KR20230169806A - Double repulsive Device using Metal Magnet Interaction Phenomenon of the Magnet - Google Patents

Abstract

The present invention relates to a double repulsion device using the Metal Magnet Interaction (MMI) phenomenon of magnets, in which two opposing magnets are in a repulsive relationship with each other and a magnetic material is placed between them to increase the force required to pull the magnetic material. More specifically, in a device composed of a housing, a central axis, and a rotor, an external permanent magnet fixed to an external support, and an internal permanent magnet and an external permanent magnet fixed to an internal support are configured to face the external permanent magnet. The opposing magnet polarities of the internal permanent magnets are configured to have the same polarity, and the metal magnet interaction (MMI) phenomenon of the magnet is used to form a rotor made of magnetic material with a predetermined distance between the external and internal permanent magnets. It is about a double repulsion device.

Description

Double repulsive device using Metal Magnet Interaction (MMI) phenomenon of magnet {Double repulsive Device using Metal Magnet Interaction Phenomenon of the Magnet}

The present invention relates to a double repulsion device using the Metal Magnet Interaction (MMI) phenomenon of magnets, in which two opposing magnets are in a repulsive relationship with each other and a magnetic material is placed between them to increase the force required to pull the magnetic material. More specifically, in a device composed of a housing, a central axis, and a rotor, an external permanent magnet fixed to an external support, and an internal permanent magnet and an external permanent magnet fixed to an internal support are configured to face the external permanent magnet. The opposing magnet polarities of the internal permanent magnets are configured to have the same polarity, and the metal magnet interaction (MMI) phenomenon of the magnet is used to form a rotor made of magnetic material with a predetermined distance between the external and internal permanent magnets. It is about a double repulsion device.

In general, a device that converts mechanical energy into electrical energy is called a generator device, and a device that converts electrical energy into mechanical energy is called an electric motor (or motor) device. These devices are machines that obtain rotational or linear motion power and are usually connected between a coil that generates electromagnetic force and a magnetic material - a magnetic material refers to a metal such as iron or nickel that reacts with a magnet. - It uses the force of attraction (gravity) to cause rotational or linear movement. In this case, magnets - Here, magnets refer to magnets, electromagnets, and permanent magnets generated by current applied to the coil. - Magnetic materials usually use the force of magnet attraction and form a rotating magnetic field to rotate the magnetic material.

First, to explain the general properties of magnets, assume that one of the two magnets is fixed and the other magnet moves freely horizontally. If you experiment while ignoring resistance, the force used to separate the two magnets in an attractive relationship is It is the same as the force that pulls the magnet back together when a dropped magnet is released. In other words, two magnets in a repulsive relationship will try to push each other apart, and the force used to move the fallen magnets to a position where they overlap is the same as the force that causes the magnets in a repulsive relationship to fall apart. Figure 1 shows a schematic diagram of an existing magnetic induction motor. It shows a general schematic diagram of how the rotor rotates under the guidance of the stator.

Meanwhile, Figure 2 shows the principle of manufacturing an electric motor with higher efficiency than existing electric motors by using the phenomenon of Metal Magnet Interaction (hereinafter referred to as MMI), which was newly invented to achieve the present invention. As can be seen from Figure 2, the force to separate a magnetic material vertically from a certain distance L on one magnet from the magnet is calculated. After the magnetic material is separated from another magnet by L1, the force to separate it from the magnet is calculated. Find the value. Assume that the arithmetic average of these two values is k. When two magnets are placed in an attractive relationship, spaced L and L1 away from the magnets, respectively, and a magnetic body is placed in the middle, when the magnetic body is pulled horizontally in the direction away from the magnet, the force required is only about α. The value of α is always less than 2k. In the same situation, if the relationship between the two magnets is set to repulsion and the magnetic material in the middle is pulled, a force of about β (β ≒ 3 α to 4 α) is required. Place the same magnets at a distance of (L+L1)/2, set the two magnets in an attractive relationship, and the force when pulling one of the two magnets is always smaller than β. In other words, the force with which the magnetic bodies between the repulsive forces react is greater than the force with which magnets in an attractive relationship react with each other. This phenomenon is already a widely known fact that the resistance value of the current flowing between the attractive and repulsive forces of the magnet in the hard disk is different, and when this is interpreted mechanically, the experimental results as shown in FIG. 2 are obtained. The above phenomenon is referred to as Metal Magnet Interaction (MMI), hereinafter referred to as MMI.

A typical electric motor device (motor) flows current through a coil to generate a rotating magnetic field to move the rotor. At this time, most of the time, the electric motor device (motor) is rotated using the attractive relationship of magnets. Some electric motor devices use magnets instead of magnetic rotors to use both attractive and repulsive forces. However, electric motor devices that use such permanent magnets or coil magnets as rotors have good initial starting power, but as the rotational force increases, back electromotive force is generated, which sharply reduces the performance of the motor device. Accordingly, if a magnetic material is used for the rotor instead of using a magnet, back electromotive force is not generated and performance does not deteriorate sharply during high-speed driving. However, when a magnetic material is used as a rotor, a serious problem arises that is difficult to properly cope with when a high load is applied due to low initial maneuverability. Therefore, in order to solve this problem, the present invention attempted to manufacture a device that has a higher initial starting force than the existing method and is not affected by back electromotive force at high speeds by using the MMI phenomenon newly created in the present invention. Therefore, there is a great need to develop such high-efficiency devices.

