KR20230132963A - Magnetic field generator - Google Patents

Abstract

The present invention relates to a magnetic field generating device, comprising a first moving plate provided with a first magnet, and a second moving plate provided with a second magnet facing the first moving plate and having a polarity opposite to that of the first magnet. and a rotation shaft that is spirally coupled to the first movable plate and the second movable plate and moves the first movable plate and the second movable plate in opposite directions according to the rotation direction, and is fixedly coupled to the first movable plate or the second movable plate. It is provided between the first movable plate and the second movable plate, and includes a repulsive force applicator that applies a repulsive force to the first movable plate and the second movable plate.

Description

Magnetic field generator {MAGNETIC FIELD GENERATOR}

The present invention relates to a magnetic field generating device, and more specifically, to a magnetic field generating device for a secondary battery manufacturing process that can cancel out the attractive force between magnets by applying a repulsive force between magnets with opposite polarities to generate a magnetic field. It's about.

Generally, in the secondary battery manufacturing process, magnetic equipment is used to align and align copper foil, which is a material for secondary battery manufacturing, using a magnetic field. Magnet equipment uses magnetic fields generated between magnets with opposite polarities to arrange and align the transported copper foil materials for manufacturing secondary batteries.

Magnetic equipment in the prior art moves magnets in opposite directions by driving a motor equipped with a reducer so that an attractive force acts between magnets with opposite polarities facing each other, thereby minimizing the gap between magnets.

However, in order to widen the gap between magnets, the strong attractive force acting between the magnets must be overcome, and since this places a lot of load on the motor, the strong attractive force had to be overcome only by increasing the capacity of the motor and reducer. Therefore, there was a problem that the magnetic equipment became larger, which inevitably increased the manufacturing and operating costs of the equipment.

The background technology of the present invention is disclosed in Republic of Korea Patent Publication No. 10-1556049 (2015.09.25 notice, title of invention: Non-aqueous electrolyte secondary battery and manufacturing method thereof).

The object of the present invention, which was devised to solve the above-mentioned problems, is to provide a magnetic field generating device that can cancel out the attractive force between magnets by applying a repulsive force between magnets with opposite polarities to generate a magnetic field.

The present invention, devised to achieve the above object, is a magnetic field generating device, which includes a first moving plate equipped with a first magnet, a second moving plate facing the first moving plate and having a polarity opposite to the polarity of the first magnet. A second moving plate equipped with a magnet, a rotation axis spirally coupled to the first moving plate and the second moving plate, and moving the first moving plate and the second moving plate in opposite directions according to the rotation direction, and A repulsive force applicator is fixedly coupled to the first movable plate or the second movable plate, is provided between the first movable plate and the second movable plate, and applies a repulsive force to the first movable plate and the second movable plate. Includes.

The repulsive force application unit includes a hollow housing portion with openings at both ends, an elastic member accommodated inside the housing portion, a fixing block fixedly coupled to one end of the opening of the housing portion and supporting one side of the elastic member, and the other end of the housing portion. It is characterized in that it includes a moving block that is partially inserted into the inside of the housing portion through the opening to elastically support the other side of the elastic member, and is moved in and out of the housing portion by the elasticity of the elastic member.

The outer surface of the moving block is characterized in that a coupling part coupled to the first moving plate or the second moving plate is provided.

It is characterized in that it includes a limiting protrusion formed on the outer surface of the fixed block and the moving block, respectively, to limit the moving distance of the moving block when the elastic member is contracted.

The repulsive force applicator includes a hollow housing portion with openings at both ends, an elastic member accommodated inside the housing portion, and a portion of the repulsive force application portion inserted into the inside of the housing portion through an opening at one end of the housing portion to elastically support one side of the elastic member, A first moving block that moves in and out of the housing part by the elasticity of the elastic member is partially inserted into the inside of the housing part through an opening at the other end of the housing part to elastically support the other side of the elastic member, and elastically supports the other side of the elastic member. It is characterized in that it includes a second moving block that moves in and out of the housing portion.

The outer surface of the second moving block is characterized in that a coupling portion coupled to the first moving plate or the second moving plate is provided.

Characterized in that it includes a limiting protrusion formed on the outer surface of the first moving block and the second moving block, respectively, to limit the moving distance of the first moving block and the second moving block when the elastic member is contracted. do.

