KR20160111291A - Electricity generation system use of Pillar and Magnet and Wind Force - Google Patents

Abstract

The present invention relates to a wind power generation system which reduces frictional force through the repulsive properties of a magnet by arranging the magnet in a pillar, a hollow pillar, a rotary shaft, etc. to have polarity during a process using the power of wind through the pillar, a rotary blade, or a magnetic unit, such as a magnet or an electromagnet, reduces installation costs and failure, and simplifies the repair thereof. Moreover, the present invention prevents failure as bearings or various devices do not exist and enables the long-time use thereof.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power generation system using a pole, a magnet,

The present invention can produce stable electricity by using the power generation device by converting the flow energy of the wind into rotational motion by using the characteristics of the magnet.

The present invention is advantageous in that the facility is excessively inefficient and inefficient in order to develop using the wind power, while the present invention is advantageous in that it can be easily installed in a windy place, .

Electric power can be generated by the generator using the magnetic force means such as the column, the rotating blades, the magnet or the electromagnet, and by reducing the frictional force using the characteristics of the magnet, and reducing the various mechanical devices.

According to the present invention, by using magnetic characteristics such as a pillar, a rotating blade, a magnet or an electromagnet to convert the wind force into rotational force, the friction force is reduced and various mechanical devices are reduced. It is possible to make an electric power generation system which is almost nonexistent.

In the process of using the force of the wind by using the magnetic force means such as the pole, the rotating wing and the magnet or the electromagnet, when the magnet is disposed in a column or a hollow column or a rotating shaft so as to be polarized, the friction force is reduced due to the pushing force between the magnets. It is easy to repair, with fewer faults. In addition, since there are few bearings and various mechanical devices, there is little trouble and it is possible to use for a long time.

The representative drawing is a vertical wind power generator to which the technique of the present invention is applied.
1 is a view of a column and a base plate of a vertical type wind turbine to which the present invention is applied.
FIG. 2 is a hollow circular column and a base plate of a vertical wind power generator to which the present invention is applied.
FIG. 3 is a power generation system using a hollow circular column to which the present invention is applied, and a wind force having a base, a magnet and a coil coupled to each other.
FIG. 4 is a power generation system using a double circular column to which the technique of the present invention is applied, and a wind force combined with a base plate and a vertical rotating blade.
FIG. 5 is a power generation system using a hollow circular column to which the present invention is applied, a vertical rotating blade, a wind power combined with a support plate and a power generation device.
6 is a horizontal type wind power generator to which the technique of the present invention is applied.

In the construction of a power generation system using a column, a magnet, and wind power of the present invention,

1 and 2, the circular column 66 is fixed to the floor, the support plate 68 is fixed to the lower part of the circular column 66 and the magnet 69 is mounted on the support plate 68 with the same polarity, And the magnet 72 is installed outside the circular column 66 so as to have the same polarity. And a coil 74 is wound around the upper portion of the support plate 68 provided on the circular column 66 to fix it.

A vertical rotating blade 77 is fixed to a hollow cylinder 67 and a support plate 70 is installed and fixed to a lower end of the support plate 70. A magnet 71 is installed and arranged at the lower end of the support plate 70 with the same polarity, A magnet (73) is installed inside the cylinder (67) so as to have the same polarity. A coil (74) is wound around the outside of the circular column (66), and a magnet (75) is disposed inside the cylindrical hollow (67). A support stand (78) and a lid (79) are installed on the top of the column to prevent wind and rain.

When the vertical rotary blade 77 and the hollow cylinder 67 provided with the support plate 70 are inserted into the circular column 66 provided with the support plate 68 at the lower portion and the magnets 69 and 71 provided with the same polarity and the magnets 72 73 do not collide with each other due to the pushing force between the circular column 66 and the hollow cylinder 67 and the support plates 68, 70, there is almost no frictional force.

