JP3170852U - Rotation moment generator with flywheel - Google Patents

Abstract

A rotational moment power generator with a flywheel capable of stably and smoothly rotating without unevenness is provided. A rotary moment power generation device with a flywheel includes a pair of vertical ring rails 100, a rotary drive shaft 200, a flywheel F having first weights 400 mounted on both sides of a vertical turning shaft 300, and the like. A pair of second weights 500 are supported by a parallel shaft 600, a longitudinal turning shaft 300, and a ring rail 100, and a rotational moment generating mechanism M that rotates eccentrically by the rotation of the rotary drive shaft 200. A pair of perfect ring rails 100, a flywheel F, and a rotational moment generating mechanism M are arranged in parallel on the rotary drive shaft 200, and the relative relationship of the longitudinal turning shaft 300 between each pair is 22.5. Degree. The rotary drive shaft 200 is arranged such that the shaft center 200C is orthogonally placed at an arbitrary position on the horizontal radius line 100r from the circle center 100C of the ring rail 100, the region of each set unit is supported by a bearing, and one end portion is a water turbine. Or it connects with the rotational drive side of a windmill, and connects an other end part with an electric power generating apparatus. [Selection] Figure 1

Description

  The present invention relates to a rotary moment power generator with a simple flywheel that efficiently generates power by hydropower, wind power, and a micro-motor.

Power generation devices are roughly classified as conventionally known ones, and various large-scale power generation devices such as wind power generation devices, steam power generation devices, hydroelectric power generation devices, wave power generation devices, and solar power generation devices have been developed. In recent years, the global warming problem has surfaced, and carbon dioxide emission regulations have been exclaimed. As a clean energy technology to cope with this, the above-mentioned solar cells, wind power generation and the like have been noticed and developed and are currently in operation, but the current situation is that they are not widely used due to problems such as cost and maintenance.
Therefore, recently, a simple power generation apparatus that efficiently generates power by using hydropower, wind power, and a minute electric motor has been developed. This is a device that utilizes gravity on the earth and efficiently converts it into rotational energy for power generation.

This is an eccentric rotary type that uses a motive power for the rotating drive shaft that generates and rotates as the initial dynamic power, wind power, steam power, hydraulic power, wave power, etc., and greatly improves the efficiency of converting electric energy from these natural power sources. It is a power generation device.
This eccentric rotary power generator is equipped with a vertical ring rail, and a weight via a vertical turning shaft is provided on a rotary drive shaft that is eccentric in the horizontal direction from the ring circle, and this weight runs along the ring rail. Thus, a rotational moment is applied to the rotation shaft, and the rotation drive shaft is rotated using, for example, hydraulic power as natural power, thereby ensuring efficient power generation with reduced energy loss.

  The present invention greatly improves the rotational moment pattern, eliminates the reverse rotational moment applied to the rotational drive shaft, and stably generates a smooth continuous rotational state without rotational unevenness. A device is provided.

The basic technical configuration of the rotational moment power generator with a flywheel according to the present invention that satisfies the above-described problems is as follows (1).
(1) A pair of vertical ring rails 100 is installed, and a rotary drive shaft 200 is provided in which an axis 200C is orthogonal to an arbitrary position on the horizontal radius line 100r from the center 100C of the ring rail 100, and the rotation is performed. A longitudinally turning shaft 300 that is longitudinally turned by attaching a shaft center part to the drive shaft 200 part is provided, and the turning radius L of the longitudinally turning shaft 300 is rotated from the center of the ring rail to the horizontal radius length L1 of the ring rail. The radius exceeds the total length including the length L2 up to the axis of the drive shaft, and a first weight 400 of equal weight is attached to both ends of the longitudinal turning shaft 300 to form a flywheel F. This longitudinal turning shaft A pair of second weights 500 is movably provided on 300, and the second weights 500 are supported on both ends of two pairs of parallel shafts 600 so that the two pairs of parallel shafts 600 can be moved to the rotational drive shaft 200 parts. The second weight 500 is caused to travel along the ring rail 100 by the rotation of the rotary drive shaft 200, and the second weight 500 is on the side opposite to the rotational drive shaft from the vertical line E passing through the center of the ring rail 100. A positive rotation moment is applied to the rotary drive shaft in the region Z1 located at the position Z2, and the second weight 500 is applied to the rotary drive shaft 200 in the region Z2 located on the rotary drive shaft side from the vertical line E passing through the center of the ring rail 100. A rotational moment generating mechanism M for applying a reverse rotational moment is used, and a plurality of pairs of the ring rail 100, flywheel F, and rotational moment generating mechanism M are arranged in parallel on the rotary drive shaft 200, and a vertical axis between the respective pairs is arranged. A rotational moment power generator with a flywheel, characterized in that the relative angular relationship of the revolving shaft 300 is an equal angle relationship.

