DE4013683A1 - Permanent magnetic strip for therapeutical applications - uses perforation-cavity technique to create magnetically induced multi-pole surface field - Google Patents

Abstract

The magnetic strip (1) consists of highly coercive permanent magnetic particles bonded in a flexible synthetic material and is axially magnetised such that one surface (6) is polarised as a North pole and the opposite surface (7) as a South pole. The surface of the magnetic strip is perforated with a variety of holes/cavities (8) having a dia. 5 to 30 times that of the strip thickness. This constructional technique produces an intensified magnetic induction effect which creates poles of opposite polarity to the strip surface (6.7) at the hole/cavity (8) centres, thus establishing an evenly distributed multi-pole magnetic field throughout the length of the magnetic strip (1). USE/ADVANTAGE - Thin, flexible permanent magnetic strips suitable for cushions, under blankets, shoesoles etc. Magnetic strips produce intensive, evenly distributed magnetic field with constant penetration depth. Cheap to mfr.

Description

The invention relates to a permanent magnet, in particular for therapeutic applications, with axial magneti sation.

Permanent magnets are both in different shapes Holding magnets as well as for use in medicine therapeutic area used. They usually consist of highly coercive permanent magnetic materials, as with for example with a barium and / or strontium ferrite or rare earth magnet materials, e.g. B. Neodymium Iron Boron. For the production such permanent magnets, the magnetic material itself in Form of small magnetic particles that exist that in flexible thermoplastics or for example rigid polymers, such as B. nylon-6, are embedded. This material can then, for. B. by extrusion, Calendering or injection molding process to any shape bodies, especially flat shape, processed will.

As holding magnets, these highly coercive, mostly flexible magnets are usually magnetized on one side with multiple poles with an alternating pole sequence after their manufacture, since with axial magnetization, i.e. in the direction of their smallest thickness, magnetization taking place there is no or only extremely low adhesive forces due to a lack of surface induction in the surface area have outside the peripheral zones. With one-sided lateral multi-pole magnetization with strip-shaped pole arrangements, particularly high induction values result directly at the pole edges. Due to the relationship F = c × B ^{2, the} adhesive force is proportional to the square of the induction, the proportionality factor c also including the area of the magnet exhibiting the high induction values.

Magnets multipolar magnetized on one side are also used in the therapeutic area applied. These are supposed to Magnets advantageously not only have high induction values, but also beyond be as flexible and light as possible so that they Adapt body shapes better and because of their small size Weight when wearing.

Cost savings by reducing the thickness of the Permanent magnets, however, cause a certain pole stood with one-sided lateral, multi-pole magneti sation, for example from 5 mm from the pole center to Pole center, a reduction in the desired induction value te. In addition, the manufacture of such permanent magnets technically very complex and therefore expensive. Therefore become axial, d. H. towards their smallest thickness, magnetized permanent magnets despite their smaller upper area induction preferred. These can be significantly easier to manufacture and are in medical-therapeutic area because of their large spreading depth particularly advantageous.

The invention has for its object a permanent stomach neten, especially for therapeutic applications axial magnetization, to create the despite low  Thickness on its magnetized surface with areas has high induction values.

The object is achieved in that the Permanent magnet one or more openings and / or one or several fractured depressions towards it Has magnetization.

Because of the breakthroughs or fractured depressions marginal zones within the magneti based surface formed compared to a uninterrupted surface high induction values exhibit.

By forming the breakthroughs or fragments Wells on the otherwise or previously unipolar Surface of the permanent magnet can be one of the number of these Number of breakthroughs or depressions opposite poles can be obtained. That way won a multipole arrangement on this surface, which are characterized by high induction values even in the middle of the Breakthroughs or recesses.

In a preferred embodiment of the invention axially magnetized permanent magnet essentially flat designed so that it has a flat side on one North Pole and on the opposite side a South Pole having.

Instead of a pole on each flat side of the axially Magnetized permanent magnets can also have multiple poles alternating sign on the relevant page and opposite, opposite poles on the other be provided on the flat side. The breakthroughs or fractured depressions are then within the different pole faces arranged, their diam  ser is preferably many times less than that smallest extension of the respective pole face.

The permanent magnet can, however, instead of a flat one Design can also take any other form, e.g. B. a curved surface and / or bumps, such as Knobs, have and thus z. B. as part of a shoe insole can be used.