Public Patent Publication No. 10-2006-0081179 (July 12, 2006)

Public Patent Publication No. 10-2015-0093556 (2015.08.18)

Registered Patent Publication No. 10-2310927 (2021.10.01.)

The present invention was developed to solve the above-mentioned needs and problems. Two opposing magnets are in a repulsive relationship with each other, and a magnetic material is placed between them, so that not only the force due to the repulsive force of the two magnets but also the internal magnetic material is used. The purpose is to enable the construction of a highly efficient device by generating increased magnetomotive force.

In addition, the purpose is to propose a device for generating even more increased force by repeatedly installing the internal magnetic field coil support and the internal magnetic material support.

In addition, the purpose is to improve the efficiency of electric motors or generator devices by using the double repulsion force of magnets and to enable compact and lightweight design.

According to the present invention for achieving the above-mentioned object,

In the dual repulsion device of the radial flux type using the Metal Magnet Interaction (MMI) phenomenon of a magnet, the dual repulsion device consists of a rotation axis for rotation and a fixed axis that is connected to the rotation axis but does not rotate. A central axis; and a housing connected to the central axis to form the external shape of the device; and an external magnetic supporter accommodated inside the housing at a predetermined interval and including an external magnetic material; and spaced apart from the external magnetic supporter at a predetermined interval an external magnetic field coil supporter configured to include an external magnetic field coil configured at a position corresponding to the external magnetic material; and a magnetic rotor configured to include a rotating magnetic material and rotating at a predetermined distance from the external magnetic field coil supporter; An internal magnetic field coil support configured to be spaced apart from the magnetic rotor at a predetermined distance and including an internal magnetic field coil configured at a position corresponding to the external magnetic field coil configured on the external magnetic field coil support; and spaced apart from the internal magnetic field coil support at a predetermined interval. It is configured to include an internal magnetic material supporter configured to include an internal magnetic material configured at a position corresponding to the internal magnetic field coil; One side of the housing, the external magnetic support, the external magnetic field coil support, the magnetic rotor, the internal magnetic field coil support, and the internal magnetic support is connected to and fixed to the rotation shaft; The other side of the housing, the external magnetic support, the external magnetic field coil support, the magnetic rotor, the internal magnetic field coil support, and the internal magnetic support are connected to and fixed to the fixed shaft.

In addition, in the dual repulsion device in the form of an axial flux type using the Metal Magnet Interaction (MMI) phenomenon of a magnet, the dual repulsion device is a central axis for rotation; and a rotation shaft connection bearing to the central axis. A housing that is fixed; and an external magnetic material supporter accommodated inside the housing at a predetermined distance apart and including an external magnetic material; and an external magnetic field coil spaced apart from the external magnetic material supporter at a predetermined interval and configured at a position corresponding to the external magnetic material. an external magnetic field coil supporter configured to include; and a magnetic rotor configured to include a rotating magnetic body and rotating, spaced apart from the external magnetic field coil supporter at a predetermined distance; and a magnetic rotor spaced apart from the magnetic rotor at a predetermined interval and rotating. an internal magnetic field coil supporter comprising an internal magnetic field coil configured at a position corresponding to the external magnetic field coil configured; and an internal magnetic body configured at a position corresponding to the internal magnetic field coil and spaced apart from the internal magnetic field coil support at a predetermined distance. It is configured to include an internal magnetic material support composed of a; The external magnetic support, the magnetic rotor, and the internal magnetic support are fixed to the housing through a connection bearing.

In addition, in the linear type dual repulsion device using the Metal Magnet Interaction (MMI) phenomenon of magnets, the dual repulsion device includes a linear guide and a fixed axis for linear movement; and a fixed axis fixed to the fixed axis. a housing; and an external magnetic material supporter accommodated inside the housing at a predetermined distance apart and including an external magnetic material; and an external magnetic material supporter configured at a position corresponding to the magnetic material and spaced apart from the external magnetic material supporter at a predetermined interval and including an external magnetic field coil. an external magnetic field coil supporter configured; and a magnetic rotor configured to rotate and including a rotating magnetic body spaced apart from the external magnetic field coil supporter at a predetermined distance; and a magnetic rotor configured to the external magnetic field coil supporter spaced a predetermined distance apart from the magnetic rotor. An internal magnetic field coil supporter configured at a position corresponding to the external magnetic field coil and including an internal magnetic field coil; and an internal magnetic body spaced apart from the internal magnetic field coil supporter at a predetermined distance and configured at a position corresponding to the internal magnetic field coil. It is configured to include an internal magnetic support body; The internal magnetic field coil support and the external magnetic field coil support are fixed to the housing (2), and the internal magnetic support, the external magnetic support and the magnetic rotor are installed on the linear guide on the fixed axis. .