A first fixed plate provided outside the first movable plate and rotatably coupled to the rotation shaft, provided outside the second movable plate and disposed to be spaced apart from the first fixed plate, and the rotation shaft rotates. A second fixed plate movably coupled, a fixed shaft fixed between the first fixed plate and the second fixed plate, and movably coupled to the first movable plate and the second movable plate, and the second fixed plate. It is provided on the outer surface of and is coupled to the rotation shaft, characterized in that it includes a driving part that provides rotation power to the rotation shaft.

The outer surface of the rotating shaft includes a first spiral portion with a thread formed up to one end with respect to the central portion of the rotating shaft, and a second spiral portion with a screw thread formed up to the other end in a direction opposite to the rotation direction of the first spiral portion. It is characterized by:

When the first moving plate and the second moving plate are close to each other, a magnetic field applying portion is formed between the first moving plate and the second moving plate where an attractive force between the first moving plate and the second moving plate acts. It is characterized by

The present invention can offset the attractive force between the first magnet and the second magnet by using the elastic restoring force of the elastic member, so the load on the motor and reducer can be reduced, reducing the capacity of the motor and reducer, and manufacturing and operating costs by miniaturizing the equipment. There is an effect of saving.

1 is a front view showing a magnetic field generating device according to an embodiment of the present invention;
Figure 2 is a perspective view showing a magnetic field generating device according to an embodiment of the present invention;
Figure 3 is a cross-sectional view showing a first embodiment of the repulsive force application part in the magnetic field generating device according to an embodiment of the present invention;
Figure 4 is a cross-sectional view showing a second embodiment of the repulsive force application part in the magnetic field generating device according to an embodiment of the present invention;
Figure 5 is a cross-sectional view and an enlarged view showing an operating state in which attractive force is applied between magnets in a magnetic field generating device according to an embodiment of the present invention;
Figure 6 is a cross-sectional view and an enlarged view showing an operating state in which a repulsive force is applied between magnets in the magnetic field generating device according to an embodiment of the present invention.

Hereinafter, an embodiment of a magnetic field generating device according to the present invention will be described with reference to the attached drawings. In this process, the thickness of lines or sizes of components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Figure 1 is a front view showing a magnetic field generating device according to an embodiment of the present invention, and Figure 2 is a perspective view showing a magnetic field generating device according to an embodiment of the present invention.

Referring to Figures 1 and 2, the magnetic field generating device according to a preferred embodiment of the present invention includes a first moving plate 100, a second moving plate 200, a rotating shaft 300, a repulsive force application unit 400, and a first moving plate 100. 1 It is composed of components including a fixing plate 500, a second fixing plate 600, a fixing shaft 700, and a driving unit 800, which will be described in detail as follows.

The first moving plate 100 is provided horizontally in a flat plate shape, and a first magnet 110 is provided on its upper surface. The first magnet 110 has a flat plate shape and is horizontally coupled to the first moving plate 100. The first magnet 110 may be a permanent magnet or an electromagnet.

The second moving plate 200, like the first moving plate 100, has a flat plate shape and is provided horizontally on the upper side of the second moving plate 200. The first moving plate 100 and the second moving plate 200 are arranged in parallel to face each other.

A second magnet 210 is provided on the lower surface of the second moving plate 200. Like the first magnet 110, the second magnet 210 has a flat plate shape and is horizontally coupled to the second moving plate 200. The second magnet 210 may be a permanent magnet or an electromagnet.

Accordingly, the first magnet 110 and the second magnet 210 face each other. At this time, the first magnet 110 and the second magnet 210 facing each other have opposite polarities. For example, if the first magnet 110 and the second magnet 210 are permanent magnets, the lower part of the first magnet 110 in contact with the upper surface of the first moving plate 100 is the N pole and the upper part is the S pole. , the upper part of the second magnet 210 in contact with the lower surface of the second moving plate 200 becomes the S pole and the lower part becomes the N pole.

The rotation axis 300 is perpendicular to the first moving plate 100 and the second moving plate 200, and sequentially passes through the first moving plate 100 and the second moving plate 200 to form the first moving plate ( 100) and is spirally coupled to the second moving plate 200. The first movable plate 100 and the second movable plate 200 are simultaneously moved in opposite directions according to the axis rotation direction of the rotation shaft 300.