Breakthroughs are preferably provided, which as of Magnetic material laterally surrounded holes are formed. In the edge area of such holes, higher induction values than achieved in the flat area of the permanent magnet will. The smaller the holes are, the higher is the magnetic induction in its edge areas. Also in the intermediate areas between the holes and the edge of the permanent magnet and between the holes the induction values among each other are higher than for missing holes.

The openings or holes can have any shape exhibit. In the simplest version, the holes are round or rectangular. But they can also be used as polygons or special geometric figures, such as B. rosettes, be trained.

The size and arrangement of the holes can also be any to get voted. So z. B. star or circular Arrangements possible. To generate one if possible uniform therapeutic effect Diameter and the distance between the holes and dimensioned from the edge of the permanent magnet so that about the same induction values in the middle of the holes and in the middle of the areas in between, where the induction values measured in the area of the holes For example, a north pole and the center of the intermediate ranges measured induction values  represent a south pole.

In an embodiment according to the invention, the Hole diameter at least equal to the thickness of the permanent stomach nets in the area of the hole. The is preferably Hole diameter 5 to 30 times the thickness of the Permanent magnets. One occurs in the middle area Hole in one with a specific pole (e.g. one North Pole) a particularly high magnetized area Induction value of reverse polarity (a south pole).

If fractured depressions are used, this occurs Pole of opposite sign in the area of the depressions already appear when the thickness of the lead bridges about 50% of the thickness of the surrounding magnet materials or less. Preferably, the Web thickness at most 25% of the thickness of the surrounding Magnetic material.

Just like the breakthroughs, the fractured ones can Depressions of any shape and arrangement on the Have surface of the permanent magnet. The fractured Wells can e.g. B. by crushing, milling or molded into the permanent magnet using preheated stamps will.

The permanent magnets according to the invention are for the better Adaptation to the body surface preferred as flexible Magnetic foils formed. The flexible magnetic material can be plastic-bound by extrusion, calendering or be produced by injection molding. Other Rigid magnets are also considered.

The permanent magnets according to the invention can at least one side with a heat-storing layer be. Decorative coatings are also possible.  

In a further embodiment, the fiction moderate permanent magnets with at least one side be provided with soft magnetic inference. This increases the induction values on the opposite side.

The permanent magnets created in this way can be used to achieve this therapeutic effects among other things also as a therapy magnetic plaster and as magnetic components in therapeutic pillows, duvets, bandages, shoe soles len, prostheses and the like are used.

Preferred embodiments of the invention are in following described with reference to the drawing.

Show it:

Fig. 1 is a plan view of a strip-shaped permanent magnet having holes formed therein,

Fig. 2 shows a section along the line II-II in Fig. 1, with indicated partly field lines,

Fig. 3 is an enlarged view of, denoted by III section in Fig. 2

Fig. 4 induction profile over the surface of a permanent magnet without breakthroughs,

Fig. 5 induction profile over the surface of a permanent magnet with a central aperture,

Fig. 6 is a strip-shaped permanent magnet with different magnetized areas and ver

Fig. 7 shows a permanent magnet with a specific shape and arrangement of the openings.

The permanent magnets 1 to 5 shown in the drawing are designed as flexible magnetic foils. These are z. B. from barium and / or strontium ferrites or rare earth magnetic materials, e.g. B. neodymium-iron-boron, in the form of small magnetic particles, which in a flexible plastic binder such. B. thermoplastics, are tet and are produced by extrusion, calendering or injection molding to a body of flat shape. The magnetic foils are magnetized axially, that is perpendicular to their flat sides 6 and 7 , so that a north pole N is arranged on one flat side 6 and a south pole S is arranged on the other flat side 7 , opposite.

The permanent magnets 1 and 3 to 5 have openings which are designed as holes 8 which are laterally surrounded by the magnetic material.

In the embodiment shown in FIGS. 1 to 3, the holes 8 are circular and arranged in the form of circles, each surrounding a hole 8 . The diameter of the holes 8 is a multiple of the thickness of the magnetic film, for. B. 10 mm with a film thickness of 0.5 mm, 15 mm or 20 mm with a film thickness of 1 mm. As can be seen from FIG. 3, with such dimensional relationships, a south pole S appears in the central region of the hole 8 in the surface magnetized with a north pole N.

The magnetic effect caused by the holes 8 is shown in FIGS. 4 and 5.

