JP6318331B1 - Power generator - Google Patents

Abstract

An object of the present invention is to create a power generator capable of generating a predetermined power generation amount by reducing the frictional resistance of a rotating body to zero and transmitting the rotation of the rotating body rotating within a predetermined rotation range to a generator. The rotating shaft of an electric motor (1) is connected to a rotating body, and air is supplied from an arc-shaped cage (5) provided with a number of fine holes (4) provided at the lower part of the rotating body. 2, and the air has floated a “predetermined range” at the bottom of the rotating body that has blocked many fine holes (4), and is provided in two longitudinal directions on the periphery of the rotating body 2. The N poles of the two permanent magnets provided on the arc-shaped cage (5) facing the two rubber magnets and the N poles of the two rubber magnets repel each other, and the rotating body is within a predetermined rotation range. The problem is solved by rotating at [Selection] Figure 3

Description

The present invention relates to a power generator.

In the search on the JPO homepage, a search was made for “no power generation device friction resistance” and the number of hits was zero.
As a representative technique for levitating a rotating body, there is a linear Shinkansen using a superconducting magnet.
JR Tokai's official website is a non-patent document 1 that details the principles of the Linear Shinkansen.
According to Non-Patent Document 1, in the transportation system that opens the door of the next generation,
“By applying an electric current to the propulsion coil of the guideway, a magnetic field (N pole / S pole) is generated and repels the attractive force with the superconducting magnet (alternately arranged N pole / S pole) of the vehicle. The vehicle (superconducting magnet) moves forward using this force, ”and the principle of levitation is described as“ levitation / guide coils are installed on both sides of the guideway side wall. When the superconducting magnet passes at high speed, current flows through the levitation / guide coils on both sides to become an electromagnet, which generates a force that pushes up the vehicle (superconducting magnet) (repulsive force) and a force that pulls it up (attraction force). " It is.
In Non-Patent Document 1, by switching the magnetic pole of the superconducting magnet of the vehicle, the N pole of the magnetic pole repels the N pole of the propulsion coil that is slightly behind, and is attracted to the S pole of the propulsion coil that is slightly ahead. Proceeding forward, when the superconducting magnet of the vehicle passes at high speed, current flows through the levitation / guide coils on both sides to become electromagnets, and the electromagnets are paired with magnetic poles at the top and bottom. In contrast to the mechanism that attracts the S pole of the levitation / guide coil and repels the N pole of the guide coil to levitate the vehicle, in the present invention, the arc-shaped cage (5 A large number of fine holes (4) facing the "predetermined range" of the bottom (3) of the rotating body A (2) provided on the bottom (3) of the rotating body A (2) The pressure of the fine holes (4) and the arc-shaped ridges (5) is the same. In both cases, the pressure is increased and the bottom (3) of the rotating body A (2) is levitated. The levitating device is a superconducting electromagnet in Reference 1, and the present invention is compressed air in the present invention. This is an invention different from Document 1.
In order to achieve CO2 reductions that Japan has made an international commitment to prevent global warming, further diffusion of renewable energy is necessary. Occurred, and a yellow signal was lit to further spread renewable energy.
France and the United Kingdom have stopped selling gasoline vehicles since 2040, and have declared that only electric vehicles and hybrid vehicles are allowed to be sold, and China and India have also declared the use of electric vehicles. The purpose is to prevent air pollution and global warming.
If the use of electric vehicles is to prevent global warming, the electricity from the drive source must of course be renewable energy.
In the future power supply, if we think that at least half of the supply amount should be covered by renewable energy, there is a drawback that the amount of solar power and wind power generation that occupies the core of renewable energy depends on weather conditions, Considering the possibility of an eruption in Japan as a volcanic power, there is a limit to the expansion of geothermal power generation.
The required power generator is a new type of power generator that has never been proposed before.
The rotating body is rotated with zero frictional resistance, and the rotating body is rotated within a predetermined rotation range. During rotation, the rotating body rotates without contacting anything, and is controlled to a predetermined rotational speed to generate power. If it is transmitted to the machine, the power generation device can generate a predetermined power generation amount.