The rotation shaft 300 includes a first spiral portion 310 and a second spiral portion 320.

The first spiral portion 310 is provided on the outer surface of the rotating shaft 300, and a thread is formed from the central portion of the rotating shaft 300 to one end.

To elaborate, the first spiral portion 310 is formed with a screw thread that rotates in one direction from the central portion of the rotating shaft 300 to the lower end of the rotating shaft 300. Accordingly, the first moving plate 100, which is helically coupled to the first helical portion 310, moves up and down along the first helical portion 310 according to the forward/reverse rotation direction of the rotation shaft 300.

The second spiral portion 320 is provided on the outer surface of the rotating shaft 300, and a thread is formed from the central portion of the rotating shaft 300 to the other end.

To elaborate, the second spiral portion 320 is formed with a screw thread that rotates in a direction opposite to the rotation direction of the first spiral portion 310 from the center of the rotation shaft 300 to the upper end of the rotation shaft 300. Accordingly, the second moving plate 200, which is helically coupled to the second helical portion 320, moves up and down along the second helical portion 320 according to the forward/reverse rotation direction of the rotation shaft 300.

The rotation axis 300 is rotated in one direction to raise the first moving plate 100, and at the same time, the second moving plate 200 is lowered so that the first moving plate 100 and the second moving plate 200 When they approach each other, the first magnets 110 and second magnets 210 provided on the first moving plate 100 and the second moving plate 200, respectively, also come close to each other while facing each other.

Between the first magnets 110 and the second magnets 210 that face each other and are close to each other, that is, between the first moving plate 100 and the second moving plate 200, the first moving plate 100 and the second moving plate (200) The magnetic field application part 900 in which a magnetic field is generated is formed by the action of attraction between the magnetic fields.

As the copper foil material for secondary battery manufacturing passes through the magnetic field application unit 900, where a magnetic field is generated by the attraction between the first magnet 110 and the second magnet 210 that are close to each other, the material is arranged and aligned by the magnetic field. do.

At this time, the rotation shaft 300 is rotated in the reverse direction so that the first moving plate 100 descends, and at the same time, the second moving plate 200 rises to separate the first moving plate 100 and the second moving plate 200. ) move away from each other, the first magnet 110 and the second magnet 210 provided on the first moving plate 100 and the second moving plate 200 also move away from each other while facing each other. Since the attractive force no longer acts between the first magnet 110 and the second magnet 210, the magnetic field is released.

The repulsive force applicator 400 moves the first magnet 110 when the rotation axis 300 is rotated in the reverse direction in order to separate the first moving plate 100 and the second moving plate 200 that are close to each other. A repulsive force is applied between the first magnet 110 and the second magnet 210 to apply a repulsive force to the first moving plate 100 and the second moving plate 200, thereby creating an attractive force between the first magnet 110 and the second magnet 210. It acts as an offset.

The repulsive force applicator 400 is fixedly coupled to the first movable plate 100 or the second movable plate 200 and is provided between the first movable plate 100 and the second movable plate 200.

The first fixed plate 500 is provided outside the first movable plate 100. The first fixed plate 500 has a flat plate shape and is located below the first movable plate 100 and is horizontally seated on the floor.

The rotating shaft 300 is perpendicular to the first fixed plate 500 and passes vertically downward through the upper surface of the first fixed plate 500, and the lower end of the rotating shaft 300 is rotatable about the first fixed plate 500. are combined.

The second fixed plate 600 is provided outside the second movable plate 200. The second fixing plate 600 is arranged to be vertically spaced apart from the first fixing plate 500. The second fixed plate 600 has a flat plate shape and is located on top of the second moving plate 200.

The rotation shaft 300 is perpendicular to the second fixing plate 600 and passes vertically upward through the lower surface of the second fixing plate 600, and the upper end of the rotation shaft 300 is rotatable about the second fixing plate 600. are combined.

The fixing shaft 700 is fixedly coupled between the first fixing plate 500 and the second fixing plate 600 and supports the second fixing plate 600 vertically. The lower end of the fixing shaft 700 is coupled to the upper surface of the first fixing plate 500, and the upper end of the fixing shaft 700 is fixedly coupled to the lower surface of the second fixing plate 600.