In addition, the dual repulsion device is characterized by being either a generator or an electric motor.

Additionally, the magnetic material is characterized by being composed of either a magnet or a coil.

In addition, the magnetic material is characterized in that it is a metal that reacts with a magnet, such as iron, nickel and cobalt.

In addition, the dual repulsion device is characterized by being configured by repeatedly installing the internal magnetic field coil support and the internal magnetic body support.

In addition, the external magnetic support, the magnetic rotor, and the internal magnetic support are fixed to the rotation shaft by a magnetic support fixing device.

In addition, the dual repulsion device is characterized by including a Hall sensor for detecting the position of the rotating magnetic body.

In addition, it is characterized by further comprising a brake device for stopping the rotation of the dual repulsion device inside or outside the dual repulsion device.

In addition, it is characterized by being configured to add gears of different numbers to the inside of the dual repulsion device.

As described above, according to the double repulsion device using the Metal Magnet Interaction (MMI) phenomenon of magnets according to the present invention, a large double repulsion force is generated by equalizing the magnetic pole polarity of the stators facing each other, and a magnetic material is placed between the stators. By inserting it, the repulsive force is further increased, which has the advantage of forming a highly efficient device that generates a large rotational force.

In addition, when the device using the double repulsion force of the present invention is used in a generator or electric motor, there is an advantage that the volume is significantly reduced at the same output capacity compared to a conventional generator or electric motor device.

In addition, by using the double repulsion force of the present invention, a generator or electric motor device has the advantage of reducing the manufacturing cost of manufacturing the device and increasing profits.

In addition, according to the present invention, high torque can be generated during initial startup and the phenomenon of back electromotive force due to high-speed operation is significantly reduced.

1 is a schematic diagram of a conventional magnetic induction motor device.
Figure 2 shows the MMI (Metal Magnet Interaction) phenomenon newly invented to achieve the present invention.
3 is a conceptual diagram of one embodiment of the present invention.
Figure 4 is a schematic diagram of the basic parts of the axial flux type of the dual repulsion device of another embodiment of the present invention.
Figure 5 is a flow chart of the basic component arrangement of the axial flux type of the dual repulsion device of another embodiment of the present invention.
Figure 6 shows the operating principle of the axial flux type of the dual repulsion device of another embodiment of the present invention.
Figure 7 is a conceptual diagram of an axial flux type of a dual repulsion device of another embodiment of the present invention.
Figure 8 is an axial flux type multilayer conceptual diagram of a dual repulsion device of another embodiment of the present invention.
Figure 9 is a simple axial flux type (Axial Flux Type) component diagram of a dual repulsion device of another embodiment of the present invention.
Figure 10 is a simple conceptual diagram of the axial flux type of a dual repulsion device of another embodiment of the present invention.
Figure 11 is a front view of the radial flux type of the dual repulsion device of an embodiment of the present invention.
Figure 12 is a radial flux type side view of the dual repulsion device of an embodiment of the present invention.
Figure 13 is a simple radial flux type device of a dual repulsion device according to an embodiment of the present invention.
Figure 14 is a detailed view of a linear type dual repulsion device according to another embodiment of the present invention.
Figure 15 shows the operating principle of a linear type double repulsion device according to another embodiment of the present invention.
Figure 16 is a simple view of a linear type dual repulsion device according to another embodiment of the present invention.
Figure 17 is a component diagram of the dual repulsion generator device using the MMI phenomenon of the present invention.
Figure 18 shows the power generation principle of the dual repulsion generator device using the MMI phenomenon of the present invention.
Figure 19 is a conceptual diagram of a dual repulsion generator device using the MMI phenomenon of the present invention.
Figure 20 is a conceptual diagram of a dual repulsion linear (Linear Type) generator using the MMI phenomenon of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to make the gist of the present invention clear.

The basic configuration of the double repulsion device created in the present invention is based on a five-layer structure, and the basic configuration is explained as follows. First, the external magnetic material support (3) can be composed of a magnetic material holder containing an external magnetic material (313) and a magnetic material, magnet, or coil inside, and can be removed when necessary.

Additionally, the external magnetic field coil support 4 has an external magnetic field coil 314 that generates magnetic force when power is applied, and the power can be turned on or off.

In addition, the magnetic rotor 5 is a magnetic material holder including a rotor magnetic material 315, and may be partially or entirely composed of a magnetic material.

In addition, the internal magnetic field coil support 6 has an internal magnetic field coil 316 that generates magnetic force when power is applied, and the power can be turned on or off.

In addition, the internal magnetic material support 7 may be composed of a magnetic material holder including an internal magnetic material 317 and a magnetic material, magnet, or coil therein, and may be removed when necessary.

Here, the external magnetic field coil support (4) and the internal magnetic field coil support (6) are combined and referred to as one coil pair. In addition, the external magnetic support (3), the magnetic rotor (5), and the internal magnetic support (7) are combined to form one magnetic pair.