About JR Tokai's official website, Superconducting Linear

Accordingly, the present invention has been made in view of the above circumstances, and the frictional resistance of the rotating body is made zero, the rotation of the rotating body rotating within a predetermined rotation range is transmitted to the generator, and a predetermined power generation amount is obtained. It is an object to create a power generator that can be generated.

The rotating shaft of the electric motor (1) is connected to the rotating body, and air is ejected from an arc-shaped ridge (5) provided with a number of fine holes (4) provided at the lower part of the rotating body, The above-mentioned “predetermined range” of the bottom of the rotating body where the air blocked many fine holes (4) floats, and two rubber magnets provided in the longitudinal direction at two locations on the circumferential edge of the rotating body. The N pole of the two permanent magnets provided on the arc-shaped cage (5) facing the N pole and the two rubber magnets repels and the rotating body rotates within a predetermined rotation range. Solve the problem.

An ideal power generator can be obtained by floating the rotor in the air, rotating the rotor with zero frictional resistance, and controlling the number of rotations to transmit to the generator.
A typical means of the method of floating a rotating body in the air is a method using a superconducting magnet of a linear Shinkansen. Although the superconducting magnet of the linear Shinkansen is made with liquid helium minus 269 degrees, in recent years the cost of manufacturing liquid helium, a container for storing minus 269 degrees liquid helium, etc. has increased. The demand is higher than the supply of helium, and the price is rising.
The present invention rotates using compressed air generated by a large number of fine holes (4) in an arcuate cage (5) containing air being blocked by the bottom (3) of the rotating body. Since the body is levitated in the air, the cost is overwhelmingly low, and the installation place can be installed in the place where power is used.

Is a schematic diagram of the entire present invention. Is a conceptual diagram of the rotator A (2) and the arc-shaped ridge facing each other from the bottom (3) of the rotator A (2) to the middle of the vertical height of the circumference of the rotator A (2). . Is a conceptual diagram of a “predetermined range” of the bottom (3) of the rotating body A (2) facing a number of fine holes (4) attached to the arcuate cage (5). Is a cross-sectional view of the rotator A (2), and the horizontal tangent line I (36) at the bottom and a line passing through the center point G (34) of the rotator A (2) in the horizontal direction of the rotator A (2) The conceptual diagram of the rubber magnet (8) and rubber magnet (14) in the position which cross | intersects a circular periphery. FIG. 4 is a conceptual diagram of an arc-shaped ridge (5) provided below a tangent line I (36) from a circular peripheral edge J (37) to a circular peripheral edge k (38) at the bottom of the rotating body A (2). Is a conceptual diagram of a 5-phase excitation stepping motor type excitation circuit.

The generator is a synchronous generator with a frequency of 60 Hz and the number of poles is 4 poles. The electric motor (1) has an inverter (VVVF) control system that changes the voltage and frequency, and the installed rotating body A (2) is air from below. A load that requires a sufficient torque to generate a predetermined power generation amount without being subjected to electric power, and the rotating body A (2) and the generator rotate at 1800 times / rpm to generate the predetermined power generation amount. The apparatus and operation to be performed will be described with reference to FIG. 1 to FIG.

Items other than the claims related to the present invention will be described below.

Explanation of Terms A, “Front” In the present invention, the direction of the generator is “front” when viewed from the place farthest from the generator.
(B) “Predetermined range” of the bottom (3) of the rotating body A (2) The “predetermined range” of the bottom (3) of the rotating body A (2) used in the present invention is the electric motor (1). Orthogonal to the perpendicular H (35) drawn from the center point G (34) of the rotating body A (2) to the circumferential edge of the rotating body A (2) in the cross section of the rotating body A (2) facing The bottom (3) of the rotating body A (2) in the vicinity of the tangent line I (36) from the circumferential edge J (37) to the circumferential edge k (38) of the rotating body A (2) is circular. It is the range where many fine holes (4) provided in the shape ridge (5) are closed.
C. “Stepping motor type excitation circuit for five-phase excitation” “Stepping motor type excitation circuit for five-phase excitation” is 1 step angle = 0.72 °, and when the rotation axis makes one revolution, it advances by 500 step angles. The number of step angles that rotate continuously and the number of step angles that stop are determined by the rotation sensor attached to the rotating body A (2), and depending on whether the rotational speed of the rotating body A (2) is excessive or insufficient When it is changed each time and you want to increase the number of rotations of the rotating body A (2),
When the rotating step angle is continuously rotated to reduce the rotation speed, the stopped step angle is continuously stopped.
The operation of successive steps is performed at a multiple of 1 step angle = 0.72 °. After the step angle is continuously rotated or stopped, the operation of alternately repeating rotation and stop for each step angle is alternated. Repeat.