The fixed shaft 700 vertically passes through the first moving plate 100 and the second moving plate 200, and the first moving plate 100 and the second moving plate 200 move on the fixed shaft 700. Possibly combined. To elaborate, the fixed shaft 700 guides the sliding up and down movements of the first and second movable plates 100 and 200 that move up and down.

The driving unit 800 is provided on the outer surface of the second fixing plate 600 and is coupled to the rotating shaft 300 to provide rotational power to the rotating shaft 300. The driving unit 800 is seated on the upper surface of the second fixing plate 600 and is fixedly coupled to the second fixing plate 600. The driving unit 800 may be configured to include a motor and a reducer. The rotational force of the motor is transmitted to the reducer, and the rotational power of the motor is provided to the rotation shaft 300 connected to the reducer.

Figure 3 is a cross-sectional view showing a first embodiment of a repulsive force application part in a magnetic field generating device according to an embodiment of the present invention.

Referring to FIG. 3, the repulsive force application unit 400 according to the first embodiment of the present invention will be comprised of a housing unit 410, an elastic member 420, a fixed block 430, and a moving block 440. You can.

The housing portion 410 is hollow and has openings formed at both ends. The housing portion 410 is installed vertically between the first movable plate 100 and the second movable plate 200, orthogonal to the first movable plate 100 and the second movable plate 200.

The elastic member 420 is accommodated inside the housing portion 410 and is installed in the longitudinal direction of the housing portion 410. At this time, the elastic member 420 may be a coil spring.

The fixing block 430 is fixedly coupled to one end of the opening of the housing portion 410 and supports one side of the elastic member 420. At this time, the other side of the elastic member 420 accommodated inside the housing portion 410 may be exposed to the outside through an opening at the other end of the housing portion 410.

The moving block 440 is partially inserted into the inside of the housing part 410 through the other end opening of the housing part 410 and elastically supports the other side of the elastic member 420. The moving block 440 is slidably moved in and out of the housing portion 410 through the other end opening of the housing portion 410 by the elasticity of the elastic member 420.

A coupling portion 441 may be provided on the outer surface of the moving block 440. To elaborate, a convex protrusion is formed to protrude from the lower surface of the moving block 440, so that the protrusion can be pressed into a coupling groove formed on the outer surface of the first moving plate 100 or the second moving plate 200. Accordingly, the moving block 440 may be coupled to the first moving plate 100 or the second moving plate 200.

As another embodiment, a concave coupling groove in which coupling members such as bolts and screws are spirally coupled may be formed on the lower surface of the moving block 440. Accordingly, the movable block 440 may be fixed to the first movable plate 100 or the second movable plate 200 by a coupling member.

The repulsive force applicator 400 according to the first embodiment of the present invention is provided on the fixed block 430 and the moving block 440 to limit the moving distance of the moving block 440 when the elastic member 420 is contracted. It may further include protrusions 431 and 442.

The limiting protrusion includes a first limiting protrusion 431 formed on the outer surface of the fixed block 430 and a second limiting protrusion 442 formed on the outer surface of the moving block 440. The first limiting protrusion 431 and the second limiting protrusion 442 protrude from the fixed block 430 and the moving block 440, respectively, and face each other on the inside of the housing portion 410. At this time, the protrusion length of the first limiting protrusion 431 and the protruding length of the second limiting protrusion 442 may be formed differently.

When the moving block 440 is moved to the inside of the housing part 410 and the elastic member 420 is contracted inside the housing part 410, the free end of the first limiting protrusion 431 and the second limiting protrusion 442 ) As the free ends of the blocks contact each other, the moving distance of the moving block 440 is limited.

Figure 4 is a cross-sectional view showing a second embodiment of the repulsive force application part in the magnetic field generating device according to an embodiment of the present invention.

Referring to FIG. 4, the repulsive force applicator 400 according to the second embodiment of the present invention includes a housing portion 450, an elastic member 460, a first moving block 470, and a second moving block 480. It can be configured to include.

The housing portion 450 is hollow and has openings at both ends. The housing portion 450 is installed vertically between the first movable plate 100 and the second movable plate 200 and perpendicular to the first movable plate 100 and the second movable plate 200.

The elastic member 460 is accommodated inside the housing portion 450 and is installed in the longitudinal direction of the housing portion 450. The elastic member 460 may be a coil spring. At this time, one side and the other side of the elastic member 460 accommodated inside the housing portion 450 may be exposed to the outside through one end opening and the other end opening of the housing portion 450, respectively.

