JP2019075968A - Rotor by permanent magnet adopting turbine method - Google Patents

Abstract

To eliminate defects such as magnetic force being weak for rotating a rotary body, a magnet being uneasy to move, and inability of maintaining a magnetic force continuously.SOLUTION: In the structure, a plurality of discs 2 and a control disc 5 are incorporated in a rotary shaft 1, each disc has a structure with a plurality of magnets attached to its periphery, and a lever device 4 is installed at an intermediate position of the disc from the stationary body side. The lever device is so configured that a magnet corresponding to a magnet with a disc is attached to one of the levers and a lever to which a connecting rod 7 fixed piece for connecting the other lever is incorporated in a rotary bearing stand 3. In the device, to move the lever axially, for the purpose of moving the lever to the periphery of a controlling disc, a curved rail of corrugated is provided, and a control roller device 6 which moves axially along the rails is employed.SELECTED DRAWING: Figure 1

Description

The present invention is that the magnetic force is enhanced by the recent innovation of permanent magnets. From this point of view, the present invention relates to a rotating body having a turbine type structure different from the conventional motor structure in which permanent magnets are applied to both the rotor and the stator. The rotating body has a plurality of disks incorporated at equal intervals on the rotation shaft, and a plurality of magnets are attached around the disks. On the other hand, on the stationary body side, a lever device is disposed at an intermediate position of the disc. One of the levers of this device is fitted with a magnet corresponding to the magnet of the disc. On the other side, a connecting rod fixing piece is attached to fix the connecting rod for moving the lever in the axial direction. By moving the lever, the magnet with the lever approaches the magnet with the disc and rotates the disc by repelling each other.
In the mechanism for moving the lever, in order to move the lever to the rotation shaft separately from the disk, a control disk having a larger diameter than the disk is incorporated, and a rail is provided around this. The rail shape is a wavy curve whose width is equal to the distance of movement of the lever, and the wavy curve is such as to draw peaks and valleys between the widths. Each lever is connected to the connecting rod via a connecting rod fixing piece so that the lever can be moved simultaneously in the same direction. At a circumferential fixed position of this rail, a control roller device having wheels moving along the rail is installed. By connecting the end of the connecting rod to the control roller device, the rail rotates due to the rotation of the disc, and the control roller device reciprocates in the axial direction. The movement causes the magnet with lever to move closer to the magnet with disc by pushing and pulling the connecting rod, and relates to a rotating body that repels each other and rotates.

  One of the rotating bodies currently employed is a permanent magnet, and the other is an electromagnet. A rotating body in which both are permanent magnets has not been put to practical use.

  nothing special

In order to rotate the rotating body using the rotating body, the stationary body, and the mutually attached permanent magnets, there are the following defects and can not be used.
1) The magnetic force is weak.
2) The movement of the magnet is not easy.
3) Magnetic force can not be maintained continuously.

The present invention solves the above-mentioned subject by the following way of thinking.
In this specification, the number of magnets attached to the disk will be described as four for easy understanding.
As the magnetic force of the magnet is strong, use the repulsive force of this magnetic force. In order to further increase the repulsive force, four magnets are installed at equal angles of 90 degrees around the disc of the rotating body. A plurality of such disks are incorporated into the rotation shaft at equal intervals. The lever device is installed at the intermediate position from the stationary body side. The device incorporates a lever bearing block and a lever, and the lever is provided with a magnet on one side and a connecting rod fixing piece for connecting the lever to the connecting rod on the other.
The movement of the magnet is performed by the levered magnet on the stationary body side. To do so, using the connecting rod fixing piece of each lever, connect the connecting rods with the connecting rods on the circumference of the control disc. Bond to a control roller device that moves along a corrugated curvilinear rail attached to the. The rotation of the disc causes the control roller device to move axially along the rails of the control disc and pull or push the connecting rod to move the lever in the axial direction. Each levered magnet approaches the magnet of the disc and rotational movement continues continuously.
The present invention, like the conventional motor, utilizes the repulsive force, but exerts the repulsive force on the side surface of the disc which is the rotor. Is established by
The component device comprises a control roller device 6 which is moved by the rotation of the disc 2 of the rotating body, the control disc 5, the lever device 4 on the stationary body side, and the rails 13 of the control disc 5.
In the rotating body, a plurality of disks 2 and a control disk 5 are incorporated in the rotating shaft 1. The rotary shaft 1 is supported by a rotary bearing stand 3. A disc attached magnet 8 is attached around the disc 2. Rails 13 are attached to the circumference of the control disk 5, and the swing width of the rails is a moving distance of the lever 9 and has a wavy curve. When four magnets are adopted, the rail 13 is curved so that the right end (peak) at the 0 degree position, the center at the 90 degree and 270 degree positions, and the left end (valley) at the 180 degree position . On the rail 13, a control roller device 6 moving along the rail 13 is provided. This device is incorporated into the fixed slide base 14 and slide base 14 at four points (0 degree, 90 degree, 180 degree and 270 degree positions) along the axially moving base plate 15 and the rail 13 A moving rail guide wheel 16 is provided. By the rotational movement, it moves along the rail 13 in the axial direction.
The lever device 4 on the stationary body side is provided with a lever 9 and a magnet 10 with a lever attached to one of them, and a connecting rod fixing piece 11 for fixing a connecting rod 7 for moving the lever 9 on the other. ing. Since the connecting rod 7 is joined to the control roller device 6, when rotation occurs, the control roller device 6 moves in the axial direction to push or pull the connecting rod 7. The levered magnets 10 repel each other as they approach the disked magnets 8 of the disk 2 and the rotating body rotates.
With such a mechanism, when the rotary body is rotated by the auxiliary engine at the time of start-up, the magnet 8 with a disc and the magnet 10 with a lever come closer, and they rotate by repelling each other. .

