KR20220142161A - Generator - Google Patents

Abstract

The present invention relates to a resistanceless generator, which comprises a rotating shaft (100) which has a predetermined length and which is installed in a state that a rotor (300) is mounted to a middle part of the rotating shaft to be rotated by an external force. A lower end of the rotating shaft (100) is installed in a state of being lifted by a magnetic force while a shaft support means for supporting the rotating shaft (100) in a state that it does not come into contact with the rotating shaft (100) by a magnetic force at one or more points along a length direction of the rotating shaft (100) is formed, so that the resistanceless generator does not generate frictional resistance during a process of rotating the rotating shaft (100).

Description

Resistanceless Generator {Generator}

The present invention relates to a generator, and more particularly, to a non-resistance generator in which the shaft is formed to be able to rotate in a non-resistance state.

As is well known, in general, a generator is a device that receives mechanical energy from an external power source and converts it into electrical energy, and generates a current by rotating a rotor installed with a magnet at a high speed inside a stator in which a coil is wound. At this time, the rotor rotates while being installed on the rotating shaft, and the rotating shaft is rotated by power supplied from the outside because bearings are installed.

When the generator operates in the above configuration, the rotation shaft rotates while inevitably causing friction between the accessories supporting the rotation shaft. Such friction causes resistance, which leads to loss of energy. In particular, as a considerable amount of heat is generated by the friction as described above, it may cause a malfunction of the generator due to overheating, and various problems such as noise are also generated.

Korean Patent Application Publication No. 10-2017-0022949 (2017. 3. 2.)

The present invention provides high-efficiency power generation by solving various problems caused by resistance caused by friction between a rotating shaft rotating at high speed to rotate a rotor in the process of generating electricity as a generator and friction with an accessory supporting the rotating shaft. The purpose is to propose a generator that makes this possible.

The present invention proposes a resistance-free generator that prevents the occurrence of problems due to frictional resistance by preventing friction from occurring in the process of rotating at high speed by forming a rotating shaft in a buoyant state while being spaced apart from an accessory supporting the rotating shaft. achieve the purpose of

According to the present invention, since the rotating shaft can generate electricity while rotating at high speed without frictional resistance, the occurrence of mechanical problems due to frictional resistance is prevented and a generator having improved power generation efficiency can be obtained.

1 is an exemplary view of a generator according to the present invention;
Figure 2 is an exemplary view showing a part of the configuration of the generator according to the present invention,
3 is a cross-sectional view of a generator according to the present invention;
Figure 4 is an exemplary view showing the bottom support structure of the rotating shaft of the generator in the present invention.

In the present invention, it comprises a rotating shaft that forms a certain length and is installed in a state in which the rotor is mounted in the middle part and rotates by an external force, while the lower end of the rotating shaft is installed in a state levitated by magnetic force, while the longitudinal direction of the rotating shaft is Accordingly, a shaft support means is formed to support the rotation shaft in a state not in contact with the rotation shaft by magnetic force at at least one point, so that frictional resistance does not occur in the course of the rotation shaft rotation.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings 1 to 4 .

1 is an exemplary view of a generator according to the present invention, FIG. 2 is an exemplary view showing a partial configuration of a generator according to the present invention by incision, FIG. 3 is a cross-sectional exemplary view of a generator according to the present invention, FIG. 4 is a generator according to the present invention It is an exemplary view showing the support structure at the bottom of the rotation shaft.

The resistance-free generator according to the present invention is formed so that frictional resistance does not occur in the process of rotating the rotating shaft 100 at high speed. As can be seen in a general generator, the rotating shaft 100 is formed with a rotor 300 , and the rotor 300 rotates at a high speed inside the stator 400 to generate power.

Magnetic force is used to prevent frictional resistance from occurring in the process of rotating the rotating shaft 100 at high speed, and the magnetic force is provided by a magnet.

The rotating shaft 100 has a rotor 300 provided with a magnet in the middle portion is formed. The rotor 300 is disposed inside the stator 400 on which the coil is wound and rotates at a high speed according to the rotation of the rotation shaft 100 , and as a result, electricity is generated in the stator 400 . The structure of generating electricity through the rotor 300 and the stator 400 is not different from the structure of a known generator.

In the present invention, the rotating shaft 100 is formed to have a predetermined length, and is installed upright. In this configuration, the rotary shaft 100 is formed to be in a buoyant state by magnetic force, the support 200 is formed at the lower end of the rotary shaft 100, and a magnet is installed between the rotary shaft 100 and the support 200 by the repulsive force. form a floating structure.