The first moving block 470 is partially inserted into the inside of the housing part 450 through one end opening of the housing part 450 and elastically supports one side of the elastic member 460. The first moving block 470 is slidably moved in and out of the housing portion 450 through one end opening of the housing portion 450 by the elasticity of the elastic member 460.

The second moving block 480 is partially inserted into the inside of the housing part 450 through the other end opening of the housing part 450 and elastically supports the other side of the elastic member 460. The second moving block 480 is slidably moved in and out of the housing portion 450 through the other end opening of the housing portion 450 by the elasticity of the elastic member 460.

A coupling portion 481 may be provided on the outer surface of the second moving block 480. To elaborate, a convex protrusion is formed to protrude from the lower surface of the second moving block 480, so that the protrusion can be pressed into a coupling groove formed on the outer surface of the first moving plate 100 or the second moving plate 200. Accordingly, the second moving block 480 may be coupled to the first moving plate 100 or the second moving plate 200.

As another embodiment, a concave coupling groove in which coupling members such as bolts and screws are spirally coupled may be formed on the lower surface of the second moving block 480. Accordingly, the second moving block 480 may be fixed to the first moving plate 100 or the second moving plate 200 by a coupling member.

The repulsive force applicator 400 according to the second embodiment of the present invention is provided on the first moving block 470 and the second moving block 480, and when the elastic member 460 is contracted, the first moving block 470 and It may further include limiting protrusions 471 and 482 that limit the moving distance of the second moving block 480.

The limiting protrusion includes a first limiting protrusion 471 formed on the outer surface of the first movable block 470 and a second limiting protrusion 482 formed on the outer surface of the second movable block 480. The first limiting protrusion 471 and the second limiting protrusion 482 are formed to protrude from the first moving block 470 and the second moving block 480 and face each other on the inside of the housing portion 450. At this time, the protrusion length of the first limiting protrusion 471 and the protruding length of the second limiting protrusion 482 may be formed differently.

When the first moving block 470 and the second moving block 480 are moved inside the housing portion and the elastic member 460 is contracted inside the housing portion 450, the free end of the first limiting protrusion 471 and As the free ends of the second limiting protrusions 482 come into contact with each other, the moving distances of the first moving block 470 and the second moving block 480 are limited.

The operation process of the magnetic field generating device according to an embodiment of the present invention consisting of the above-described configuration will be described as follows.

Figure 5 is a cross-sectional view and an enlarged view showing an operating state in which an attractive force is applied between magnets in the magnetic field generating device according to an embodiment of the present invention, and Figure 6 is a cross-sectional view and an enlarged view showing an operating state in which a repulsive force is applied between magnets in the magnetic field generating device according to an embodiment of the present invention. This is a cross-sectional and enlarged view showing the operating state.

5 and 6, when the drive unit 800 is driven and the rotational power of the motor is transmitted to the rotation shaft 300 through the reducer, the rotation shaft 300 is rotated in one direction, and the first moving plate 100 ) and the second moving plate 200 are close to each other.

A magnetic field application unit 900 in which a magnetic field is generated is formed as an attractive force acts between the first magnet 110 and the second magnet 210 that face each other and are close to each other. As the copper foil material for secondary battery manufacturing passes through the magnetic field application unit 900, the material is arranged and aligned by the magnetic field.

At this time, as the first moving plate 100 and the second moving plate 200 approach, the elastic member of the repulsive force application unit 400 installed vertically between the first moving plate 100 and the second moving plate 200 ( 420 is contracted inside the housing portion 410 by sliding the movable block 440 to the inside of the housing portion 410 under the pressure of the first movable plate 100 and the second movable plate 200.

When the driving unit 800 is driven again so that the rotating shaft 300 rotates in the reverse direction and the rotational power of the motor is transmitted to the rotating shaft 300 through the reducer, the first movement is performed by the elastic restoring force of the contracted elastic member 420. While applying a repulsive force to the plate 100 and the second moving plate 200, the first magnet 110 and the second magnet 210 are connected using the repulsive force of the elastic member 420 between the first magnet 110 and the second magnet 210. The attractive force between the second magnets 210 is canceled out.