Fig. 4 shows the course of induction over the surface of a permanent magnet 2 of the type described above with a thickness of 1 mm, which has no openings. This permanent magnet 2 only has higher induction values in its edge zones 9 , whereas this in the middle of the permanent magnet 2 drops approximately to the tenth part of the induction values measured in the edge zones 9 .

Fig. 5, however, shows the course of induction on the surface of a permanent magnet 1 of the same type and thickness, which has in its center a hole 8 having a diameter of 15 mm. With this permanent magnet 1, the induction values rise steeply again in the edge region of the hole 8 . They even exceed the induction values in the edge zone 9 of the permanent magnet 1 or 2 . In addition, the induction values between the edge zone 9 of the permanent magnet 1 and the edge region 10 of the hole 8 are higher than in the absence of the hole, as shown in FIG. 4. A reduction in the hole diameter leads to an increase in the magnetic induction in the edge region 10 of the hole 8 .

FIG. 6 shows a further exemplary embodiment of a permanent magnet 3 which has axially magnetized pole faces 11 and 12 arranged next to one another with an alternating pole sequence. The holes 8 are arranged in the interior of the pole faces 11 and 12 . Advantageously, the smallest dimension of the pole faces 11 and 12 is at least 40 times the material thickness in order to allow openings (shown enlarged in FIG. 6), the diameter of which is preferably many times smaller than the smallest dimension of a pole face.

As an alternative to the shape and arrangement of the holes 8 considered so far, they can be designed in any other way and arranged on the magnetized surfaces. Fig. 7 shows further examples. In the left half of FIG. 7, circular holes 8 are formed in a star shape in a permanent magnet 4 . In the right half of FIG. 7, a permanent magnet 5 is shown, which has circular holes 8 of different sizes and rectangular holes 8 of different shapes.

Other forms of holes and composed of them Geometric figures are easy to think about.

The permanent magnets broken through in this way can at least one of its flat sides with one (in the Drawing not shown) heat storage or decorative layer, e.g. B. is self-adhesive provided be.

In a further embodiment, these permanent magnets on at least one of its flat sides with a (in the drawing, not shown) soft magnetic Inference be provided.

Reference symbol list

1 permanent magnet
2 permanent magnet
3 permanent magnet
4 permanent magnet
5 permanent magnet
6 flat side
7 flat side
8 holes
9 edge zone of the magnet
10 edge area of the hole
11 pole face with north pole
12 pole face with south pole
N north pole
S South Pole

Claims (11)

1. Permanent magnet, in particular for therapeutic applications with axial magnetization, characterized in that it has one or more openings and / or one or more bruch-shaped recesses in the direction of its magnetization. 2. Permanent magnet according to claim 1, characterized ge indicates that the breakthroughs or Depressions within the magnetized surface are designed so that in their central areas to the pole (N) of the magnetized surface opposed poles (S) occur. 3. Permanent magnet according to claim 1 or 2, characterized in that it is formed ausgebil det, so that it has on its one flat side ( 6 ) a north pole (N) and on the opposite side ( 7 ) has a south pole (S). 4. Permanent magnet according to claim 1 or 2, characterized in that it is extensively ausgebil det, so that it has on its one flat side several poles (N, S) alternating sign and on the opposite side correspondingly opposite poles (S, N) has, and the openings or depressions in the pole faces ( 11 , 12 ) are net angeord. 5. Permanent magnet according to one of claims 1 to 4, characterized in that openings are provided which are formed as holes laterally surrounded by the magnet material ( 8 ). 6. Permanent magnet according to claim 5, characterized in that the holes ( 8 ) are round or rectangular. 7. Permanent magnet according to claim 6, characterized in that the hole diameter is at least equal to the thickness of the permanent magnet ( 1-5 ) in the region of the hole ( 8 ). 8. Permanent magnet according to claim 7, characterized in that the hole diameter is 5 to 30 times the thickness of the permanent magnet ( 1-5 ) in the region of the hole ( 8 ). 9. Permanent magnet according to one of claims 1 to 8, characterized in that he is designed as a flexible magnetic sheet and art bonded by extrusion, calendering or in Injection molding process is made. 10. Permanent magnet according to one of claims 1 to 9, characterized in that it is provided on at least one side ( 6 , 7 ) with a heat-storing layer. 11. Permanent magnet according to one of claims 1 to 10, characterized in that it is provided on at least one side ( 6 , 7 ) with a soft magnetic net inference.