When the vertical rotating blades 77 begin to rotate using the wind force, the hollow cylinder 67 will rotate and the magnet 75 inside the hollow cylinder 67 will rotate. The coil 74 provided on the circular column 66 is fixed and the magnet 75 opposite to the magnet is rotated, so that electricity can be produced by the electromagnetic induction principle. The generated electricity can be collected in the capacitor 93 or electricity can be sent to the desired location. The fixed coil 74 and the rotating magnet 75 are power generators 76 by themselves and have excellent power generation efficiency without the need for gears or bearings and have little trouble.

In the construction of a power generation system using a column, a magnet, and wind power of the present invention,

In figures 3, 4 and 5

The column 20 is firmly fixed to the floor and a pedestal 21 is installed on the bottom of the column 20 and a magnet 24 is installed on the top of the pedestal 21. A magnet (33) is disposed on the outside of the magnet (32) inside the hollow circular column (20). A vertical rotary blade (23) is fixed to the hollow double cylinder (22). A support plate 25 is provided at the lower end of the hollow double cylinder 22 and a magnet 26 is installed at the lower end of the support plate 25. A magnet 30 is installed inside the hollow double cylinder 22, A magnet (31) is installed outside the rotary shaft (29) coupled with the double cylinder (22). A magnet 34 is installed outside the rotary shaft 29 coupled with the hollow double cylinder 22 and the coil 35 is installed inside the hollow double cylindrical body 22 opposite to the rotary shaft 29. A capacitor (36) is installed under the hollow circular column (20).

The magnet 24 of the hollow circular column 20 receiving plate 21 and the magnet 26 of the hollow double cylinder 22 receiving plate 25 are arranged and arranged so as to have the same polarity, Therefore, there is almost no friction between the support plate 21 and the support plate 25 because the support plate 21 hardly bumps against the support plate 25 and the magnets 32 and 33 inside and outside the hollow circular column 20 and the magnet 30 inside the hollow double cylinder and the rotary shaft 29 The hollow circular cylinder 20 and the hollow double cylindrical body 22 and the rotary shaft 29 almost collide with each other due to the property that the external magnets 31 are installed and arranged so as to have the same polarity, Since there is almost no friction, there is no loss of torque due to friction, and there is no need for bearings and various lubricants to reduce friction. The weight of the hollow double cylinder 22, the rotary shaft 29, the vertical rotary vanes 23 and the support plate 25 is adjusted by the repulsive force of the magnets 24 and 26 provided on the support plates 21 and 25 with the same polarity So that there is little frictional force.

Since the hollow circular column 20 is fixed, the coil 35 wound around the hollow circular column 20 is also fixed. The hollow cylindrical cylinder 22, the rotary shaft 29 and the vertical rotary blades 23 When the vertical rotary blade 23 rotates using the wind force, the rotary shaft 29 rotates and the magnet 34 is installed outside the rotary shaft 29, so that the magnet 34 rotates do. The rotating magnet (34) outside the rotary shaft (29), which is opposed to the coil (35) stopped inside the hollow circular column (20), can produce electricity due to the electromagnetic induction principle. The fixed coil 35 and the rotating magnet 34 are power generating devices 41 themselves, and there is no gears, bearings, or the like, so that the power generation efficiency is excellent. The generated electricity can be collected in a capacitor (36) installed under the hollow circular column (20), and electricity can be sent to the desired location.

Further, the fixed coil 35 and the rotating magnet 34 function as the power generation device 41, so that electricity can be produced.

The present invention has a simple structure and almost no friction due to the repulsive force of the magnet, so that it is efficient to produce electricity, does not require bearings or additional supports, has little trouble, The size, length and width of the hollow circular cylinder 20 and the hollow circular cylinder 22 can be made as large as desired by increasing the repulsive force of the circular rotary vane 23, There is an advantage that the diameter, the length, the width and the weight of the hollow circular column 20, the vertical rotary vane 23 and the hollow double cylinder 22 can be made large. Various types of vertical rotating blades can be coupled to the hollow double cylinder 22 as desired. In addition, the number and the angle of the vertical rotary blades 23 can be varied, and the vertical rotary blades 23 can be freely installed at desired positions. If the vertical rotary blades are oriented in one direction, rotation in one direction . There are not many places where breakdown occurs, and there is not much to repair or exchange, so it is easy to replace.