Pairs of magnetic materials are connected and fixed to each other to rotate or move in a straight line as a single component. Coil pairs are also tied together and fixed to a fixed central axis that does not rotate, allowing them to rotate or be fixed as a single component. There is no difference whether either of these two rotates, but when the coil pair rotates, a device is needed to supply current to the coil pair. The place that needs fixing is fixed to the place connected to the housing (body or rotation axis), and the place that needs to be rotated is fixed to the place connected to the housing (body or rotation axis). Bearings are used to allow rotation. For convenience of explanation, the following description assumes that the coil pair is fixed and the magnetic material pair performs linear or rotational movement.

Figure 3 shows a conceptual diagram of an embodiment of the present invention, showing a device (1) using double repulsion force of an embodiment of the present invention, which is configured in a radial form in the form of a generator or electric motor, and is composed of five layers. In the dual repulsion device of the radial flux type using the Metal Magnet Interaction (MMI) phenomenon of magnets, the dual repulsion device includes a rotation axis (8) for rotation and a fixed axis that is connected to the rotation axis but does not rotate. A central axis (10) consisting of (9), a housing (2) connected to the central axis (10) to form the external shape of the device, and an external magnetic body (313) stored at a predetermined distance inside the housing (2). ) and an external magnetic field coil support (314) configured to be spaced apart from the external magnetic material support (3) at a predetermined distance and configured at a position corresponding to the magnetic material ( 4) and a magnetic rotor 5 that rotates at a predetermined distance from the external magnetic field coil support 4 and includes a rotating magnetic body 315, and is spaced a predetermined distance from the magnetic rotor 5 and rotates the external magnetic field coil. An internal magnetic field coil support 6 including an internal magnetic field coil 316 configured at a position corresponding to the external magnetic field coil 314 configured on the support 4 and a predetermined distance between the internal magnetic field coil support 6 and the internal magnetic field coil support 6. It is configured to include an internal magnetic body support 7 that includes an internal magnetic body 317 that is spaced apart and configured at a position corresponding to the internal magnetic field coil 316, and includes the housing 2 and the external magnetic body support 3. , one side of the external magnetic field coil support (4), the magnetic rotor (5), the internal magnetic field coil support (6), and the internal magnetic support (7) are connected to and fixed to the rotation shaft (8) and the housing ( 2), the other side of the external magnetic support (3), the external magnetic field coil support (4), the magnetic rotor (5), the internal magnetic field coil support (6), and the internal magnetic support (7) are connected to the fixed shaft It consists of a structure that is connected to and fixed to (9).

The device (1) using the double repulsion force is called a coil pair by combining the two supports of the external magnetic field coil support (4) and the internal magnetic field coil support (6), and the external magnetic support (3) and magnetic rotor for supporting the magnetic material. (5) and internal magnetic body support (7) The three supports are grouped together and called a magnetic body pair. Among the external magnetic support (3), external magnetic field coil support (4), magnetic rotor (5), internal magnetic field coil support (6), and internal magnetic support (7), the internal magnetic support (7) is connected to the rotation shaft (8). The rest connects one side to the rotating axis and the fixed axis, and can be rotated or fixed as needed.

The direction of the current is set so that the polarity of the facing surface of the external magnetic field coil 314 and the internal magnetic field coil 316 is the same, and the magnetic rotor 5 is positioned between the magnetic field coils 210. It consists of a structure.

Figure 4 shows a schematic diagram of the basic parts of the axial flux type (Axial Flux Type) dual repulsion device of another embodiment of the present invention. First, looking at the basic structure that constitutes the electric motor device, the axial flux type (Axial Flux Type) electric motor device If we separate the most basic structures one by one and explain their structure, we can divide them into two disks. One has a structure consisting of a disk-shaped magnetic support 250 and a magnetic material 260 inside the magnetic support. The magnetic material can be made by removing a portion of the metal that responds to magnets from a circular plate, or it can be made and fixed to a circular plate that does not respond to magnets by creating a trapezoid-shaped magnetic material. Meanwhile, the other one is in the form of a disk and consists of one or more coils inside, and this coil has a shape that penetrates the disk. This disk shape is called the magnetic field coil support 200, and the coil inside it is the magnetic field coil 210. and turns the power of the magnetic field coil on or off.

Figure 5 shows a flowchart of the basic parts arrangement of the axial flux type of the dual repulsion device of another embodiment of the present invention. In the axial flux type motor, the radial flux type motor is also used. It consists of five floors as shown. First, an external magnetic support (3), an external magnetic field coil support (4) spaced apart from the external magnetic support (3) at a predetermined distance, a magnetic rotor (5) configured to be spaced a predetermined distance from the external magnetic field coil support, and the above. It is composed of an internal magnetic field coil support (6) that is spaced apart from a magnetic rotor at a predetermined distance, an internal magnetic material support (7) that is configured at a predetermined distance apart, and a rotation shaft (8) that combines all of them, and its function and configuration are also axial magnetic flux. It is the same as the type electric motor, and each of them is as follows.

First, the external magnetic material support 3 can be composed of a magnetic material holder containing an external magnetic material 313 and a magnetic material, magnet, or coil inside, and can be removed when necessary.