The magnetic field generator according to an embodiment of the present invention can cancel out the attractive force between the first magnet 110 and the second magnet 210 by using the elastic restoring force of the elastic member 420, so that the load of the motor and the reducer is reduced. The capacity of the motor and reducer can be reduced, and manufacturing and operating costs can be reduced by miniaturizing the equipment.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will recognize that various modifications and other equivalent embodiments are possible therefrom. You will understand. Therefore, the true technical protection scope of the present invention should be determined by the scope of the patent claims below.

100: first moving plate 110: first magnet
200: second moving plate 210: second magnet
300: rotation axis 310: first spiral portion
320: second spiral portion 400: repulsive force application portion
410, 450: Housing portion 420, 460: Elastic member
430: Fixed block 431, 442, 471, 482: Limiting protrusion
440: moving block 441, 481: coupling part
470: 1st moving block 480: 2nd moving block
500: first fixing plate 600: second fixing plate
700: Fixed shaft 800: Drive part
900: Magnetic field authorization unit

Claims (10)

a first moving plate provided with a first magnet;
a second moving plate facing the first moving plate and provided with a second magnet having a polarity opposite to that of the first magnet;
a rotation shaft helically coupled to the first moving plate and the second moving plate, and moving the first moving plate and the second moving plate in opposite directions according to a rotation direction; and
It is fixedly coupled to the first movable plate or the second movable plate, is provided between the first movable plate and the second movable plate, and applies a repulsive force to the first movable plate and the second movable plate. wealth;
A magnetic field generating device including a. According to paragraph 1,
The repulsive force applicator,
A hollow housing portion provided with openings at both ends;
an elastic member accommodated inside the housing portion;
a fixing block fixedly coupled to one end of the opening of the housing and supporting one side of the elastic member; and
A moving block that is partially inserted into the inside of the housing unit through the other end opening of the housing unit, elastically supports the other side of the elastic member, and is moved in and out of the housing unit by the elasticity of the elastic member;
A magnetic field generating device comprising: According to paragraph 2,
A magnetic field generating device, characterized in that a coupling portion coupled to the first moving plate or the second moving plate is provided on an outer surface of the moving block. According to paragraph 2,
Limiting protrusions formed on the outer surfaces of the fixed block and the moving block respectively to limit the moving distance of the moving block when the elastic member contracts;
A magnetic field generating device comprising: According to paragraph 1,
The repulsive force applicator,
A hollow housing portion provided with openings at both ends;
an elastic member accommodated inside the housing portion;
a first moving block that is partially inserted into the inside of the housing through an opening at one end of the housing, elastically supports one side of the elastic member, and is moved in and out of the housing by the elasticity of the elastic member; and
a second moving block that is partially inserted into the inside of the housing unit through an opening at the other end of the housing unit, elastically supports the other side of the elastic member, and is moved in and out of the housing unit by the elasticity of the elastic member;
A magnetic field generating device comprising: According to clause 5,
A magnetic field generating device, characterized in that a coupling portion coupled to the first moving plate or the second moving plate is provided on an outer surface of the second moving block. According to clause 5,
Limiting protrusions that protrude from outer surfaces of the first movable block and the second movable block respectively and limit the moving distances of the first movable block and the second movable block when the elastic member contracts;
A magnetic field generating device comprising: According to paragraph 1,
a first fixed plate provided outside the first moving plate and rotatably coupled to the rotating shaft;
a second fixed plate provided outside the second moving plate, spaced apart from the first fixed plate, and rotatably coupled to the rotation axis;
a fixed shaft fixed between the first fixed plate and the second fixed plate, and on which the first movable plate and the second movable plate are movably coupled; and
a driving unit provided on an outer surface of the second fixing plate and coupled to the rotation shaft to provide rotational power to the rotation shaft;
A magnetic field generating device comprising: According to clause 8,
The outer surface of the rotating shaft includes a first spiral portion with a thread formed up to one end with respect to the central portion of the rotating shaft, and a second spiral portion with a screw thread formed up to the other end in a direction opposite to the rotation direction of the first spiral portion. A magnetic field generating device characterized by: According to paragraph 1,
When the first moving plate and the second moving plate are close to each other, a magnetic field applying portion is formed between the first moving plate and the second moving plate where an attractive force between the first moving plate and the second moving plate acts. A magnetic field generating device characterized in that.

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