In the construction of the power generation system using the column, the magnet, and the horizontal rotating blades of the present invention,

In FIG. 6, the column 80 is firmly fixed to the floor and a magnet 86 is installed in the rotation shaft hole 95 of the upper rotation part 94, which is positioned at the upper end of the column 80, The magnets 87 are installed in the same polarity. A magnet 85 is installed on the outside of the rotary shaft 82 connected to the horizontal rotary vane 81 with the same polarity and a magnet 96 is installed on the outside of the rotary shaft support plate 83 provided on the rotary shaft 82 with the same polarity .

The rotary shaft 82 and the rotary shaft support plate 83 are installed in the rotary shaft hole 95 and the rotary shaft support 84.

The rotating shaft 82 and the rotating shaft hole 95 do not hit each other due to the mutual pushing properties of the magnet poles 86 and 85 provided on the inside and the outside of the rotating shaft hole 95 and the rotating shaft 82. The rotating shaft supporting plate 83 and the rotating shaft supporting member 84 do not hit each other due to the pushing nature of the polarized magnets 87 and 96 provided inside and outside the rotating shaft supporting plate 84 and the rotating shaft supporting plate 83, Since the rotary shaft support plate 83 is hardly moved back and forth due to the structure of the rotary shaft support 84, the rotary shaft 82 is fixed without any frictional force.

A magnet 89 is disposed outside the rotary shaft 82 and a coil 88 is wound around the rotary shaft hole 95 to fix the rotary shaft.

When the horizontal rotation blade 81 starts to rotate using the wind force, the rotation shaft 82 will rotate, and when the rotation shaft 82 rotates, the magnet 89 will rotate. Since the coils 88 installed inside the rotary shaft hole 95 are fixed and the magnet 89 is rotated, electricity can be produced by the electromagnetic induction principle. The generated electricity can be collected in the capacitor 91 or sent to the desired location. The fixed coil 88 and the rotating magnet 89 are power generators 90 themselves, and since there is no gear or bearing, the power generation efficiency is excellent and there is almost no trouble.

As described above, the power generation system using the nature of the magnetic force means such as a magnet or an electromagnet does not need a gear device or a bearing, is simple in structure, has few faulty spots, and can maximize power generation efficiency. In the conventional power generation apparatus, once the power generation unit is used, the power generation range is short such that it is difficult to generate electricity if the power transmitted to the power generation unit exceeds a certain level. However, the present invention has a wide range of using the power.

Although it is possible that a minimum frictional force reduction device may be required because the repulsive force of a magnetic means such as a magnet or an electromagnet is utilized and the size of the device changes to a large scale, the weight may be limited to some extent, When the nature of the magnetic means such as a magnet or an electromagnet is used, there is almost no need for frictional force and various gear devices, so that there is no trouble and the power generation efficiency is excellent.

(Or a magnetic means such as an electromagnet), 25: a supporting plate, 26: a magnet (or a magnetic means such as an electromagnet, etc.), and 20: a hollow circular column, 21: (Magnetic means such as an electromagnet), 32: magnet (or magnetic means such as an electromagnet), 33: magnet (or magnetic means such as an electromagnet), 34 A magnet (or a magnetic force such as an electromagnet), 35: a coil, 36: a capacitor, 41: a generator (34 + 35), 66: a circular column, 67: a hollow cylinder, 68: (Or a magnetic means such as an electromagnet), 73: a magnet (or a magnetic means such as an electromagnet), 74: a coil, 75: a magnet (76 + 75), 77: vertical rotary wing, 78: supporting stand, 79: lid, 80: pillar, 81: horizontal rotating blade, 82: rotary shaft, 83: (Or a magnetic means such as an electromagnet), 87: a magnet (or a magnetic means such as an electromagnet), 88: a coil, 89: a magnet A magnet (or a magnetic means such as an electromagnet), a magnet (or a magnetic means such as an electromagnet).

