The invention relates to a method for magnetizing at least two magnets having different magnetic coercivities.
Polarized electromagnetic relays are known which may each have a magnet system comprising a coil, a magnetic core and two permanent magnets. Such a polarized electromagnetic relay is known for example from WO 2013/144232 A1.
The problem addressed by the present invention is to provide a method with which at least two magnets can be differently magnetized in a simple, rapid, flexible and cost-effective manner.
A key concept of the invention can be considered that of exposing at least two magnets having different magnetic coercivities simultaneously to a first magnetic field and then simultaneously to a second magnetic field which have opposite magnetic field directions, such that the two magnets have different magnetizations at the end of the magnetization process. For this purpose, the magnets are preferably arranged together in a magnetization device, which for example comprises a magnetization coil, before they are magnetized according to the invention.
The magnets magnetized in this way can be used in particular as permanent magnets in an electromagnetic relay. It should be noted that the at least two magnets can initially be unmagnetized or premagnetized as desired before they are exposed to the first magnetic field.
The above-mentioned technical problem is solved by the method steps in claim 1.
Accordingly, a method for magnetizing at least two magnets having different magnetic coercivities is provided, which method comprises the following method steps:
a) simultaneously exposing the at least two magnets to a first substantially homogeneous magnetic field having a predeterminable first field strength and a first magnetic field direction for completely magnetizing the magnets in the first magnetic field direction;
b) simultaneously exposing the magnets magnetized in step a) to a second substantially homogeneous magnetic field having a predeterminable second field strength and a second magnetic field direction opposite to the first magnetic field direction such that the at least two magnets are differently magnetized, the first field strength being higher than the second field strength.
If exactly two magnets are magnetized in this way, they can be considered to be an assembly having the properties of a three-pole magnet.
It should be noted that the at least two magnets can initially be unmagnetized or premagnetized before they are exposed to the first and then the second magnetic field. The premagnetization can take place in a predetermined manner or in any manner. In other words, the level of the premagnetization can be predetermined or can be selected as desired.
The term “completely magnetize” can be understood to mean that the magnets are magnetized to magnetic saturation.
Expediently, before carrying out steps a) and b), the at least two magnets are arranged in a magnetization device, the first and second magnetic fields being provided by the magnetization device. The first and second homogeneous magnetic fields are preferably generated in an interior of the magnetization device in which the magnets are arranged.
The magnetization device may comprise a magnetization coil, a device electrically connected to the magnetization coil for generating an adjustable excitation current, in particular a pulse magnetization device, and optionally a carrier assembly for receiving and retaining the magnets.
In relation to the first and second magnetic field directions, the magnets are arranged one behind the other, such that the magnets are magnetized axially or in the field direction.
In an advantageous manner, in step b), the predeterminable second field strength of the second magnetic field can be set such that the at least two magnets are magnetized in opposite directions, the magnet having the higher magnetic coercivity being magnetized in the first magnetic field direction and the magnet having the lower coercivity being magnetized in the second magnetic field direction.
The invention is explained in greater detail in the following on the basis of an embodiment, in which:
The assembly 10 preferably has a carrier component 50, which may have a U-shaped cross section. In this case, the carrier component 50 has two opposite wall portions 51 and 52 and a base portion 53 connecting the two wall portions. Although the two magnets 20 and 22 can be arranged immediately next to one another, in the example shown they are arranged between magnetic flux parts 30, 31 and 32 and thus are spatially separated from one another.
As also shown in
The magnetic flux part 31 forms a bearing piece for a rocker armature (not shown), while the two magnetic flux parts 30 and 32 form the poles of an electromagnet. The magnetic flux parts 30, 31 and 32 and the two magnets 20 and 22 are supported by a support plate 40. The magnetic flux parts 30 to 32, the magnets 20 and 22 and the support plate 40 are arranged above the base portion 53 between the two wall portions 51 and 52 and enclose a receiving region 110 together with the carrier component 50, in which components of a magnet system can be arranged, as is shown by way of example in
Two connection pins 100 and 101 protrude from the carrier component 50, the connection pin 71 acting, for example, as a load connection pin and the connection pin 70 being provided for electrical connection to a fixed contact of a polarized electromagnetic relay shown by way of example in
Before the assembly 10 comprising the two magnets 20 and 22 is inserted into the polarized electromagnetic relay shown in
The entire assembly 10 is preferably first arranged in a magnetization device 80, as shown by way of example in
As shown in
Advantageously, the magnetization coil 60 arranged in the housing 75 completely encloses the inserted assembly 10 and thus the two magnets 20 and 22 in the mounted state, as shown in
It should be noted at this point that the current source (not shown) can provide a first adjustable excitation current which can produce a first substantially homogeneous magnetic field having a predeterminable field strength in the interior 62 of the magnetizing coil 60, which magnetic field has a first magnetic field direction pointing in the positive z direction. The current source can also provide a second adjustable excitation current which can produce a second substantially homogeneous magnetic field having a predeterminable field strength in the interior 62 of the magnetizing coil 60, which magnetic field has a second magnetic field direction pointing in the negative z direction.
It should be noted at this point that the field strength of the first magnetic field is greater than the field strength of the second magnetic field. Furthermore, it should be noted that the first excitation current may be 1000 to 5000 A, for example, while the second excitation current is set to 200 A, for example.
The method for differently magnetizing the magnets 20 and 22 will now be explained in more detail on the basis of a plurality of embodiments in conjunction with
It is assumed that the assembly 10 having the two magnets 20 and 22, which can be unmagnetized or premagnetized as desired, is arranged in the carrier assembly 80 and thus in the magnetization coil 60, as shown by way of example in
It can be seen from
An assembly having the properties of a three-pole magnet then results from the two magnets 20 and 22 which were previously unmagnetized or premagnetized as desired, namely an assembly having two outer north poles and a common inner south pole.
Number | Date | Country | Kind |
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2017/5552 | Aug 2017 | BE | national |
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PCT/EP2018/071813 | 8/10/2018 | WO | 00 |
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WO2019/030399 | 2/14/2019 | WO | A |
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