As described above, according to the present invention, the rotating body is rotated by the repulsive force of the magnet attached to the periphery of the plurality of disks of the rotating body and the magnet attached to the lever of the lever device installed at the midpoint between the disks. It is. By moving the lever, each other's magnets come close, repel and rotate. To move the lever, attach a corrugated curvilinear rail to the circumference of the control disk and install a control roller device that moves along the curve of the rail, and use the control roller device and the lever device lever. By joining the connecting rods connected to the connecting fixed piece, the control roller device moves in the axial direction along the rails by the rotation of the rotating body, and the connecting rods push and pull the lever. A magnet with a lever will approach a magnet with a disc. The discs rotate due to the repulsive force of the mutual magnets. The realization of a rotating body that uses the corresponding repulsive force of permanent magnets in this way is very useful for Japan, which relies on fuel overseas. At the same time, it can contribute to the people of the world by supplying it to developing countries in the world. Furthermore, the utility pole that is harming the landscape of Japan is no longer required, and the landscape is improved.
Although the output of this engine is small, in order to increase the output, it is conceivable to increase the number of disks of the device, to connect in parallel, to increase the size, and the like. By doing so, it can also be used as an engine such as a home generator, a car, or a leisure boat. Further increase in size will lead to large ships, small power plants and so on.
At the same time, there is nothing to discharge from the environment, which can contribute to global warming.

It is a side view of the rotating body of the present invention. It is a front view of the rotating body of the present invention. Fig. 2 shows a disc according to the invention. It is a lever device of the present invention. The front view and sectional drawing of a control disc of this invention, and a rail are shown. It shows a control roller device of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a side view of the rotating body.
The side view shows the rotary shaft 1, the plurality of disks 2, the control disk 5, the control roller device 6, the rotary bearing stand 3, the lever device 4, and the connecting rod 7.
FIG. 2 shows a front view of the rotating body.
FIG. 3 shows the disc 2. It is incorporated in the rotating shaft 1 and is equipped with a disk-mounted magnet 8 at its periphery.
FIG. 4 shows the lever device 4. The lever bearing base 12 is attached to the stationary body, the lever 9, the magnet with lever 10 to one side, the connecting rod fixing piece 11 to the other, and the connecting rod 7 is connected. The end of the connecting rod 7 is joined to the control roller device 6.
FIG. 5 shows a control disk 5 for moving the lever 9 of the lever device 4, and a cross section of the rail 13 attached to the periphery thereof and the rail at 0 degree, 90 degrees, 180 degrees and 270 degrees.
FIG. 6 shows the control roller assembly 6 moving along the rail 13. The slide base 14 is fixed, and the base plate 15 moves in it. The end of the connecting rod 7 connected to the connecting rod fixing piece 11 of the lever 9 is joined to the base plate 15. There is a rail guide wheel 16 incorporated in the base plate 15 and moves along the rail 13. When the control disk 4 rotates, this device moves along the rails 13 so that the base plate 15 of the control roller device 6 reciprocates in the axial direction.

Reference Signs List 1 rotation shaft 2 disc 3 rotation bearing stand 4 lever device 5 control disc 6 control roller device 7 connecting rod 8 magnet with disc 9 lever 10 magnet with lever 11 connecting rod fixing piece 12 lever bearing stand 13 rail 14 slide Base 15 Base plate 16 Rail guide wheel

Claims (1)

A plurality of disks are incorporated into the rotation shaft at equal intervals, and a plurality of magnets are attached at equal angles around the disks. The magnets corresponding to the magnets are attached to one of the levers incorporated in the lever device on the stationary body side. The levers are located at a central position between the discs. That is, it is in a position to balance with the magnetic force of the magnets of the front and rear disks.
The other of the levers is fitted with a connecting rod fixing piece and connected to the connecting rod. The end of the connecting rod is joined to the control roller device. The lever is reciprocated in the direction of the rotation axis by the movement of the control roller device via the connecting rod, whereby the magnet with the lever is brought close to the magnets of the front and rear disks. Thereby, a repulsive force is generated between corresponding magnets.
In order to move the lever, a control disc larger in diameter than the disc is incorporated in the rotary shaft, and a rail is provided on the circumference. If there are four magnets on the disc, the rail is curved right at the 0 degree position of the circle, at the center at the 90 degree position and at the 270 degree position, and to the right at the 180 degree position. The swinging distance of the lever is equal to the movement distance of the lever. The control roller device incorporates a base plate on a slide fixed to a stationary body so as to move in an axial direction. A device that moves along a curve of a rail by a rail guide wheel incorporated in the base plate, and when the control disk rotates by rotation of a rotating body, the base plate of the control roller device axially reciprocates It is a mechanism. The lever can be moved axially by pulling or pushing the connecting rod of the lever.
The rotating body is rotated by the auxiliary engine at the time of start-up. When rotation starts, the base plate of the control roller device axially reciprocates along the rails attached to the control disc to push and pull the connected lever, thereby attaching the lever. A rotating body that generates a repulsive force and rotates by keeping the magnet close to a disked magnet, and keeps the rotation.

Images