Regarding the power source of the present invention, the power source of the present invention uses electricity (Japanese Patent No. 4362545) generated by the rotation of a DC electric motor connected to a storage battery charged with electricity obtained by solar power generation.
This patent keeps track of the power consumption, ranks the power consumption, and controls the rotation of the DC electric motor to supply the ranked higher power.
The power consumption used in the present invention is always grasped and ranked, and the electricity higher than the rank is efficiently supplied by controlling the rotation speed of the DC electric motor. Yes.
Since the generation of CO2 between the photovoltaic power generation and the power generation generated by the present invention is zero, it is a clean energy power generation device.

About the five-phase excitation stepping motor type excitation circuit in the present invention The present invention is provided with a five-phase excitation stepping motor type excitation circuit.
The stepping motor type excitation circuit has one step angle = 0.72 °, and advances by 500 step angles when the rotation shaft makes one round, and is provided at the middle position of the diameter in the longitudinal direction of the rotating body A (2).
As shown in FIG. 6, a stator A (28) provided with an electromagnet A (27) in which an electric wire is wound around an iron core in a concentric circular ring A (26), and the electromagnet A (27) are opposed to each other. In addition, a rotor A (29) provided with a magnet B (30) magnetized concentrically in the axial direction around the shaft, a programmable controller A (31, not shown), a controller A (32, FIG. And a driver A (33, not shown) connected to an electromagnet A (27).
When a current is passed through the controller A (32) and a pulse signal is given to the driver A (33), and the driver A (33) switches the current of the electromagnet A (27), the magnetic pole of the electromagnet A (27) Switching is performed, and the rotation sensor attached to the rotating body A (2) catches the excessive or insufficient rotation of the rotating body A (2), and the number of step angles to rotate continuously or the step of stopping continuously A pulse signal is given to the driver A (33) by a command from the computer that calculates the number of corners, and the rotating step angle is continuously stopped by rotating the step angle to be rotated or continuously stopped. The predetermined rotational speed of 2) is maintained.
For example, when the rotation of the rotating body A (2) returns to a predetermined number of rotations by continuously rotating two step angles, the operation is stopped by one step angle, and the operation is repeated to repeat the rotation and stop for each original step angle.
The rotational speed blur is corrected within the range of 1 step angle = 0.72 °, so even if the time required for correction is the entire 1 step angle, it is corrected within a maximum of 1/500 times. The rotation speed is maintained at 1800 times / rpm without accumulating, and the rotation of 1800 times / rpm is transmitted to the generator to enable synchronous power generation.

The claims will be described below.