Claims (3)

In the construction of a power generation system using a column, a magnet, and wind power of the present invention,

A circular column 66 rigidly fixed to the floor;
A hollow cylinder 67 coupled with the vertical rotating blades 23;
A vertical rotary vane 77 for converting the force of wind into a rotary force;
A magnetic force means 72 of the same polarity installed on the outside of the circular column 66 made to have no frictional force by using the repulsive force to push the same poles of the magnets to each other and a magnetic force means 73 of the same polarity provided inside the hollow cylinder 67, and;
A support plate 68 provided below the circular column 66 and a support plate 70 provided at the lower end of the hollow cylinder 67;
A magnetic force means 69 of the same polarity provided on the upper end of a support plate 68 made to have no frictional force by using a repulsive force to push the same poles of magnets to each other and a magnetic force means 71 of the same polarity installed at the lower end of the support plate 70;
A coil 74 installed outside and fixed to the circular column 66;
Magnetic force means (75) installed inside the hollow cylinder (67) and rotating;
A power generating device 76 for generating electricity constituted by a coil 74 installed outside and fixed to the circular column 66 and a magnetic force means 75 installed inside the hollow cylinder 67 and rotating;
A capacitor 93 below the circular column 66 for collecting the produced electricity;

A power generation system using a column, a magnet, and wind power combined with the components.
In a power generation system using columns, magnets and wind,

A hollow circular column 20 rigidly fixed to the floor;
A hollow double cylinder 22 coupled with the vertical rotary vane 23 and the rotary shaft 29;
A vertical rotary blade 23 for converting the force of wind into a rotary force;
A rotary shaft (29) rotating in accordance with rotation of the vertical rotary vane (23);
Magnetic force means (32, 33) of the same polarity installed on the inside and outside of the hollow circular column (20) which makes the frictional force free by using the repulsive force pushing the same pole of the magnet to each other, Magnetic force means (30) and magnetic force means (31) of the same polarity provided outside the rotating shaft;
A support plate 21 provided below the hollow circular column 20 and a support plate 25 provided at the lower end of the hollow double cylinder 22;
Magnetic force means (24) of the same polarity installed on the upper end of a support plate (21) made to have no frictional force by using the repulsive force to push the same poles of the magnets to each other and magnetic force means (26) of the same polarity installed at the lower end of the support plate (25);
A fixed coil 35 installed inside the hollow circular column 20;
A rotating magnetic force means (34) provided outside the rotary shaft (29);
A power generator 41 for generating electricity, which is composed of a coil 35 fixed inside the hollow circular column 20 and a magnetic force means 34 installed outside the rotary shaft 29 and rotating;
A capacitor (36) below the hollow circular column (20) collecting the produced electricity;

A power generation system using a column, a magnet, and wind power combined with the components.
In a power generation system using columns, magnets and wind,

A column 80 rigidly fixed to the floor;
A horizontal rotating blade 81 for converting the force of the wind into rotational force;
A rotary shaft 82 for transmitting the rotational force of the horizontal type rotary vane 81;
A rotary shaft support plate 83 and a rotary shaft support 84 provided in the middle of a rotary shaft 82 serving to fix the rotary shaft 82;
A magnetic force means 85 of the same polarity provided on the outside of the rotary shaft 82 which makes the frictional force free from the frictional force by pushing the same poles to each other and a magnetic force means 86 of the same polarity provided inside the rotary shaft hole 95;
A magnetic force means (96) outside the rotation axis support plate (83) and a magnetic force means (87) inside the rotation axis support base (84) serving also as a frictional force and a support force by using a repulsive force to push the same poles of the magnets to each other;
A magnetic force means 89 provided outside the rotary shaft 82 and rotating;
A coil 88 installed inside and fixed to the rotary shaft hole 95;
A power generating device 90 for generating electricity, comprising a coil 88 installed inside and fixed to the rotary shaft hole 95 and a magnetic force means 89 provided outside the rotary shaft 82 and rotating;
A capacitor 91 for collecting the produced electricity;

A power generation system using a column, a magnet, and wind power combined with the components.

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