JPH0417585A - Dynamic device - Google Patents

Abstract

PURPOSE: To generate electric energy easily and continuously in safety by turning a rotator continuously through the repelling force of a magnet and generating power through the rotating power thereof. CONSTITUTION: When rotator 26 turns to pass over a rolling magnet 40, rotation of a shaft 20 is detected through a relay switch 68 and air supply to a pump 56 is controlled. Consequently, the piston of the pump 56 is driven and the linear reciprocal motion thereof is transmitted to a rod 54 which rolls each magnet 40 at a predetermined angle. When two magnets in the rolling magnet 40 repeats reciprocal rolling motion every time when the rotator 26 turns one fifth of a revolution, the rotator 26 continues clockwise rotation. A generator is driven through the continuous rotational motion of the rotator 26 to generate power which is stored in a battery 66.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a power generation device that converts magnetic force into mechanical motion and extracts it as electrical energy.

(Conventional technology) Many conventional power generation devices consume fossil fuels and convert them into electric energy, but their energy conversion efficiency is low, and the earth's resources are limited, and they cause problems such as air pollution. When considering the negative impact of electricity on the environment, conventional power generation devices are not necessarily sufficient as a means of generating electrical energy (and are not desirable in terms of industrial development either).

(Problems to be Solved by the Invention) The present invention has been made in view of the above points, and it is possible to easily and safely obtain electrical energy continuously by using the energy inherent in permanent magnets. The aim is to provide a power generation device that can.

(Means for Solving the Problems) According to the present invention, there is provided a rotating body in which a plurality of magnets are arranged at equal intervals on the outer periphery, and the rotating body is rotated by magnetic repulsion to each magnet of the rotating body. A driving means for driving, a power generation means for generating power by the rotational force of the rotating body, a power storage means for storing the power generated by the power generation means, and a power storage means for storing the power generated by the power generation means, and the energy stored in the power storage means is used to generate the power. It is possible to provide a power generation device characterized by comprising a control means for controlling the drive means in synchronization with the rotation timing of the rotating body.

(Function) In the power generating device of the present invention, the rotating body is continuously rotated by the repulsive force of the magnet, and the rotating force generates electricity, thereby accumulating the generated energy.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a plan view showing the main parts of the mechanical configuration centering on the rotating body of the power generation device of the present invention, and
A cross section taken along line I is shown in FIG. The upper and lower frames 1O112 are both made of steel, intersect at 90° in the center, and support the device installed on the floor 14.

The four legs of the lower frame 10 are fixed to the floor 14 by bolts via the base member 16. At the center portion of this frame IO, a bearing 1 is rotatably mounted.
A shaft 20 carried by 8 is vertically supported on the base member 22, and a rotating body 26 is defined by a plurality of spokes 24 extending laterally from the shaft 20. Each spoke 24 of this rotary body 26 consists of two upper and lower spokes 24a and 24b, the tips of which are located at equal intervals on the outer periphery of the rotary body. those spokes 24
A housing 27 holding a magnet 28 inside is attached to the tip of each housing, and between these housings,
As clearly shown in Figure 1, the outside is circular and the inside is 5.
They are connected by a square flywheel 29. This flywheel 29 is for maintaining the rotation of the rotating body 26 and ensuring efficient power generation.

The originating side 10 is installed on the lower frame lO that supports the rotating body 26, and the belt 32 is mounted on the upper frame 12.
．． A rotational force transmission mechanism is also provided consisting of a pulley 34 and a pulley 36,38. That is, the rotational force of the rotating body 26 is first transmitted to the first pulley 36 directly connected to the shaft 20, then transmitted to the second pulley 38 via the belt 32, and from there to the generator 30 by the belt 34. Reportedly.

FIG. 3 shows the arrangement of rocking magnets that swing in response to the magnets that rotate together with the rotary body 26 on the floor 14 on which the frame 10 that supports the rotary body 26 is installed, and the arrangement of the rocking magnets. FIG. 4 also shows the arrangement of magnets that rotate together with the rotating body 26. Each oscillating magnet 40 is
As shown in the side view in FIG. 5, a horizontal plate 44 is rotatably supported by a pivot on a base member 42 fixed to the floor 14, and a horizontal plate 44 is held at a predetermined interval. It consists of a set of two magnets 46 and 48 arranged. A cam member 50 that rotates in synchronization with the shaft 20 is provided on the shaft 20 of the rotating body 26, and this cam member 50
, divide the outer circumference into 10 equal parts, and divide every other 5
A protrusion 51 is formed in one portion. This cam member 5
The circular hub 52 supporting the rotating body 2 from below is
The hub 52 rotates independently of the shaft 20 of the hub 52, and five locations on the outer circumference of the hub 52 are connected to the oscillating magnet 4, respectively.
A rod 54 is rotatably connected to one end of the horizontal plate 44 of 0, and a hub 5 is further connected to the rod 54 to control the oscillating magnets 40 to determine the rotational speed of the rotating body 26.
2 is connected to the piston shaft of the pump 56.

The pump 56 is connected by two pipes 58, 60 to an air cylinder 62, which is suitably supplied with compressed air from a compressor 64. The compressor 64 is connected to a battery 66 and
It is operated by receiving N source supply from 6.

A relay switch 68 operated by the cam member 50 is also connected to the battery 66 so as to synchronize the timing of the swinging of the swinging magnet 40 by the pump 56 and the rotation of the rotating body 26.