In addition, the external magnetic field coil support 4 has an external magnetic field coil 314 that generates magnetic force when power is applied, and the power can be turned on and off.

Additionally, the magnetic rotor 5 may be composed of a magnetic material holder or a magnetic material including the rotating magnetic material 315.

In addition, the internal magnetic field coil support 6 has an internal magnetic field coil 316 that generates magnetic force when power is applied, and the power can be turned on and off.

In addition, the internal magnetic material support 7 may be composed of a magnetic material holder including an internal magnetic material 317, and a magnetic material, magnet, or coil therein, and may be removed when necessary.

Here, the external magnetic field coil support (4) and the internal magnetic field coil support (6) are combined and called a coil pair. In addition, the external magnetic support (3), the magnetic rotor (5), and the internal magnetic support (7) are collectively called a magnetic pair.

Pairs of magnetic materials can be connected and fixed to each other to rotate or be fixed in the form of a single component. The coil pair is also bundled and fixed to the central axis (10) so that it can be rotated or fixed as a single component. There is no difference whether either of these two rotates, but if the coil pair rotates, a device will be needed to supply current to the coil pair. Places that require fixation are fixed to places connected to the body, and areas that require rotation are allowed to rotate using bearings.

Figure 6 shows the operating principle of an axial flux type electric motor among the dual repulsion electric motor devices, and is explained assuming that magnetic materials rotate. Current flows through the coil pairs corresponding to the external magnetic field coil support (4) and the internal magnetic field coil support (6). The current forms a rotating magnetic field using the drive or controller of an existing electric motor device, allowing the magnetic material to rotate. Adjust the direction of the current so that the polarities of the coils facing each other have the same polarity. Accordingly, the magnetic rotor (5) reacts in a repulsive relationship between the magnetic field coils, and the magnetic materials of the external magnetic support (3) and the internal magnetic support (7) react in an attractive relationship with the magnetic field coil. In this way, all of the magnetic force generated from the coil pair can be used without loss, increasing the device's efficiency and increasing its output.

Meanwhile, magnetic materials are made of pure iron or use metals that have the property of losing magnetism quickly. Depending on the induction mechanism of the motor device or the number of coils, one or more magnetic materials may be formed inside the magnetic material support.

That is, moving from Stage 1 to Stage 2 in FIG. 6, pairs of magnetic materials rotate toward adjacent magnetic field coils to which current is applied. When the magnetic pair stops, the power of the magnetic field coil pair overlapping with the magnetic material pair is turned off, and current is applied to the immediately adjacent magnetic field coil, resulting in Stage 3. In this state, the pair of magnetic materials rotates to the adjacent magnetic field coil again by inertia, which is Stage 4. If the sequence from Stage 1 to Stage 4 is repeated, an electric motor device capable of continuous rotation is formed. It will happen.

Figure 7 shows a conceptual diagram of an axial flux type of a dual repulsion device of another embodiment of the present invention. The configuration of Figure 6 is located inside the housing (2), and the rotation axis (8) is fixed to the housing (2). It shows an electric motor device using the double repulsion force of the present invention combined with a bearing 50 to allow rotational movement. Either the magnetic field coil pair or the magnetic material pair must be allowed to rotate. The following explanation will be made assuming that the magnetic pair is rotating. The rotating part is combined with the rotating shaft (8) and the magnetic support fixture (40) to rotate, and the part that requires rotation is combined with the housing (2) and the connecting bearing (30) to enable rotational movement. Additionally, the connecting bearing 30 suppresses eccentricity that occurs during rotation. The part that needs to be fixed is connected to the rotating shaft (8) and the magnetic field coil support bearing (41) and fixed with the housing (2) and the coupling screw (31) to prevent it from rotating.

The housing (2) serves to surround the entire electric motor device using the double repulsion force of the present invention and also plays the role of fixing the magnetic field coil pair, thereby fixing the electric motor device to the floor or the part to be fixed.

Figure 8 shows a multi-layer conceptual diagram of the axial flux type among the dual repulsion electric motor devices, and is a multi-layer form that increases the output of the electric motor device by composing the internal magnetic field coil support (6) and the internal magnetic body support (7) in several layers. It shows the structure of . As can be seen from Figure 8, it can be confirmed that the dual repulsion device according to the present invention can be conveniently used by using a multi-layer structure to increase the output.

Figure 9 shows a simple part diagram of an axial flux type dual repulsion motor device, and Figure 10 shows a simple conceptual diagram of an axial flux type (Axial Flux Type) of a dual repulsion device (1) of another embodiment of the present invention. .

As can be seen through Figures 9 and 10, there is a magnetic rotor (5) in the center in three concentric circles at different distances around the central axis (10), and an internal magnetic field coil support (6) and an external magnetic field on both outer sides. Position the coil support (4). A magnetic rotor (5) is placed between the coil pairs, and the magnetic rotor (5) is configured to receive a repulsive force from the coil pair. This shows the same structure and function as in Figure 5.

