JP2019132263A - Energy-saving power device - Google Patents

Abstract

To provide an energy-saving power device having minimized energy consumption in order to solve such a problem that the conventional power device requires a large amount of energy.SOLUTION: An energy-saving power device is characterized in that a universal joint is provided on a center shaft upper part, a center shaft moving disc provided with a magnet attracting iron-core is provided on an upper part thereof, electromagnets are provided on right and left of the center shaft moving disc and the universal joint is provided on a center shaft lower part, a bob-attaching metal fitting to which a bob is attached is provided near the shaft center of the universal joint substantially at right angle, an electrode plate is provided on the center shaft below a lower part universal joint, electrode terminals are provided on right and left of the electrode plate, an electrode terminal lift-up pendulum is provided, a terminal lift-up disc is provided and the electrode terminal is hung down on the terminal lift-up disc, a flywheel is provided on an electrode plate lower part and an outputting gear is provided thereunder, and a bearing is provided on the lowermost part.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an energy-saving power device having a structure in which a weight is fixed to a central shaft installed vertically, a drop force due to the pulling force of the weight is converted into rotation of the central shaft, and the rotational force is smoothly extracted.

  Conventional power devices could not be operated unless large energy such as nuclear power, oil, coal, and a large amount of water was used as a power source from the outside. Currently, solar power generation devices and wind power generation devices are beginning to spread, but there are other questions about whether new energy-saving power devices can be created.

This has the following drawbacks.
(B) Large hydropower, electric power, and nuclear energy are required for high output.
(B) Nuclear power and large amounts of fossil fuels are required for large-scale motors.
(C) Solar power generation requires a large area of land and a large number of panels.
(D) No power is derived from the self-rotating mechanism. Although we experimented for many years, we did not continue the movement by ourselves and we could not extract it as power.
(E) A large force was required to move the central axis for lifting the weight.
(F) It was not easy to extract a smooth rotational force from the rotating shaft that sways from side to side.
The present invention has been made to eliminate the above drawbacks.

(B) In order to utilize the drop force due to the pulling force of the weight, the weight is fixed to the central axis with a weight mounting bracket, and the central axis is tilted to the opposite side of the weight to generate the rotational movement of the central axis.
(B) To move the upper part of the central axis to the left and right, it is sufficient to have a force to attract the magnetic iron core attached to the central axis moving board, and only a small amount of power introduced from the outside is required.
(C) To cause rotation of the central shaft, attach a weight to the tip of the weight mounting bracket fixed to the central shaft, and convert the falling force of the weight to rotational force.
(D) Provide a universal joint at the connection with the flywheel below the center shaft. While the upper part of the central axis rotates, it swings only to the left and right, but the lower part of the central axis rotates while slightly swinging. This rotational force is smoothly transmitted to the flywheel and taken out as power.
(E) The weight mounting bracket should be mounted at or slightly below the center point of the lower universal joint. The lever principle makes it easy to move the central axis to lift the weight.
(F) If the central axis is lengthened, the movement can be further reduced by the lever principle.
(G) When the weight is heavy, it rotates faster.
The present invention is an energy saving power device having the above-described configuration.

(B) Since the lever can be moved and the weight can be lifted lightly by the lever principle, it can be operated with a small amount of electric power, and power can be obtained with energy saving.
(B) The structure is simple and a power device of any size can be easily made.
(C) It can be operated continuously and can also be used as power for generators for in-vehicle charging.
(D) The rotational force can be changed by changing the weight of the weight.

  It is a top view of the present invention.   It is a front view of the present invention.   It is a side view of the present invention.   It is a perspective view of the present invention.   It is an operation | movement diagram of this invention.   It is an electrode plate enlarged view of the present invention.

Hereinafter, modes for carrying out the present invention will be described.
Mount the universal joint (8) on the upper part of the central shaft (7). A central axis moving board (2) with a magnet attracting iron core (3) is attached to the upper part of the universal joint.
Attach electromagnets (1) to the left and right of the central axis moving board.
Attach the universal joint (8) to the lower part of the central shaft (7). A weight mounting bracket (6) with a weight at the center of the universal joint or slightly below is attached at a substantially right angle.
Attach the electrode plate (9) to the central axis under the lower universal joint. Electrode terminals (10) are provided on the left and right sides of the electrode plate (9) and installed so as to be in contact with the electrode plate.
As the rotational speed increases, an electrode terminal lifting pendulum (14) that rises by centrifugal force is attached, and the terminal lifting disk (15) is connected.
An electrode terminal (10) is suspended from the terminal lifting disk, and moves up and down corresponding to the upper and lower sides of the disk and contacts the electrode.
A flywheel (4) is attached to the lower part of the electrode plate, and a gear connected to the output shaft (12) is installed thereunder.
Install the bearing (13) at the bottom.
The present invention has the above structure.
When using this, the electrode terminal connected to the electromagnet I is in contact with the electrode plate below the central axis, the current is sent to the electromagnet I, and the iron core for the magnet attached to the central axis moving board by the electromagnet I is the electromagnet. It is attracted to the I side.
For this reason, the weight is at the uppermost portion (1), but when moving downward from this position by gravity, it moves clockwise to the position of the lowermost portion (2) while rotating the central axis around the central axis.
When the weight moves to the position of the lowest part (2), the electrode terminal connected to the electromagnet II comes into contact with the electrode plate below the central axis, the current flows to the electromagnet II, and the central axis moving board is quickly moved by the magnet II. By pulling toward the electromagnet II side, the weight moves from the position (2) to the position (3).
Then, the weight tries to move to the position (4). This operation is repeated to continuously generate the rotational force.
To operate the electromagnet, an electrode plate is attached to the lower part of the central axis. The electrode plate keeps the current flowing from the contact terminal to the electromagnet I while the weight moves from {1} to {circle around (2)} so that the central axis does not return to the electromagnet II side due to the weight of the weight. Do the same for the II side.
When the rotation is started, the rotation speed is increased by gradually moving the central axis to the opposite side earlier, so that the electrode terminal is gradually pulled up by the rotating centrifugal force. Therefore, the electrode terminal lifting pendulum (14) and the terminal lifting disk (15) is provided. Attach it so that it can be energized little by little.
The electrode plate (9) is a parallelogram, and the length of the top and bottom sides is the length of the half circumference of the electrode mounting shaft.

DESCRIPTION OF SYMBOLS 1 Electromagnet 2 Center axis moving board 3 Magnet attracting iron core 4 Handwheel 5 Weight 6 Weight mounting bracket 7 Center shaft 8 Universal joint 9 Electrode plate 10 Electrode terminal 11 Electrode terminal support 12 Output shaft 13 Bearing 14 Electrode terminal lifting pendulum 15 Terminal lifting disk

Claims (1)

A universal joint is provided at the upper and lower parts of the central axis. A central axis moving board with a magnetic iron core is provided on the upper universal joint. Electromagnets are provided on the left and right sides of the central axis moving board. In addition, a weight mounting bracket with a weight with low air resistance is installed so that it is almost perpendicular to the central axis. An electrode plate with one side of the parallelogram is half on the lower axis of the lower universal joint. An electrode terminal lifting pendulum is provided. An electrode terminal lifting disk is connected under the electrode terminal lifting pendulum. An electrode terminal hanging bracket is provided so as to slide on the outer periphery of the electrode terminal lifting disk, and the electrode plate is in contact therewith. The electrode terminal support that holds the electrode terminal is provided on the left and right. The flywheel is provided at the lower part of the center shaft. The gear is installed at the lower part of the flywheel, the output shaft is provided, and the bearing that supports the center shaft is provided at the bottom. An energy-saving power unit.

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