1 is a schematic of an apparatus of the present invention.
FIG. 1 is an overall schematic view of the present invention.
The rotating body A (2) is provided facing the electric motor (1), and the rotating body A (2) is provided horizontally extending in the direction of the generator (53). A rotating shaft (52) connected to the rotating body A (2) is provided in the “front”, and the other of the rotating shaft (52) is connected to the generator (53).
As shown in FIG. 2, an arcuate scissors (5) is provided facing the bottom of the rotator A (2), and the rotator A (see FIG. 4) is facing the electric motor (1). 2) A tangent line I (36) perpendicular to the perpendicular H (35) drawn from the center point G (34) of the rotating body A (2) to the circumferential edge of the rotating body A (2) in the cross section of 2). As shown in FIG. 5, the tangent line I (36) extends from the circumferential edge J (37) of the rotating body A (2) to the position of the circumferential edge k (38), and is located near the tangent line I (36). The “predetermined range” of the bottom part (3) of the rotating body A (2) in FIG. 5 closes a large number of fine holes (4) provided in the arc-shaped ridge (5).
As shown in FIG. 3, a large number of fine holes provided in the upper portion of the arc-shaped ridge (5) facing the “predetermined range” portion of the bottom (3) of the rotating body A (2). (4) is open and provided, and the air blown from the blower (23) is contained in the arc-shaped bowl (5).
As shown in FIG. 5 below the “predetermined range” of the bottom (3) of the rotating body A (2) in the vicinity of the tangent line I (36) drawn in the longitudinal direction of the bottom of the rotating body A (2). Are provided with arc-shaped ridges (5) to which a number of fine holes (4) are attached.
As shown in FIG. 5, the rotation passing through the center point G (34) of the rotating body A (2) in parallel with the tangent line I (36) intersects the circumferential edge of the rotating body A (2). A rubber magnet Q (8) is provided from the circumferential edge O (6) facing the electric motor (1) of the body A (2) to the circumferential edge P (7) facing the generator (53). The magnetic pole with the rubber magnet Q (8) facing the arcuate ridge (5) is an N pole R (9).
The circle facing the portion from the circumferential edge O (6) facing the electric motor (1) of the rotating body A (2) to the circumferential edge P (7) facing the generator (53). A permanent magnet S (10) is installed in the arc-shaped cage (5), and the magnetic pole whose surface of the permanent magnet S (10) faces the rotating body A (2) is an N pole T (11). .
Electric power is generated from the circumferential edge U (12) shown in FIG. A magnetic pole is provided with a rubber magnet W (14) up to the circumferential edge V (13) facing the machine (53), and the rubber magnet W (14) faces the arcuate cage (5). N pole X (15).
A permanent magnet Y (16) is installed on the arcuate ridge (5) facing the portion from the circumferential edge U (12) to the circumferential edge V (13), and the permanent magnet Y (16) The magnetic pole facing the rotating body A (2)) is the N pole Z (17).

The vertical direction is from the bottom (3) of the rotating body A (2) to the middle of the vertical height of the circumference of the rotating body A (2), and the horizontal direction is the rotating body A as shown in FIG. An arc-shaped ridge (5) is provided so as to face the circular peripheral edge k (38) from the circular peripheral edge J (37) of (2), and “predetermined” of the bottom (3) of the rotating body A (2) A number of fine holes (4) shown in FIG. 3 are formed in the portion of the arc-shaped ridge (5) facing the surface area of “range”, and the arc-shaped ridge (5) The air blown from the blower (23) through the hose (25) is built in, and the hose (25) can only flow inward from the blower (23) into the arc-shaped bowl (5). A stop valve is provided.
Since air has “viscousness”, the air in the arc-shaped ridge (5) is difficult to pass through the fine holes (4), and the pressure in the arc-shaped ridge (5) M (21) is slightly higher than atmospheric pressure M0 (20).
In FIG. 3, a large number of fine holes (4) of the arcuate ridge (5) provided facing the “predetermined range” of the bottom (3) of the rotator A (2) When the “predetermined range” at the bottom (3) of A (2) is closed, the flow of air in the hole (4) becomes gentle, and the pressure M1 (19) is reduced to the pressure M ( 21) When the pressure M (21) is gradually increased, the pressure M1 (19) also increases, and many of them face the “predetermined range” at the bottom (3) of the rotating body A (2). If the surface area of the “predetermined range” of the bottom part (3) of the rotating body A (2) closing the fine hole (4) is L (22), the force is greater than (M−M0) × L force, The pressure M1 (19) acts on the “predetermined range” of the bottom (3) of the rotating body A (2) from below the rotating body A (2), and “floats” the bottom (3) of the rotating body A (2). So, the "floating" is "floating" to a position balanced with the gravity working downwards to the bottom of the rotating body A (2) (3).
Each of the holes (4) is perpendicular to a tangent line drawn perpendicularly to a line connecting the circumference of the rotating body A (2) from the center point G (34) of the rotating body A (2). The air from the hole (4) near the surface area of the "predetermined range" of the bottom (3) of the rotating body A (2) is provided to the rotating body A (2). 2) Even if the rotating body A (2) approaches the arcuate cage (5) by shifting the center point G (34), the N pole R (9), the N pole T (11), and The magnetic poles provided at two locations of the N pole X (15) and the N pole Z (17) repel each other, and the rotating body A (2) is pushed back within a predetermined rotation range, so that the rotating body A (2) Rotates within a predetermined rotation range without contacting the arc-shaped ridge (5).