However, it is configured to remove the external magnetic support (3) and internal magnetic support (7) that exist in FIG. 5. In this way, the electric motor device can be made small and lightweight, and can also be used when a simple structure of the electric motor device is needed.

Figures 11 and 12 show the main components of Figure 3 combined inside the housing (2). This is an example of making and implementing a radial flux type electric motor device. 11 and 12, the fixed shaft 9 is connected to the housing 2 and fixed so that it cannot rotate. The rotating shaft (8) is connected to the housing (2) and the rotating shaft connecting bearing (50) to allow rotation. Housing (2) and the external magnetic material support (3) stored inside the housing (2), the external magnetic field coil support (4) formed at a predetermined distance from the external magnetic material support (3), and the external magnetic material support (4) at a predetermined distance. A magnetic rotor (5) spaced apart from each other, an internal magnetic field coil support (6) spaced apart from the magnetic rotor (5) at a predetermined distance, an internal magnetic support (7) spaced apart from the magnetic rotor (5) at a predetermined distance, and a combination thereof. It consists of a rotating shaft (8) and a fixed shaft (9) that is coupled to the housing (2) and is rotatable and connected to the rotating shaft (8), but does not rotate like the rotating shaft (8) and is fixed in combination with the housing (2).

The device (1) using the double repulsion force of the present invention is called a coil pair by combining the external magnetic field coil support (4) and the internal magnetic field coil support (6), and includes the external magnetic support (3), the magnetic rotor (5), and the internal magnetic field coil support (6). The three supports of the magnetic body support (7) are grouped together and called a magnetic body pair. In addition, among the external magnetic support (3), external magnetic field coil support (4), magnetic rotor (5), internal magnetic field coil support (6), and internal magnetic support (7), the internal magnetic support (7) is connected to the rotation axis (8). and the rest are connected to the rotating axis (8) and the fixed axis (9), and can be rotated or fixed as needed. The direction of the current is set so that the polarities of the facing surfaces of the external magnetic field coil 314 and the internal magnetic field coil 316 have the same polarity. The magnetic rotor (5) is comprised of being placed between the magnetic field coils.

In addition, the external magnetic support (3) and the internal magnetic support (7) are composed of a magnetic material, and are constructed by removing the external magnetic support (3) and the internal magnetic support (7), and the external magnetic field coil support (4) and the internal magnetic field coil support (6) is directly connected to the fixed shaft (9), and the fixed shaft (9) is connected and fixed to the housing (2), and is connected between the magnetic field coil support (200), that is, the external magnetic field coil support (4) and The magnetic rotor (5) is placed between the internal magnetic field coil supports (6), and the magnetic rotor (5) is connected to the fixed shaft (9) and connected to the bearing (11) to allow rotational movement. . In other words, of the two supports that respectively support the magnetic pair and the coil pair, one is connected to the rotating axis and one is connected to the fixed axis (9), allowing the magnetic pair to rotate, but not allowing the coil pair to rotate.

FIG. 13 is a simplified version of the radial flux type motor device described in FIGS. 11 and 12 and is configured to be suitable for making a small motor device or a high-output motor device. The fixed shaft (9) is connected to the housing (2) to prevent it from rotating, and the rotating shaft (8) is connected to the housing (2) and the bearing (11) to allow rotation. As previously explained in FIG. 3, the external magnetic support (3) and the internal magnetic support (7) were removed and the electric motor device was manufactured. The direction of the current is adjusted so that the opposing coils in the coil pair have a repulsive relationship, and in between, one magnetic rotor (5) is connected to the rotating axis (8) and the fixed axis (9), respectively, and the external magnetic field coil support (4) is connected. Connect to the housing (2) and connect the internal magnetic field coil support (6) to the fixed shaft (9). The coil pair is connected and fixed to each other so that it does not move, and the rotating shaft (8) connected to the magnetic rotor (5) rotates.

Looking at Figures 14 and 15, the device using the double repulsion force of the present invention can also be used in a linear type electric motor device. The structure and mechanism are also the same as the previously described circular electric motor device. However, the only difference is that the magnetic pair moves linearly rather than rotationally, but everything else is the same.

Figure 16 is shown in Figures 14 and 15, showing a simplified structure of the linear type electric motor using the MMI phenomenon of the magnet created in the present invention.

In addition, Figures 17 and 18 show that the double repulsion device (1) using the MMI phenomenon of the present invention can be manufactured not only as an electric motor but also as a generator device. First of all, a generator is a device that increases or decreases the magnetic field by moving the coil in the magnetic field of a coil or permanent magnet to which power is applied, thereby causing an electromotive force induction phenomenon in the coil and obtaining the power generated at this time.

The structure of the generator using the MMI phenomenon of the present invention is the same as the previously described electric motor device using the MMI phenomenon. The electric motor device of the present invention is composed of five layers as described in FIG. 5. However, in the internal magnetic material support (7) and external magnetic material support (3) that constitute the electric motor, the external magnetic material (313) is replaced with a coil and its name is external induction coil (410). The external induction coil (410) The disk shape included is called the external induction coil support (400), and the internal magnetic material (317) is replaced with a coil in the internal magnetic material support (7) and its name is called the internal induction coil (460). The disk shape including the internal induction coil (460) is called the external induction coil support (450).

