it is provided according to the invention that the Preferred direction also locally within the segments varies. In contrast to the well-known segmented According to the invention, magnet systems become the complete magnet magnetized, namely by a cylinder or spherical magnetizer in the body is introduced, which is a homogeneous inside Magnetic field generated. With the magnetizing device it is preferably one in the desired Field direction homogeneously magnetized, anisotropic, cylindrical or spherical permanent magnets or around a coil, the shape and structure of which will be described.

The advantages of the magnet system according to the invention lie in that this consists of one or a few pieces and thus comparatively inexpensive to manufacture can. It is not an individual processing of segments and little or no installation effort required. In addition is the magnetization at every location of the magnet system provided according to the Halbach regulation, and it there are no or only minor deviations in the field homogeneity. This is particularly advantageous Magnet system according to the invention if its wall thickness in Ratio to the diameter is small. With such a Magnetic system would otherwise be the necessary segmentation according to the prior art particularly complex.

In contrast, the magnetization according to the invention of such a system is particularly simple and the fro position of isotropic magnet systems made of plastic-bonded Materials particularly preferred. This can be advantageous Magnet system according to the invention in particular there  be set where only comparatively small fields are required because then thin walls are required and are made of easily magnetizable ferrite material is sufficient. There are economic advantages especially with larger quantities, because the costs for Production and assembly of a segmented design essentially proportional according to the prior art to the number of pieces, while the cost of inventing Magnetizing device according to the invention arise only once.

In principle, only isotropic materials with a BH characteristic that is approximately linear in the second quadrant or materials in which the coercive field strength is significantly greater than the ratio of remanence Br to the magnetic field constant μ _o are suitable as magnetic material. These are, in particular, sintered or plastic-bonded ferrites and rare earth magnets in the form of isotropic sintered magnets and plastic-bonded magnets of the Nd-Fe-B or Sm-Fe-N type.

In the following the invention based on the embodiment examples and the drawings explained in more detail. Show it:

Fig. 1 is a graphical representation of the Halbach regulation;

Fig. 2 shows an inventive tubular magnet system;

Figure 3 is a tubular magnet system in a segmented construction according to the prior art.

Fig. 4 shows a cylindrical magnetizing coil and a magnetic body to be magnetized

Fig. 1 shows a cross section through an annular, tubular or spherical magnet system. The direction of the field of the homogeneous magnetic field inside the system is shown as an open arrow and a direction of magnetization at a specific location of the magnet system as a closed arrow. Furthermore, the corresponding angles to illustrate the Halbach regulation are Darge. The angle between the magnetic field direction and the preferred direction is designated by gamma and the location coordinate by phi.

The invention is based on the knowledge that - as well like a magnetized according to the condition gamma = 2 phi Cylinder in its interior a homogeneous transverse Field generated - a homogeneously transversely magnetized cylindrical permanent magnet reversed in its Generates a magnetic field, the direction of which Halbach condition specified above is sufficient. It deals is a 2D dipole field. The same applies to the three-dimensional case of a structure according to Halbach Regulation that is azimuthal, i.e. H. around the field axis is symmetrical, or homogeneous in the case of an inner magnetized permanent magnet ball. This is followed in following not specifically pointed out. Is it a spherical magnet system, this must be divided at least once to the magnetizer to be able to insert and remove the device, d. H. Such a device must consist of at least two segments consist. Essential for the magnet according to the invention systems is to do without segmentation Direction of magnetization or the presence of different Magnetization directions in a single part of the Magnet system.

In Fig. 2, a magnet system according to the invention is Darge, which is tubular and consists of a single part made of isotropic permanent magnet material. The preferred direction in the magnetic material varies locally. In comparison, a magnet system according to the prior art is shown in FIG. 3. This is assembled from individual segments, each segment having a fixed preferred direction. Due to the finite segmentation, there are deviations in the homogeneity of the magnetic field inside the system.

The magnetization of the magnet system according to the invention can by a homogeneously magnetized anisotropic cylindrical or spherical permanent magnets. The magnetizing field of this permanent magnet should basically larger than local internal stray fields and far-reaching demagnetization fields and therefore preferably in the order of remanence of the iso tropical magnetic material. For the special case one quickly quenched plastic bonded magnet NdFeB types, however, become significantly larger magnets preferred fields. Enter in the magnet systems magnetizing fields that are oblique to the desired one The direction of the field can lie and at most the order of magnitude achieve remanence. Certain deviations from the local Magnetization direction from that according to the Halbach This makes regulation ideal direction inevitable. However, the larger the magnetizer, the weaker they are field in relation to these demagnetizing fields is.

Alternatively, the magnetization of the permanent magnet system according to the invention can also take place by means of a coil which is cylindrical or spherical. With such coils, the lateral surfaces must be energized and the current density in the field direction must be constant. For example, a coil that is wound on the surface of a sphere in the direction of latitude with a constant axial winding spacing creates a dipole field on the outside and a homogeneous field from pole to pole in the center, just like a spherical permanent magnet. Such coils produce the desired configuration for magnetizing the magnet system in a single step without a limitation in the field strength, as is the case when using a permanent magnetic magnetizing device. In the case of a cylindrical coil, there are deviations from the Halbach configuration at the two coil ends. The magnetizing coil must therefore be longer than the magnet system. This is also shown in FIG. 4, for example.

Fig. 4 shows a tubular magnet system 1 and a coil 2 arranged inside it, which is formed from conductors 3 . The current direction is shown in Fig. 4 as well as the resulting field direction. A short, strong current pulse is applied to the magnetizing coil in the usual way. The resulting strong forces of the current conductors on the aquator (phi = 90 °) can generally not be absorbed by the magnet system itself. Therefore, it is advantageous to provide external support by a strong non-magnetic cylinder into which the cylindrical magnet system is fitted or clamped for magnetization.

The magnetizing coil can still go high permeable iron core included. Next to the coil field is then the demagnetizing field of the iron core homogeneous. The cylinder ends are an exception. The external field for magnetizing the magnet system is thereby reinforced, but in its directional configuration not changed fundamentally. Desirably with such an arrangement local deviations from the ideal Halbach configuration, which is characterized by the result in a finite number of conductors through which counteracted more uniform field of the iron core.

Claims (5)

1. Ring or tubular permanent magnet system with a locally varying preferred direction for generating a homogeneous magnetic field in its interior according to the formula gamma = 2 _* phi, where gamma is the angle between the magnetic field direction and the preferred direction and phi is the location coordinate, characterized in that Permanent magnet system is made in one piece from isotropic permanent magnet material. 2. Ring, cylinder or spherical permanent magnet system made up of a few segments with a locally varying preferred direction for generating a homogeneous magnetic field in its interior according to the formula gamma = 2 _* phi, where gamma is the angle between the magnetic field direction and the preferred direction and phi is the spatial coordinate , characterized in that the preferred direction also varies locally within the segments. 3. A method for magnetizing an annular, tubular or spherical body made of isotropic permanent magnet material with a locally varying preferred direction such that the magnetized body in turn generates a homogeneous magnetic field in its interior according to the formula gamma = 2 _* phi, where gamma is the angle between the magnetic field direction in the interior of the body and the preferred direction and phi is the spatial coordinate, by introducing into the body a cylindrical or spherical magnetizing device which generates a homogeneous magnetic field in its interior. 4. The method according to claim 3, characterized in that as a magnetizing device, a homogeneously magnetized anisotropic, cylindrical or spherical permanent magnet is used. 5. The method according to claim 3, characterized in that a coil is used as a magnetizing device, which is cylindrical or spherical, the side surfaces are energized and their current density is constant in the field direction.