When “floating” is performed to a position that balances the gravity acting downward on the bottom (3) of the rotating body A (2), the “predetermined range” of the bottom (3) of the rotating body A (2) and the rotation The pressure M1 (19) between the "predetermined range" of the bottom part (3) of the body A (2) and a number of fine holes (4) facing the inside of the arc-shaped cage (5) It becomes slightly lower than the pressure M (21), and the bottom (3) of the rotating body A (2) starts to fall.
The distance between the numerous fine holes (4) shown in FIG. 3 and the “predetermined range” of the bottom (3) of the rotating body A (2) is measured by a total station that combines an electronic theodolite and a light wave rangefinder. When the interval reaches a predetermined interval, the rotational speed of the blower (23) installed on the outside of the rotating body A (2) is increased, and the amount of air blown through the hose (25) = the amount of air is circular. The air is blown to (5), the amount of air in the arc-shaped bowl (5) is increased, and a large number of fine holes (4) and the “predetermined range” of the bottom (3) of the rotating body A (2) Is maintained at a predetermined distance.

FIG. 4 is a cross-sectional view of the rotating body A (2) facing the electric motor (1).
A line passing through the center point G (34) of the rotating body A (2) in parallel with the tangent line I (36) drawn in the horizontal direction at the bottom of the rotating body A (2) is the rotating body A (2). 5 facing the electric motor (1) of the rotating body A (2) intersecting with the peripheral edge of the circular peripheral edge P (7) facing the generator (53) from the circular peripheral edge O (6) shown in FIG. ), And a rubber magnet W (14) is provided between the rubber magnet Q (8) and the bottom of the rotating body A (2).

As shown in FIG. 5, the rubber magnet Q (8) generates power from a circumferential edge O (6) facing the electric motor (1) of the rotating body A (2) in the longitudinal direction of the rotating body A (2). The magnetic pole that is provided up to the circumferential edge P (7) facing the machine (53) and the rubber magnet Q (8) faces the arcuate ridge (5) is an N pole R (9). is there.
A permanent magnet S (10) is installed on the arcuate ridge (5) facing the portion from the circumferential edge O (6) to the circumferential edge P (7), and the permanent magnet S (10) The magnetic pole whose surface faces the rotating body A (2)) is the N pole T (11).
When the rotating body A (2) approaches the arcuate cage (5), the N pole R (9) and the N pole T (11) repel each other so that the rotating body A (2) is within a predetermined rotation range. Pushed back.

As shown in FIG. 5, the rubber magnet W (14) has a circumferential edge facing the generator (53) from a circumferential edge U (12) facing the electric motor (1) of the rotating body A (2). Up to V (13).
The N pole X (15), which is the magnetic pole of the rubber magnet W (14), faces the arcuate cage (5).
The arcuate scissors (5) facing the portion from the circumferential edge U (12) facing the electric motor (1) to the circumferential edge V (13) facing the generator (53) Is provided with a permanent magnet Y (16), and the magnetic pole with the permanent magnet Y (16) facing the rotating body A (2) is an N pole Z (17).
When the rotating body A (2) approaches the arcuate cage (5), the N pole X (15) and the N pole Z (17) repel each other, and the rotation of the rotating body A (2) is a predetermined rotation. Pushed back into range.

