KR100465020B1 - Transverse flux monopole magnetizer and the magnetizing method - Google Patents

Abstract

The present invention is to provide a transverse magnetic flux monopole magnetizer and a magnetizing method for attaching a permanent magnetic material without a magnetic field to an iron core and flowing an impulse current to a coil to magnetize the permanent magnetic material to have a residual magnetic field. To this end, the lateral flux monopolar magnetizer of the present invention comprises: a magnetizer winding wound around a magnetron core and a magnetizing current flows; The magnetizing iron core which forms a closed loop of magnetic flux through the magnetizing object when the magnetizing current is applied to the winding; It comprises a magnetizer driving means for supplying a magnetizing current to the magnetizer winding. Here, the magnetizing iron core is composed of a magnetic circuit for magnetically connecting the side and the top of the magnetized object.

Description

Transverse flux monopole magnetizer and the magnetizing method

The present invention relates to a lateral flux monopolar magnetizer and a method of magnetizing the same, and more particularly, a lateral flux type for attaching a permanent magnetic material without a magnetic field to an iron core and applying a pulse current to the coil to magnetize the permanent magnetic material to have a residual magnetic field. It relates to a unipolar magnetizer and a magnetizing method thereof.

Recently, with the development of high energy density permanent magnets, these high energy density permanent magnets have been introduced into new electrical and magnetic applications. Permanent magnet devices have the advantage of small size and light weight, simple maintenance, and high efficiency operation because they do not need a device for supplying windings, iron cores, and current to generate magnetic fields. Conventionally, a permanent magnet having a high magnetic field is attached to the surface of an iron core. In this case, it is difficult to attach the permanent magnet due to the strong repulsion force generated between the permanent magnets having a strong magnetic field. There is a risk that the permanent magnet may bounce off due to strong repulsive force, and in this case, there is a high risk of damaging the worker or surrounding equipment.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the transverse magnetic flux type single pole magnetizer which attaches a permanent magnetic material without a magnetic field to an iron core and flows an impulse current to a coil to magnetize the permanent magnetic material to have a residual magnetic field. And it aims to provide a magnetization method.

1 is a view showing a form in which a permanent magnet is magnetized on an iron core using a lateral magnetic flux monopolar magnetizer according to a first embodiment of the present invention;

2A and 2B are diagrams for explaining the magnetization principle of the lateral magnetic flux monopolar magnetizer of FIG. 1;

3 is a view showing a state of a permanent magnet after completion of magnetization to a permanent magnet on an iron core by using the lateral magnetic flux monopolar magnetizer of FIG.

4 is a diagram illustrating a magnetizing iron core of a lateral magnetic flux monopolar magnetizer of FIG. 1;

5 is a diagram illustrating a magnetizer winding of the lateral magnetic flux monopolar magnetizer of FIG. 1;

6 is a magnetization circuit diagram of a lateral flux type single pole magnetizer according to the present invention;

FIG. 7 is a diagram illustrating a form of magnetizing a permanent magnet on an iron core using a lateral magnetic flux monopolar magnetizer according to a second embodiment of the present invention;

8 is a view for explaining the magnetization principle of the lateral magnetic flux monopolar magnetizer of FIG.

FIG. 9 is a view illustrating a coupling state of a magnetizer winding and a magnetizer iron core of the lateral magnetic flux monopolar magnetizer of FIG. 7.

※ Explanation of code for main part of drawing

1,20 magnetizing iron core 2: magnetizing winding

3: permanent magnet 4: iron core

5: magnetic flux 6: AC power

7: transformer 8: rectifier diode

9: charging switch 10: magnet switch

11 charging capacitor 12 magnetization current

In order to achieve the above object, the lateral flux monopolar magnetizer according to the present invention includes: a magnetizer winding wound around a magnetron core and a magnetizing current flows; The magnetizing iron core which forms a closed loop of magnetic flux through the magnetizing object when the magnetizing current is applied to the winding; It characterized in that it comprises a magnetizer driving means for supplying a magnetizing current to the magnetizer winding. Here, the magnetized object is composed of an iron core to which a permanent magnetic material having no magnetic field is attached.

And, a preferred embodiment of the magnetizing iron core is composed of a magnetic circuit in which the magnetizing iron core magnetically connects the side and the top of the magnetizing object.

Further, another preferred embodiment of the magnetizing iron core is composed of a magnetic circuit in which the magnetizing iron core magnetically connects the lower part and the upper part of the magnetizing object.

In this case, the magnetizing iron core is preferably laminated. Preferably, the winding is wound around the pillar portion of the magnetizing iron core.