That is, a protrusion 120 having a diameter smaller than that of the rotary shaft 100 or the support 200 is formed in any one of the lower end of the rotary shaft 100 and the upper end of the support 200 , and a shaft groove having a larger diameter than the protrusion 120 is formed in the other one. 220 is formed and the protrusion 120 is fitted and coupled to the shaft groove 220. At the lower end of the rotation shaft 100 and the upper end of the support 200, the levitation magnets 140 and 240 are formed so that the same poles face each other. By the repulsive force between the levitation magnets 140 and 240, the rotating shaft 100 is in a buoyant state. When the projection 120 is formed at the lower end of the rotation shaft 100, the shaft groove 220 is formed in the support 200, the projection 120 is fitted into the groove, and the projection 120 in the state in which the rotation shaft 100 is lifted. The lower end is to be floated to maintain a state spaced apart from the inner bottom of the shaft groove 220. According to the above, since the rotation shaft 100 and the support 200 are maintained in a state not in contact with each other, frictional resistance does not occur between the rotation shaft 100 and the support 200 when the rotation shaft 100 rotates.

The levitation magnets 140 and 240 are formed in a ring shape and may be respectively installed horizontally on the lower end of the rotation shaft 100 and the upper end of the support 200 . Therefore, when the levitation magnets 140 and 240 are installed at the lower end of the rotating shaft 100 and the support 200, the N pole and the S pole are arranged vertically, and at the lower end of the rotating shaft 100 and the support 200, at the top. Repulsive force acts by placing the same poles facing each other between the installed ones. However, the shape of the levitation magnets 140 and 240 is not limited to a ring shape.

On the other hand, a means for restricting the rotation shaft 100 from excessive movement in the horizontal direction is formed at the point where the levitation magnets 140 and 240 are installed as described above. Through this, the protrusion 120 does not come into contact with the inner wall surface of the shaft groove 220 , and the lower support magnet 520 may be adopted as such means.

The lower support magnet 520 is installed to correspond to the point where the levitation magnets 140 and 240 are installed at regular intervals from the outer circumferential surface of the rotation shaft 100, and the levitation magnets 140 are formed so that the same poles face each other up and down. 240) are formed to face each other. For example, when the S poles of the levitation magnets 140 and 240 are formed to face each other, the lower support magnet 520 is formed at a position where the S poles correspond to the S poles of the levitation magnets 140 and 240 . . Accordingly, a repulsive force acts between the lower support magnet 520 and the buoyancy magnets 140 and 240, so that the rotation shaft 100 is restricted from moving in the horizontal direction so that the protrusion 120 does not come into contact with the inner wall surface of the shaft groove 220. will do As a result, the projection 120 can rotate without frictional resistance inside the shaft groove 220 .

The lower support magnet 520 as described above is formed in a ring shape and may be installed in such a way that the rotation shaft 100 passes therethrough. However, the present invention is not limited thereto, and may be installed radially with respect to the rotation axis by forming a bar magnet shape.

The rotating shaft 100 is formed to maintain an erected state as a shaft support means. The shaft support means is to be formed at at least one point along the longitudinal direction of the rotation shaft 100, and is formed to support the rotation shaft 100 by magnetic force. Since the lower support magnet 520 supports the lower portion of the rotation shaft 100 , the shaft support means is formed on the rotation shaft 100 .

The shaft support means may include a shaft magnet 160 installed on the rotation shaft 100 and an upper support magnet 540 having poles opposite to each other and spaced apart from the shaft magnet 160 . In a state in which the axis magnet 160 is formed to have an N pole and an S pole arranged in the height direction, the upper support magnet 540 is placed at a position corresponding to the N pole or the S pole so that the poles such as the N pole or the S pole face each other. By being formed, a repulsive force is formed between the shaft magnet 160 and the upper support magnet 540 , so that the rotating shaft 100 is formed so as not to be in contact with the upper support magnet 540 . Through this, the rotation shaft 100 rotates in a state in which frictional resistance does not occur in the course of rotation.

The upper support magnet 540 as described above is formed in a ring shape and may be installed in such a way that the rotation shaft 100 passes therethrough. However, the present invention is not limited thereto, and may be installed radially with respect to the rotation axis by forming a bar magnet shape.

In the generator according to the present invention described above, the shaft rotation means is formed to rotate the rotation shaft 100 . The shaft rotation means may be any means capable of rotating the rotation shaft 100 , but the driving magnet 180 and the driving magnet 180 installed on the rotation shaft 100 and the electromagnet 600 installed at a predetermined interval. ) may be formed.

The driving magnet 180 is formed such that the N pole and the S pole of the rotation shaft 100 are arranged in opposite directions in the horizontal direction with respect to the center of the rotation shaft 100 . In this configuration, when power is supplied to the electromagnet 600 , the magnetic force generated in the electromagnet 600 pushes the driving magnet 180 , and as a result, the rotation shaft 100 rotates. This configuration also does not come into contact between the driving magnet 180 and the electromagnet 600 , so that frictional resistance does not occur in the process of providing power to rotate the rotating shaft 100 .