In addition to the rotating body A (2) being connected to the rotating shaft of the electric motor and rotating by the rotating force of the electric motor, the rotating body A (2) to be installed is not receiving air from the lower part. The rotating body A (2) has a load that requires a sufficient torque to generate a predetermined amount of power generation, and the rotating body A (2) floats upward with air from the bottom of the rotating body A (2), resulting in zero frictional resistance. Rotation A (2) rotates without touching the arcuate ridge (5) because it rotates within a predetermined rotation range as detailed in paragraphs 0018 and 0019.
The torque required to generate a predetermined amount of power generation is secured by adding the rotational force of the stepping motor type excitation circuit of the five-phase excitation, and the rotating body A (2) is controlled at a speed of 1800 times / rpm, and 1800 times. The rotation of / rpm is transmitted to the generator (53), enabling synchronous power generation.

1 = Electric motor 2 = Rotating body A
3 = Bottom of rotating body A (2) 4 = Many fine holes in the bottom (3) of rotating body A (2) 5 = Arc-shaped scissors 6 = Rotation facing the electric motor (1) Circumference O of body A (2)
7 = circumferential edge P facing the generator (53) of the rotating body A (2)
8 = Rubber magnet Q provided from the circumferential edge O (6) to the circumferential edge P (7) facing the generator (53)
9 = N pole R of rubber magnet Q (8)
10 = A permanent magnet S of arcuate cage (5)
11 = N pole T on the surface where the permanent magnet S (10) faces the rotating body A (2)
12 = circumferential edge U facing the electric motor (1) of the rotating body A (2)
13 = circumferential edge V facing the generator (53) of the rotating body A (2)
14 = Rubber magnet W
15 = N pole X on the surface where the rubber magnet W (14) faces the arcuate cage (5)
16 = Permanent magnet Y on arcuate cage (5)
17 = N pole Z on the surface of the permanent magnet Y (16) facing the rotating body A (2))
19 = pressure M1 between a number of fine holes (4) and the bottom (3) of the rotating body A (2)
20 = Atmospheric pressure M0
21 = Pressure M on the bottom surface of the bottom (3) of the rotating body A (2) M
22 = area L of the bottom (3) of the rotating body A (2) blocking many fine holes (4)
23 = blower 25 = hose 26 connected from the blower (23) to the arc-shaped bowl (5) = concentric ring A provided at the center of the longitudinal diameter of the rotating body A
27 = Electromagnet A
28 = Stator A
29 = Rotor A
30 = Magnet B magnetized concentrically in the axial direction around the axis
31 = Programmable controller A
32 = Controller A
33 = Driver A
34 = Center point G of rotating body A (2)
35 = perpendicular line H drawn from the center point G (34) of the rotating body A (2) to the circumferential edge of the rotating body A (2)
36 = tangent line I perpendicular to perpendicular H (35)
37 = circumferential edge J of rotating body A (2)
38 = Round circumference K of rotating body A (2)
52 = Rotating shaft 53 connecting the rotating body A (2) and the generator 53 = Generator

Claims (5)