The magnetizer driving means includes: an AC power supply and a transformer connected to the AC power supply for boosting and outputting an input AC power supply; A charging element connected in parallel between the output terminal of the transformer and the magnetizer winding; A rectifier circuit connected in series between the output terminal of the transformer and the charging element to rectify the output of the transformer; A magnetization switch connected between the charging device and the magnetizer winding to supply and cut off a magnetizing current applied to the magnetizer winding, and a power source connected between the rectifying circuit and the charging device and applied to the charging device. And a charging switch for supplying and shutting off.

In addition, the horizontal magnetic flux monopolar magnetizing method of the present invention for achieving the above object, the first step of attaching a permanent magnetic material without a magnetic field to the upper portion of the iron core, and the permanent magnetic material to the iron core attached to the permanent magnetic material And a second step of causing a strong magnetic flux to flow in a direction perpendicular to the iron core. In the second step, the iron core to which the permanent magnet material is attached is divided into at least two sections, and a strong magnetic flux flows in the first vertical direction with respect to the first one of the iron cores, and the second section of the iron core to which the permanent magnet material is attached. It is preferable to perform a process for flowing a strong magnetic flux in a direction opposite to the first vertical direction with respect to all sections.

Here, the permanent magnet material is preferably made of a rare earth material, it is preferable to attach the permanent magnet material to the iron core by an adhesive.

Hereinafter, a lateral flux type single pole magnetizer and a magnetizing method thereof according to exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

First, a lateral flux type single pole magnetizer and a magnetization method thereof according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 6.

1 is a view showing a form in which a permanent magnet is magnetized on an iron core by using a lateral flux monopolar magnetizer according to a first embodiment of the present invention, and FIGS. 2A and 2B are views of the lateral flux monopolar magnetizer of FIG. 1. 3 is a view for explaining the principle of magnetization, Figure 3 is a view showing the state of the core and the permanent magnet after completion of magnetization to the permanent magnet material on the iron core using the lateral magnetic flux monopolar magnetizer of Figure 1, Figure 4 Fig. 5 is a diagram illustrating a magnetizing iron core of a lateral flux monopolar magnetizer, and FIG. 5 is a diagram illustrating a magnetizer winding of the lateral flux monopolar magnetizer of FIG. 1.

As shown in FIG. 1, the lateral magnetic flux type single pole magnetizer according to the first embodiment of the present invention has a magnetizing iron core 1 for reducing the applied current of the magnetizer and a magnetizer generating magnetic flux, and a current in the magnetizer. It is a very simple structure composed of a magnetizer winding (2) which flows through, and a permanent magnet material (3) and an iron core (4) to be magnetized by the magnetizer impulse current.

The magnetizer winding 2 is configured in a ring shape as shown in Figs. 1 and 5, and the magnetizer winding 2 is wound around the magnetizing iron core 1.

And, as shown in Fig. 1 and 4, the magnetizing iron core 1 has a lower side 1D facing one side of the iron core 4 of the magnetizing object and the other side of the lower side 1D. A pillar portion 1C integrally formed on the upper side, an upper portion 1A formed integrally with the pillar portion 1C and facing the lower portion 1D, and the pillar portion 1C side of the upper portion 1A. On the other side, the protrusion 1 is integrally formed in a direction parallel to the pillar portion 1C, and the protrusion surface is formed of the protrusion 1B facing the permanent magnet material 3 on the upper side of the magnetizing object.

Referring to FIGS. 2A and 2B, the magnetization principle is described. When a current flows through the magnetizer winding 2, a magnetic flux 5 is formed to magnetize the permanent magnet material 3 to be magnetized. As shown in Fig. 2A, when a current in the .x direction flows through the magnetizer winding 2, the magnetic flux 5 causes the upper side of the permanent magnet material 3 to magnetize to the S pole and the lower side to the N pole. In addition, as shown in FIG. 2B, when a current in the X direction flows through the magnetizer winding 2, the upper side of the permanent magnet 3 is magnetized to the S pole by the magnetic flux 5.

Here, in Fig. 1, Fig. 2A and Fig. 2B, the magnetizer winding 2 is wound around the pillar part 1C of the magnetizing iron core 1, but the magnetizer winding is a pillar part 1C of the magnetizing iron core 1; What is necessary is just to wind up in at least any one part of 1 A of upper part and 1 B of protrusions.

2A, 2B and 3, the transverse magnetic flux monopolar magnetizing method according to the present invention will be described.

First, the permanent magnet material 3 (for example, rare earth material) having no magnetic field is attached to the upper portion of the iron core 4 by, for example, an adhesive.

Thereafter, a strong magnetic flux flows in the direction perpendicular to the permanent magnetic material 3 and the iron core 4 to the iron core 4 to which the permanent magnetic material 3 is attached, thereby magnetizing the permanent magnetic material 3. Perform.

Here, in order to alternately form the magnetization direction in the permanent magnet material 3, the permanent magnet material 3 attached to the iron core 4 is divided into a plurality of sections at required intervals. Then, using the magnetizers 1 and 2 having a width corresponding to the interval of each section, the permanent magnet material 3 has a different magnetization direction for each section using the method of FIGS. 2A and 2B.