Here, the electromagnet 600 is supplied with electricity from the outside, the system may be configured such that the electricity supplied from the outside is intermittently supplied for a predetermined time. Since the rotation shaft 100 continues to rotate due to inertia when it reaches a constant speed after the rotation starts, the rotation speed is maintained to some extent even if magnetic force is not generated in the electromagnet 600, so that the rotation speed is lower than the rotation speed required for power generation. When it is reduced, the speed is sensed by a sensor and electricity is supplied to the electromagnet 600 . That is, since the rotation shaft 100 rotates without frictional resistance in the resistanceless generator according to the present invention, when the rotation shaft 100 reaches a certain degree after starting rotation, even if the force to rotate the rotation shaft 100 is removed, the rotation shaft ( Since the 100) continues to rotate due to inertia, power generation can be generated while maintaining the rotational speed to a certain extent even when the power to rotate the rotating shaft 100 is intermittently supplied using the electromagnet 600 .

Here, as is well known, in the generator, the stator 400 surrounds the rotor 300 installed on the rotating shaft 100 and is installed so that electricity is produced in the stator 400 according to the rotation of the rotor 300, the present invention In the stator 400 , a portion of electricity produced is supplied to the electromagnet 600 to be used as a power source to operate the electromagnet 600 .

The resistanceless generator according to the present invention may be installed inside the housing 900 . The housing 900 may be formed so that the interior is maintained in a vacuum state, and when the interior of the housing 900 is formed in a vacuum state, even air resistance does not occur during the rotation of the rotating shaft 100, so maximizing power generation efficiency be able to devise

On the other hand, in the non-resistance generator according to the present invention described above, the upper support magnet 540, the lower support magnet 520, the electromagnet 600, and the stator 400 are formed in a fixed position with a support not shown. . The support may adopt any means to firmly support the components and prevent them from moving.

According to the present invention as described above, the configuration for supporting the lower portion of the rotary shaft 100 , the configuration for supporting the upper portion, and the configuration for rotating the rotary shaft 100 can all be formed so as not to contact the rotary shaft 100 . Therefore, the rotation shaft 100 starts to rotate by the shaft rotation means, reaches a predetermined rotation speed, and in the process of generating electricity, the rotation shaft 100 can rotate without frictional resistance, so the power generation efficiency is improved, and friction no mechanical damage caused by

100: rotation axis, 120: projection,
140, 240: levitation magnet, 160: axis magnet,
180: driving magnet, 200: support,
220: shaft groove, 300: rotor,
400: stator, 520: lower support magnet,
540: upper support magnet, 600: electromagnet,
900: housing.

Claims (6)

It forms a certain length and includes a rotating shaft 100 that is installed and installed in a state in which the rotor 300 is mounted in the middle part, and rotates by an external force,
The lower end of the rotating shaft 100 is installed in a state buoyed by magnetic force, while at least one point along the longitudinal direction of the rotating shaft 100 is a shaft support means for supporting the rotating shaft 100 in a state not in contact with the rotating shaft 100 by magnetic force. is formed,
A resistance-free generator in which frictional resistance does not occur in the process of rotating the rotating shaft 100. The method of claim 1,
The lower end of the rotation shaft 100 is supported by the support 200,
A protrusion 120 is formed on one of the lower end of the rotation shaft 100 and the support 200, while a shaft groove 220 having a larger diameter than the projection 120 is formed on the other, so that the protrusion 120 is a shaft groove. (220) is fitted and coupled,
At the lower end of the rotating shaft 100 and the upper end of the support 200, levitation magnets 140 and 240 are respectively formed so that the same poles face each other,
A lower support magnet 520 in which poles such as the levitation magnets 140 and 240 face each other at regular intervals from the outer peripheral surface of the rotation shaft 100 are provided,
The rotation shaft 100 is levitated in a state not in contact with the support 200 by the repulsive force formed between the levitation magnets 140 and 240 and the lower support magnet 520, so that the rotation shaft 100 is rotated A resistance-free generator in which frictional resistance is not generated. The method of claim 1,
The shaft support means includes a shaft magnet 160 installed on the rotation shaft 100 and an upper support magnet 540 with poles such as the shaft magnet 160 facing each other and formed at regular intervals,
A resistance-free generator in which the rotating shaft 100 is supported upright by the repulsive force formed between the shaft magnet 160 and the upper support magnet 540, so that frictional resistance does not occur in the course of rotation. The method of claim 1,
A shaft rotation means is installed at a certain point of the rotation shaft 100 to rotate the rotation shaft 100,
The shaft rotation means includes a driving magnet 180 installed on the rotation shaft 100 and an electromagnet 600 installed at a predetermined distance from the driving magnet 180,
By supplying power to the electromagnet (600) to generate magnetic force, the electromagnet (600) pushes the driving magnet (180) to rotate the rotation shaft (100). 5. The method of claim 4,
The electromagnet 600 is installed to surround the rotor 300 installed on the rotation shaft 100 and is intermittently supplied with electricity from the stator 400 that produces electricity according to the rotation of the rotor 300 to generate magnetic force. Resistance generator let. 6. The method according to any one of claims 1 to 5,
A resistance-free generator installed in the housing (900), further comprising a housing (900) in which the inside is maintained in a vacuum state.

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