A rotating body A (2) is provided between the electric motor (1) and the generator (53), and is connected to the rotating shaft of the electric motor (1). Is provided with an arc-shaped ridge (5) having a number of fine holes (4),
A rubber magnet Q (8) is provided in the middle of the vertical height of the circumferential edge of the rotating body A (2) and in the longitudinal direction of the rotating body A (2). The rubber magnet Q (8) A permanent magnet S (10) is installed facing the rubber magnet Q (8) on the arc-shaped ridge (5) facing the
A rubber magnet W (14) is located in the middle of the circumferential edge between the rubber magnet Q (8) of the rotating body A (2) and the bottom of the rotating body A (2) and in the longitudinal direction of the rotating body A (2). Rotating in an apparatus in which a permanent magnet Y (16) is installed on an arcuate cage (5) facing the rubber magnet W (14) and facing the rubber magnet W (14). Air coming out from a number of fine holes (4) of the arc-shaped ridge (5) provided facing the "predetermined range" of the bottom (3) of the body A (2) is the rotating body. It has a function of floating the bottom part (3) of A (2), and the rotating body A (2) rotates with a zero frictional resistance within a predetermined rotation range without contacting the arc-shaped ridge (5). A power generator characterized by that. The function of the air coming out of the numerous fine holes (4) to float the bottom (3) of the rotating body A (2) is that the atmospheric pressure is M0 (20), the numerous fine holes (4) The pressure between the bottom part (3) of the rotating body A (2) is the pressure M1 (19), the pressure in the arc-shaped ridge (5) is the pressure M (21), and the arc-shaped ridge ( 5) The air is continuously being injected from the blower (23), and the "predetermined range" of the bottom (3) of the rotating body A (2) faces the "predetermined range". When the fine hole (4) is closed, the pressure M1 (19) is increased to about the pressure M (21) from the “Bernoulli theorem”, and the pressure M1 (19) increases gradually as the pressure M (21) gradually increases. When the surface area of the “predetermined range” of the bottom (3) of the rotating body A (2) closing the numerous fine holes (4) is L (22), (M−M0) × L The pressure M1 (19) becomes larger than the force, and acts on the “predetermined range” of the bottom (3) of the rotating body A (2) from below the rotating body A (2), and the bottom of the rotating body A (2) ( 3. The method according to claim 1, wherein 3) is "floating" and said "floating" "floats" to a position that balances with gravity acting downward on the bottom (3) of rotating body A (2). Power generation device. A total station combining an electronic theodolite and a light wave distance meter is provided, and when the "floating" is performed to the position that balances the gravity working downward on the bottom (3) of the rotating body A (2) according to claim 2, the rotating body Between the “predetermined range” of the bottom part (3) of A (2) and the many predetermined holes (4) facing the “predetermined range” of the bottom part (3) of the rotating body A (2) Pressure M1 (19) is slightly lower than the pressure M (21) in the arc-shaped bowl (5), and when the bottom (3) of the rotating body A (2) begins to drop, ), The number of rotations of the blower (23) is increased, and the amount of air blown through the hose (25) = the amount of air is blown to the arc-shaped cage (5), and a large number of fine holes (4) And the “predetermined range” at the bottom (3) of the rotating body A (2) is maintained at a predetermined distance. Power generating device according to claim 2, characterized in that it is. A line passing through the center point G (34) of the cross section of the rotating body A (2) parallel to the tangent I (36) drawn horizontally at the bottom (3) of the cross section of the rotating body A (2) The circumferential edge P facing the generator (53) from the circumferential edge O (6) facing the electric motor (1) of the rotating body A (2) intersecting with the circumferential edge of the rotating body A (2). The rubber magnet Q (8) is provided by (7), and the magnetic pole with the rubber magnet Q (8) facing the arcuate ridge (5) is the N pole R (9),
A permanent magnet S (10) is placed on the arcuate ridge (5) facing the portion from the circumferential edge O (6) to the circumferential edge P (7), and the permanent magnet S (10) The magnetic pole facing the rotator A (2) is the N pole T (11). When the rotator A (2) approaches the arcuate ridge (5), the N pole R (9) and the N pole T (11) is repelled, and the rotating body A (2) is pushed back within a predetermined rotation range, so that the rotating body A (2) and the arcuate hook (5) do not come into contact with each other. The power generation device according to claim 1, wherein A rubber magnet W (14) rotates in the longitudinal direction of the rotating body A (2) around the circumference of the rotating body A (2), which is an intermediate between the rubber magnet Q (8) and the bottom of the rotating body A (2). It is provided from the circumferential edge U (12) facing the electric motor (1) of the body A (2) to the circumferential edge V (13) facing the generator (53), and the rubber magnet W ( 14) is an N pole X (15) facing the arcuate cage (5), and a generator (53) is formed from a circular periphery U (12) facing the electric motor ((1)). The permanent magnet Y (16) is installed on the arcuate ridge (5) facing the portion up to the circular peripheral edge V (13) facing the outer periphery V), and the permanent magnet Y (16) is the rotating body A. The magnetic pole facing (2) is the N pole Z (17). When the rotating body A (2) approaches the arcuate cage (5), the N pole X (15 ) And the N pole Z (17) are repelled, and the rotating body A (2) is pushed back within a predetermined rotation range, and the rotating body A (2) and the arcuate hook (5) are in contact with each other. The power generation device according to claim 1, wherein the power generation device is not provided.

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