Inside each housing 27 of the rotating body 26 shown in FIG. 4, there are a pair of permanent magnets 282 and 284 facing each other from above and below at a predetermined interval on the outer circumferential side of the rotating body, and a pair of permanent magnets 282 and 284 on the inner circumferential side of the rotating body. An auxiliary magnet 286 having a polarity different from that of the permanent magnets 282 and 284 and facing the swinging magnet 40 from above is provided. The polarity of these magnets is the same as that of the oscillating magnet 40.
5 as a rotating magnet to exert a repulsive force between
In the case located at the apex of the rectangle, the magnet on the outer circumference side is set to the same polarity as the swinging magnet 40, and in the case located in the middle of the sides of the pentagon, the auxiliary magnet on the inner circumference side is set to the same polarity as the swinging magnet 40. The polarity is set to be the same as that of 40. As the rotating body 25 rotates, a repulsive force acts between the oscillating magnet 40 and the rotating magnet shown in FIG. 5, and this repulsive force acts as a force to further rotate the rotating body 26 in a fixed direction. , the interval between the rotating magnets and the length of the horizontal plate 44 of the oscillating magnet 40 are adjusted.

Figures 6 (A) and (B) show the rotating body 2 rotating clockwise.
The timing of the swinging of the 60-rotation magnets #1, #2, #3 and the swinging magnet 40 fixed to the floor surface 14 is shown. When the rotating body 26 rotates, the swinging magnet 40 is located at the position shown in FIG. 6(A) and rotates counterclockwise.
A repulsive force acts between rotating magnets #1 and #2, and this repulsive force acts as a force to rotate the rotating body 26 clockwise to the state shown in Fig. 6 (B), and then swings at this position. When the magnet 40 rotates clockwise, a force that further rotates the rotating body 26 clockwise acts on rotating magnets #2 and #3.

Next, the operation of the embodiment apparatus having the above configuration will be explained.

When the rotating body 26 rotates and passes over the swinging magnet 40, the rotation of the shaft 20 is detected by the relay switch 68, and the timing at which the swinging magnet 40 is reversed is determined. That is, the detection signal of the relay switch 68 is turned on and off by the cam member 50, thereby controlling the supply of air to the pump 56. Therefore, the piston of the pump 56 is driven, and its reciprocating linear motion is transmitted to the rod 54, causing each swing magnet 40 to swing at a predetermined angle. 6th
As shown in the figure, two magnets of the oscillating magnet 40 are connected to the rotating body 2.
The rotating body 26 continues to rotate clockwise by repeating one reciprocating rocking motion during one-fifth of a rotation.

This continuous rotational movement of the rotating body 26 is transmitted via the shaft 20 to a boot and belt mechanism, which drives a generator 30. The power generated by the generator 30 is immediately stored in the battery 66,
A part of it is used as air compression force in the compressor 64.

(Effects of the Invention) As explained above, according to the present invention, the rotating body is continuously rotated by the repulsive force of the magnet, and the power generation action is performed by the rotational force, so that the rotating body can be easily and safely continuously rotated. It is possible to provide a power generation device that can obtain electrical energy by

[Brief explanation of the drawing]

FIG. 1 is a plan view showing the main parts of the power generation device of the present invention;
Figure 2 is a diagram showing a cross section along the line ■-■ in Figure 1;
The figure is a plan view showing the arrangement of the oscillating magnets and the drive mechanism for the oscillating magnets, FIG. 4 is a side view showing the arrangement of the magnets on the outer periphery of the rotating body, and FIG. 5 is a side view of the oscillating magnets. 6(A) and 6(CB) are diagrams showing the timing of the rotation of the rotating magnet of the rotating body and the swinging of the swinging magnet fixed to the floor surface. 1O112... Frame body, 14... Floor surface, 20... Shaft, 24... Spoke, 26... Rotating body, 28...
Magnet, 30... Generator, 40... Oscillating magnet, 50.
...Cam member, 56...Pump, 64...Compressor, 66...Battery, 68...Relay switch. Patent applicant George Nis Tokunaga agent Patent attorney Minoru Tsuji

Claims (6)

[Claims] (1) A rotating body in which a plurality of magnets are arranged at equal intervals on the outer periphery, a driving means for rotationally driving the rotating body by magnetic repulsive force against each magnet of the rotating body, and a rotational force of the rotating body. a power generation means that generates electricity by the power generation means; a power storage means that stores the power generated by the power generation means; and a drive means that synchronizes with the rotation timing of the rotating body using the energy stored in the power storage means. A power generation device characterized by comprising a control means for controlling. (2) The power generating device according to claim 1, wherein the rotating body is composed of a plurality of spokes and permanent magnets arranged at the tip portions of these spokes. (3) The driving means for the rotating body includes a pump that initially drives the rotating body, a converting unit that converts the reciprocating linear motion of the pump into a reciprocating rotational motion at a predetermined angle, and a converting unit that is coupled to the converting means to rotate the rotating body. 2. The power generating device according to claim 1, further comprising a swinging magnet that is fixedly arranged with respect to the magnets of the body and acts repulsively with each of these magnets. (4) The oscillating magnets are disposed on the outer periphery of a plurality of second rotating bodies supported by shafts fixed to the rotating bodies, and each of the oscillating magnets is arranged in synchronization with the reciprocating rotational movement by the converting means. 4. The power generating device according to claim 3, wherein the power generating device acts on a magnet of a rotating body. (5) The driving means for the rotating body includes an air compressor;
4. The power generating device according to claim 3, further comprising a tank for accumulating compressed air produced by the air compressor, and the compressed air is appropriately supplied to the pump. (6) The control means for controlling the drive means includes a cam means for setting the timing of reciprocating linear movement of the pump;
4. The power generating apparatus according to claim 3, further comprising a relay means which is turned on and off by the cam means.