If the shape, size, and number of induction coils are configured so that the quantity, size, and position of the magnetic materials present in the magnetic rotor 5 are the same, the configuration shown in FIG. 18 becomes the same. At this time, current is applied to the external magnetic field coil support (4) and the internal magnetic field coil support (6) in the same manner as when driving the motor device. In other words, when the direction of the current is adjusted so that the polarity of the opposing coils is the same and the current is applied to the magnetic field coil using a controller that drives the motor device, the magnetic rotor (5) has rotating power.

When the internal induction coil support (400), external induction coil support (450) and magnetic rotor (5) are fixed to each other and moved together, the internal induction coil support (400), external induction coil support (450) and magnetic rotor (5) are fixed to each other and moved together. ) moves in the same direction.

In the internal induction coil support 450 and the external induction coil support 400, an electromotive force induction phenomenon occurs due to the electromotive force of the internal induction coil support 450 and the external induction coil support 400, and strongly resists rotational movement. To overcome this problem, if power is supplied from the outside to force rotation, the magnetic rotor 5 rotates in the same direction, thereby reducing the load on the external power source.

Like a conventional generator device, the power of the external power can be reduced by the power of the rotational movement occurring in the magnetic rotor (5) from the power of the strong external power for power generation. As explained earlier, by using the MMI phenomenon of the present invention, the polarity of the opposing coils is equalized, and the force of the magnetic material between them is stronger than the force we previously knew, so the force of external power can be greatly reduced. A generator device using this MMI phenomenon cannot rotate on its own unless it has infinite power. However, we would like to clarify that the meaning of the present invention is to reduce the load on the external power source 600 by efficiently using the magnetic force generated from the magnetic field coil without waste.

In Figure 19, all the components in Figure 17 are installed in a housing and connected to an external power source (600). At this time, the frequency of the power applied to the external power source 600 and the magnetic field coil of the generator device must be set in conjunction with the rotation of the external power source to match the rotation speed of the power source and the rotation frequency of the magnetic field coil of the generator device. In this way, when an external power source is applied to the magnetic field coil to perform rotational movement, it rotates without disharmony, and the force generated when the magnetic rotor (5) rotates is generated from the internal induction coil support (450) and the external induction coil support (400). It will be possible to significantly reduce the resistance to the electromotive force induction phenomenon.

Figure 20 is a generator device applying the linear type electric motor device mentioned in Figure 14. In the linear type motor device of FIG. 14, the external magnetic support (3) and the internal magnetic support (7) are replaced with the external induction coil support (400) and the internal induction coil support (450). A support reinforcement (720) that connects and fixes the external induction coil support (400), the internal induction coil support (450), and the magnetic rotor (5) is installed and configured to move together when moving. This support reinforcement bar (720) is connected and fixed to the disk-type motion conversion device (700) using a long bar, that is, a linear motion conversion bar (710). The central axis of movement of the external power source (600) is connected to the center of the disc-shaped motion converter (700) at 90 degrees so that when the external power source rotates, the disc-shaped motion converter (700) also rotates. When the external power source rotates, the straight conversion rod (710) fixed to the disk-type motion conversion device (700) is replaced by the internal induction coil support (450) in the linear type generator device. The support reinforcement (720) connecting the external induction coil support (400) and the magnetic rotor (5) is made to move in a straight line.

At this time, the power applied to the magnetic field coil is adjusted in synchronization in conjunction with the rotational movement of the external power source. When the magnetic rotor uses the repulsive force relationship between the opposing magnetic field coils to generate the MMI phenomenon, the magnetic material rotates due to the MMI phenomenon. The ruler makes a straight reciprocating motion with strong force. This force creates a force that opposes the electromotive force induction phenomenon occurring in the internal magnetic field coil support 450 and the external magnetic field coil support 400, ultimately reducing the load on the external power source.

The embodiments described in this patent can be modified and used in various forms. For example, the double repulsion device (1) can utilize the MMI phenomenon of the magnet of the present invention in various types of electric motors or generators, and the device of the present invention is constructed integrally with the wheels of a device for moving means or It is possible to mix and configure it in different forms.