If the sections are equidistantly spaced, the same magnetizer is used to allow strong magnetic flux to flow in the first vertical direction in odd-numbered sections, and strong magnetic flux to flow in the opposite direction to the first vertical direction in even-numbered sections. As shown in Fig. 3, the permanent magnet material 3 can be magnetized. That is, when the permanent magnet is used in a general electric equipment (for example, an electric motor), the N pole and the S pole are alternately arranged so that if the magnetizer is moved by one pole, the direction of the current flowing through the magnet winding 2 is changed. It is possible to obtain a magnetized permanent magnet as shown in FIG.

4 is a view of the magnetizing iron core 1, which advantageously uses the iron core in a possible magnetic circuit in order for the magnetic flux generating flux to flow and to reduce the applied current of the magnetizing magnet. In order to prevent the magnetic flux from decreasing due to the eddy current generated in the iron core when impulse current is applied, a layered iron core may be used.

Next, an embodiment of a driving circuit for driving the lateral flux type single pole magnetizer according to the present invention will be described with reference to FIG. 6.

The magnetizer drive circuit includes a commercial AC power supply 6, a transformer 7 connected in parallel with the AC power supply 6 to boost an input AC power, and output a high voltage, and an output terminal of the transformer 7; The capacitors connected in parallel between the magnetizer windings 2 are connected in series between the charging capacitor 11 and the output terminal of the transformer 7 and the charging capacitor 11 to rectify the output of the transformer 7. Magnetizer switch (10) connected between the diode (8), the charging capacitor (11) and the magnetizer winding (2) to supply or cut off the magnetizing current (12) applied to the magnetizer winding (2) And a charging switch 9 connected between the diode 8 and the charging capacitor 11 to supply or cut off power applied to the charging capacitor 11.

Here, the magnetizing switch 10 is in an open state when the charging capacitor 11 is charged, and blocks the magnetizing current 12 from being supplied to the magnetizing winding 2, and the magnetizing winding When the supply of the magnetizing current of the (closed) state is closed so that the magnetizing current 12 is supplied to the magnetizer winding (2).

In addition, the charging switch 9 is operated to block the supply of power from the diode 8 when the magnetizing current is supplied to the magnetizer winding 2, and the diode is charged when the charging capacitor 11 is charged. Power is supplied from (8).

According to the magnetizer driving circuit configured as described above, a commercially available AC power supply 6 obtains a high voltage through a boosting transformer 7, and a charging capacitor 11 via a rectifying diode 8 and a charging switch 9. ) Is charged to a voltage of several kV, and then the magnetization switch 10 is turned on to supply the magnetizing current 12 of several kA to the magnetizer.

Next, a lateral flux type single pole magnetizer according to a second embodiment of the present invention will be described with reference to FIGS. 7 to 9.

FIG. 7 is a view illustrating a form in which a permanent magnet is magnetized on an iron core using a lateral flux monopolar magnetizer according to a second embodiment of the present invention, and FIG. 8 is a magnetization principle of the lateral flux monopolar magnetizer of FIG. 7. FIG. 9 is a diagram illustrating a coupling state of a magnetizer winding and a magnet core of the lateral magnetic flux monopolar magnetizer of FIG. 7.

The lateral flux type single pole magnetizer of this embodiment is composed of a magnetizer winding 2 and a magnetizer iron core 20, and the magnetizer winding 2 has the same configuration as that of the first embodiment of FIG. Detailed description will be omitted. The magnetizing iron core 20 has a lower portion 22 on which the iron core 4 as a magnetizing object is mounted on one side, and is integrally perpendicular to the upper side of the other side of the lower portion 22 so that the magnetizing machine winding 2 is formed. It is different from the pillar part 26 which is wound up, the upper part 24 which is integrally formed with the said pillar part 26, and opposes the said lower part 22, and the said pillar part 26 side of the said upper part 24. Protruding portion 24A is formed integrally from the side in the direction parallel to the pillar portion 26 and the protruding surface thereof faces the permanent magnet material 3 which is the upper side of the magnetizing object. Here, the magnetizer winding 2 may be wound around at least one of the pillar portion 26, the upper portion 24, and the protrusion portion 24A of the magnetizer iron core 20.

The magnetization principle of this embodiment is the same as that of FIG. 8, and when the magnetizing current flows in the opposite direction to FIG. 8, magnetization is performed in the opposite polarity to the permanent magnet material 3. In addition, the magnetization method using the lateral flux type single-pole magnetizer of the present embodiment is made by the same method as in the above-described first embodiment, and description thereof will be omitted. In addition, since the magnetizer driving circuit applied to the lateral magnetic flux monopolar magnetizer of the present embodiment may use the configuration of FIG. 6 as it is, description thereof will be omitted.