  The rotational moment generator with flywheel of the present invention greatly improves and equalizes the rotational moment pattern, eliminates the reverse rotational moment applied to the rotational drive shaft globally, and prevents the rotation unevenness phenomenon to smoothly rotate. The power generation state can be obtained stably.

FIG. 3 shows an embodiment of the present invention, and is an explanatory diagram viewed from the side when eight sets of the components shown in FIG. It is explanatory drawing which shows the detail of the vertical turning shaft 300 part of the horizontal state shown in FIG. 1, (1) is side explanatory drawing from arrow AA of (2), (2) is arrow view of (1). Plan explanatory drawing from BB, (3) is sectional explanatory drawing from arrow CC of (1). It is explanatory drawing which shows the modification which made the ring rail which guides the 2nd weight 500 shown in FIG. 2, and a to-be-guided part a permanent magnet type, (1) is side surface description from the arrow DD of (2). FIGS. 2A and 2B are plan explanatory views from the arrow EE in FIG.

  The mode for carrying out the invention will be described in detail by way of examples.

An example of a rotational moment power generator with a flywheel according to the present invention will be described in detail with reference to FIGS.
1 to 3, a rotational moment power generation device with a flywheel is a flywheel having a pair of vertical ring rails 100, a rotary drive shaft 200, and first weights 400 mounted on both sides of a vertical turning shaft 300. F, and a pair of second weights 500 supported by a parallel shaft 600, a longitudinal turning shaft 300, and a ring rail 100, and a rotational moment generating mechanism M that rotates eccentrically by the rotation of the rotary drive shaft 200.

  A pair of perfect circle ring rails 100, a flywheel F, and a rotational moment generating mechanism M are arranged in parallel on the rotary drive shaft 200, and the relative angular relationship of the longitudinally rotating shaft 300 between each pair is shown in FIG. As shown by overlapping each set, they are arranged at an equal angle of 22.5 degrees.

The ring rail 100 shown in FIG. 1 and FIG. 2 may be a vertical roller guide rail, and the guided member provided on the second weight 500 is mounted on both sides of the second weight 500 and contacts the roller guide rail 100. The roller-type guided 700 is engaged and arranged so as to be able to run in the state.
Further, the ring rail 100 shown in FIG. 3 has two inner and outer rows of concentric magnet guide rails in which permanent magnets 100M are arranged at predetermined intervals in the circumferential direction, and each permanent magnet 100M has, for example, an S pole on the inner peripheral side of the magnet guide rail With the N pole facing outward. The guided to be provided on the second weight 500 with respect to the magnet guide rail 100 is provided on both sides of the second weight 500, and the facing magnetic pole with the permanent magnet 100M is repelled between the inner and outer permanent magnet 100M rows. The rotational resistance is greatly reduced by using a permanent magnet type guided 700M that is inserted and arranged so as to be able to run in a non-contact state.

  The rotary drive shaft 200 is arranged with the shaft center 200C orthogonally crossed at an arbitrary position on the horizontal radius line 100r from the circle center 100C of the ring rail 100, the region of each set unit is supported by a bearing, and one end portion is a water turbine. Or it connects with the rotational drive side of a windmill, and connects an other end part with an electric power generating apparatus.