1: Device 2: Housing
3: External magnetic body support, 4: External magnetic field coil support
5: Magnetic rotor, 6: Internal magnetic field coil support,
7: Internal magnetic support, 8: Rotation axis
9: fixed axis 10: central axis
11: Bearing 30: Connection bearing
31: Connection screw 40: Magnetic support fixture
41: Magnetic field coil support fixed bearing 43: External coil support bearing
46: Internal coil support bearing 50: Rotation shaft connection bearing
60: Base 200 magnetic field coil support
210: magnetic field coil 250: magnetic support
260: magnetic material, 313: external magnetic material
314: External magnetic field coil 315: Rotating magnetic body
316: Internal magnetic field coil, 317: Internal magnetic material
400: External induction coil support 410: External induction coil,
450: Internal induction coil support 460: Internal induction coil
600: External power source 700: Disk-type motion conversion device
710: Linear motion conversion bar 720: Support reinforcement bar

Claims (11)

In the dual repulsion device of the radial flux type using the Metal Magnet Interaction (MMI) phenomenon of magnets,
The dual repulsion device is a central axis consisting of a rotation axis for rotation and a fixed axis that is connected to the rotation axis but does not rotate; and
A housing connected to the central axis and constituting the external appearance of the device; and
An external magnetic material support is stored inside the housing at a predetermined interval and includes an external magnetic material; and
An external magnetic field coil support configured to include an external magnetic field coil configured at a position corresponding to the external magnetic material and spaced apart from the external magnetic material support at a predetermined interval; and
A magnetic rotor configured to include a rotating magnetic body 315 and rotating at a predetermined distance from the external magnetic field coil support;
An internal magnetic field coil support configured to be spaced apart from the magnetic rotor at a predetermined distance and including an internal magnetic field coil configured at a position corresponding to the external magnetic field coil configured on the external magnetic field coil support; and
It is configured to include an internal magnetic material supporter that is spaced a predetermined distance from the internal magnetic field coil supporter and includes an internal magnetic material configured at a position corresponding to the internal magnetic field coil;
One side of the housing, the external magnetic support, the external magnetic field coil support, the magnetic rotor, the internal magnetic field coil support, and the internal magnetic support is connected to and fixed to the rotation shaft;
The other side of the housing, the external magnetic support, the external magnetic field coil support, the magnetic rotor, the internal magnetic field coil support, and the internal magnetic support is connected to and fixed to the fixed shaft.
In the dual repulsion device of the axial flux type using the Metal Magnet Interaction (MMI) phenomenon of magnets,
The dual repulsion device is a central axis for rotation; and
A housing fixed to the central axis through a rotating shaft connection bearing; and
An external magnetic material support is stored inside the housing at a predetermined interval and includes an external magnetic material; and
An external magnetic field coil support configured to include an external magnetic field coil configured at a position corresponding to the external magnetic material and spaced apart from the external magnetic material support at a predetermined interval; and
A magnetic rotor configured to include a rotating magnetic body and rotating at a predetermined distance from the external magnetic field coil support;
An internal magnetic field coil support configured to be spaced apart from the magnetic rotor at a predetermined distance and including an internal magnetic field coil configured at a position corresponding to the external magnetic field coil configured on the external magnetic field coil support; and
It is configured to include an internal magnetic material supporter that is spaced a predetermined distance from the internal magnetic field coil supporter and includes an internal magnetic material configured at a position corresponding to the internal magnetic field coil;
The external magnetic support, the magnetic rotor, and the internal magnetic support are fixed to the housing through a connection bearing.
In the linear type double repulsion device using the Metal Magnet Interaction (MMI) phenomenon of magnets,
The dual repulsion device includes a linear guide and a fixed axis for linear movement; and
a housing fixed to the fixed shaft; and
An external magnetic material support is stored inside the housing at a predetermined interval and includes an external magnetic material; and
An external magnetic field coil support is spaced apart from the external magnetic material support at a predetermined distance and is configured at a position corresponding to the magnetic material and includes an external magnetic field coil; and
A magnetic rotor configured to include a rotating magnetic body and rotating at a predetermined distance from the external magnetic field coil support;
an internal magnetic field coil support that is spaced apart from the magnetic rotor at a predetermined distance and is configured at a position corresponding to the external magnetic field coil configured in the external magnetic field coil support and includes an internal magnetic field coil; and
It is configured to include an internal magnetic material supporter that is spaced a predetermined distance from the internal magnetic field coil supporter and includes an internal magnetic material configured at a position corresponding to the internal magnetic field coil;
The internal magnetic field coil support and the external magnetic field coil support are fixed to the housing (2), and the internal magnetic support, the external magnetic support and the magnetic rotor are installed on the linear guide on the fixed axis. Double repulsion device.
According to any one of claims 1 to 3,
The double repulsion device is either a generator or an electric motor.
According to any one of claims 1 to 3,
A dual repulsion device, characterized in that the magnetic material is composed of either a magnet or a coil.
According to clause 4,
A dual repulsion device, characterized in that the magnetic material is a metal that reacts with a magnet, such as iron, nickel and cobalt.
According to paragraph 2,
The dual repulsion device is configured by repeatedly installing the internal magnetic field coil support and the internal magnetic material support.
According to paragraph 2,
The external magnetic support, the magnetic rotor, and the internal magnetic support are fixed to the rotation axis by a magnetic support fixing device.
According to any one of claims 1 to 3,
A dual repulsion device comprising a Hall sensor for detecting the position of the rotor magnetic body inside the dual repulsion device.
According to clause 9,
Dual repulsion device further comprising a brake device inside or outside the dual repulsion device for stopping the rotation of the dual repulsion device.
According to clause 9,
A dual repulsion device characterized in that it is configured to add gears of different numbers to the inside of the dual repulsion device.