In the present embodiment, when the permanent magnet 3 of the magnetization target is small, the magnetic circuit may be long to some extent, so that the magnet may be magnetized very uniformly without magnetizing to the side as shown in FIGS. 1 and 2a and b. have.

As described above, in the present invention, a permanent magnetic material without a magnetic field is simply attached to an iron core, and an impulse current flows through the coil to magnetize the permanent magnetic material to have a residual magnetic field, thereby simplifying permanent magnet operation and improving productivity and product quality. It can improve and eliminate the risk of permanent magnet attachment. In addition, since high energy density permanent magnets, such as rare earth permanent magnets, require a residual magnetic flux of about 1.2T, a magnetic flux density of about 4T, which is three times higher than the residual magnetic flux, is required to completely magnetize the permanent magnet. In this case, since the iron core of the magnetizer is greatly saturated, a very large magnetizing current is required, and thus a magnetizer having a short application path of magnetic flux is required. The lateral flux type single-pole magnetizer according to the present invention has a short capacity because it is possible to magnetize a permanent magnet with a relatively small magnetizing current because the path of application of the magnetic flux of the magnetizer is short in the direction of the current and the magnetic flux of the magnetizer. Magnetization becomes possible.

On the other hand, the present invention is not limited to the above-described typical preferred embodiments, but can be carried out in various ways without departing from the gist of the present invention, various modifications, alterations, substitutions or additions are common in the art Those who have knowledge will easily understand. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended claims, the technical idea should also be regarded as belonging to the present invention.

As described in detail above, according to the present invention, the permanent magnet material without a magnetic field is simply attached to the iron core and the impulse current flows through the coil to magnetize the permanent magnetic material to have a residual magnetic field, thereby making the permanent magnet work simple, thus improving productivity and product quality. It is possible to improve, and since the permanent magnet is not attached as in the prior art can eliminate the risk of injury. In addition, in the conventional magnetizer, since the length of the magnetic circuit is long, a large magnetizing current is required. Since it is possible to magnet the permanent magnet with a relatively small magnetizing current, it is possible to magnetize the magnet with a small capacity.

Claims (15)

A magnetizer winding wound around the magnetizing iron core and carrying an impulse current; The magnetizing iron core which forms a closed loop of magnetic flux through an iron core to which a permanent magnetic material having no magnetic field is attached upon application of an impulse current to the winding; And a magnetizer driving means for supplying an impulse current to the magnetizer winding. delete delete delete The method of claim 1, The magnetizing iron core, the lower side and one side facing the side of the magnetized object; A pillar portion integrally formed on the upper side of the other side of the lower portion; An upper portion formed integrally with the pillar portion to face the lower portion; The horizontal magnetic flux monopolar magnetizer, characterized in that the protrusion formed in a direction parallel to the pillar portion integrally different from the side of the pillar portion of the upper portion and the projection surface thereof faces the upper side of the magnetized object. The method of claim 1, The magnetizing iron core, and a lower portion on which the magnetizing object is mounted; A pillar portion integrally formed on the upper side of the other side of the lower portion; An upper portion formed integrally with the pillar portion to face the lower portion; The horizontal magnetic flux monopolar magnetizer, characterized in that the protrusion formed in a direction parallel to the pillar portion integrally different from the side of the pillar portion of the upper portion and the projection surface thereof faces the upper side of the magnetized object. The method of claim 1, The magnetizer driving means includes an AC power supply; A transformer connected to the AC power supply for boosting and outputting an input AC power; A charging element connected in parallel between the output terminal of the transformer and the magnetizer winding; A rectifier circuit connected in series between the output terminal of the transformer and the charging element to rectify the output of the transformer; A magnetization switch connected between the charging element and the magnetizer winding to supply and block magnetizing current applied to the magnetizer winding; And a charging switch connected between the rectifier circuit and the charging device to supply and cut off power applied to the charging device. The method of claim 7, wherein The magnetizing switch is a lateral flux type single-pole magnetizer, characterized in that the supply of the magnetizing current to the magnetizer winding during the charging of the charging element. The method of claim 7, wherein And the charging switch is operable to cut off power supply from the rectifier circuit upon supply of magnetizing current to the magnetizer winding. delete The method according to any one of claims 1 and 5 to 9, And the winding is wound around at least one of a pillar portion, an upper portion, and a protrusion of the magnetizing iron core. Attaching a permanent magnetic material having no magnetic field on top of the iron core; The iron core to which the permanent magnetic material is attached is divided into at least two sections, and a strong magnetic flux flows in a first vertical direction with respect to the first section, and the first section to the second section of the iron core to which the permanent magnetic materials are attached. And a second step of performing all the sections in such a manner that a strong magnetic flux flows in a direction opposite to the vertical direction. delete delete delete