Two pairs of the vertical turning shafts 300 are arranged in parallel to the extension line of the radius of the rotary drive shaft 200, and the pair is connected and connected in series via a mounting block B fixed to the rotary drive shaft 200 to rotate with the flywheel F. The moment generation mechanism M is shared.
The turning radius L of the longitudinal turning shaft 300 is a radius exceeding the total length obtained by adding the length L2 from the center 100C of the ring rail 100 to the axis 200C of the rotary drive shaft to the horizontal radius length L1 of the ring rail. The flywheel F is constructed by attaching the first weight 400 of equal weight to both ends of the vertical turning shaft 300 with appropriate attachments such as bolts and nuts.
Further, the vertical turning shaft 300 supports the second weight 500 of the rotational moment generating mechanism M at an intermediate portion so as to be movable in parallel with the rotational radius.
The rotational moment generating mechanism M is configured integrally by attaching and fixing a second weight 500 to both ends of a pair of parallel shafts 600 using appropriate attachments such as bolts and nuts. Guide freely.
As a result, the rotation of the rotary drive shaft 200 causes the second weight 500 to travel along the ring rail 100, and the second weight 500 moves from the vertical line E passing through the center 100 </ b> C of the ring rail 100 to the counter-rotation drive shaft side. A positive rotational moment is applied to the axis of the rotary drive shaft 200 in the region Z1 positioned, and the second weight 500 rotates in the region Z2 positioned on the rotary drive shaft side from the vertical line E passing through the circle center 100C of the ring rail 100. A rotational moment generating mechanism M that applies a reverse rotational moment to the drive shaft 200 is configured.

<Modification>
A continuous weight ring as an alternative to the second weight 500 may be mounted.
The first weight 400 may be heavier than the second weight 500 to increase the rotational torque.
Although not shown in the figure, when the magnet guide rail 100 and the permanent magnet guided 700M are installed, each group unit is supplementarily attracted and attracted within the range where the reverse rotation moment is generated in the rotation region of the permanent magnet guided 700M. An acceleration electromagnet array that repeats repulsion may be arranged on the first weight 400 and / or the second weight 500 along the inside and / or outside of the rotation locus, and a permanent magnet may be attached to the weight. In this auxiliary electromagnet array, when the permanent magnet of the weight approaches, the rotation angle sensor or the proximity switch is operated to make the electromagnet attract and accelerate as an attracting action magnetic pole, and at the time of facing, the repulsion action magnetic pole is sequentially switched to repulsion acceleration. It is something to be made.

  Since the present invention has excellent effects as described above, it is possible to easily obtain maintenance-free power generation at low cost as clean energy, and widely spread to various power supply industries as well as general households. It is a power generation device to be used.

E: Vertical line L: Turning radius Z1: Region Z2: Region M: Rotating moment generation mechanism F: Flywheel 100: Ring rail 100M: Permanent magnet 100C: Circular center 100r: Horizontal radius line 200C: Axis center 200: Rotation drive shaft 300: longitudinal turning shaft 400: first weight 500: second weight 600: two pairs of parallel shafts 700: roller-type guided 700M: permanent magnet-type guided

Claims (1)

  A pair of vertical and circular ring rails 100 is installed, and a rotary drive shaft 200 is provided in which an axis 200C is orthogonally crossed at an arbitrary position on the horizontal radius line 100r from the center 100C of the ring rail 100. A vertical turning shaft 300 is provided for turning the shaft by attaching a shaft center portion to the shaft 200, and the turning radius L of the vertical turning shaft 300 is rotated from the center of the ring rail to the horizontal radius length L1 of the ring rail. A radius exceeding the total length including the length L2 up to the axis of the shaft is added, and a first weight 400 of equal weight is attached to both ends of the vertical turning shaft 300 to form a flywheel F. A pair of second weights 500 are movably provided, and the second weights 500 are supported at both ends of two pairs of parallel shafts 600, and the two pairs of parallel shafts 600 are movably supported on the rotary drive shaft 200 part. Then, the second weight 500 is caused to travel along the ring rail 100 by the rotation of the rotary drive shaft 200, and the second weight 500 moves from the vertical line E passing through the center of the ring rail 100 to the counter-rotation drive shaft side. A positive rotational moment is applied to the rotational drive shaft in the region Z1 located, and the second weight 500 is opposite to the rotational drive shaft 200 in the region Z2 located on the rotational drive shaft side from the vertical line E passing through the center of the ring rail 100. A rotational moment generating mechanism M for applying a rotational moment is used, and a plurality of pairs of the ring rail 100, flywheel F, and rotational moment generating mechanism M are arranged in parallel on the rotational drive shaft 200, and the vertical turning between the respective pairs is performed. A rotational moment power generator with a flywheel, characterized in that the relative angular relationship of the shaft 300 is a uniform angular relationship.

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