FR2904862A1 - Automatic rotating mechanism for generating electric power, has gravitational rotating metal belt and movable heavy wheel that drop predetermined distance to generate kinetic energy to output rotating power - Google Patents

Abstract

The mechanism (100) has an auxiliary wheel (110) provided above a main wheel (140). An auxiliary wheel (130) and a movable heavy wheel (160) are respectively provided on both sides of the main wheel. A gravitational rotating metal belt (120) has heavy blocks (122) on an outside of a flexible metal connecting device (124). An arrestor (170) moves upward of the heavy wheel and the belt. The belt and the heavy wheel drop a predetermined distance to generate kinetic energy to output a rotating power, when the arrestor is removed from the belt and the heavy wheel.

Description

AUTOMATIC ROTATION MECHANISM FIELD OF THE INVENTION

  The invention generally relates to an automatic rotation mechanism and, more particularly, to an automatic rotation mechanism provided with a movable inertia wheel and a gravity-rotating metal belt. STATE OF THE ART 15 With a strong growth of commercial, industrial and comfort needs of modern life, there is an ever increasing demand and dependence on electrical energy. Currently, electricity is generated mainly from nuclear power, coal, oil, gas, wind, basements and the sun. 20 Earth's energy resources are continually depleting. However, energy consumption is increasing day by day. As a result, environmental demands are increasing and pollution is increasing. In this perspective of limited energy resources on earth, it is imperative for scientists to find new alternative energies. Currently, there are supporters and detractors of the use of nuclear energy; in particular, the extension of its development has initiated a long-term debate. As for hydropower, most water resources have been exploited and the impact of hydropower on nature is still being criticized; his future is also very limited. In addition, environmental pollution and the greenhouse effect due to coal combustion are not yet solved. Faced with foreseeable energy deficits in the future and the inability to find new alternative energy, it is natural to use any process and mechanism to generate energy reducing the impact of the energy crisis for Humanity. SUMMARY OF THE INVENTION The object of the present invention is to provide an automatic rotation mechanism utilizing the kinetic energy of a gravitational rotating metal belt driving an energy generator to provide power to the machine. electric energy at a low price. Another object of the present invention is to provide an automatic rotation mechanism operating automatically to generate energy driving any other device.

  To fulfill the foregoing objectives, the present invention provides an automatic rotation mechanism. The automatic rotation mechanism comprises a main wheel, a first auxiliary wheel, a second auxiliary wheel, a movable flywheel, a gravity rotation metal belt and a stopping base. The first auxiliary wheel is preferably placed above the main wheel, and the second auxiliary wheel and the movable flywheel are preferably placed on each side of the main wheel. The mobile inertia wheel is, for example, 4 to 6 times heavier than the main wheel, the first auxiliary wheel and / or the second auxiliary wheel. The gravity rotation metal belt consists of a flexible metal bonding device and several mass blocks fixed on an outer face of the flexible metal bonding device. Adjacent mass blocks are separated by a space at the predefined distance. The flexible metal bonding device passes around the first auxiliary wheel, the second auxiliary wheel and the mobile flywheel, and the main wheel is placed under the gravity-rotating metal belt to form a supporting fulcrum. the rotating metal belt by gravity. The base of the gravity rotation metal belt is placed under the movable flywheel and under the outside of the gravity rotation metal belt to lift the movable flywheel and the rotating metal belt. gravity. When the stopping base is removed from the base of the moving flywheel, the moving flywheel and gravity rotation metal belt can be lowered by a predefined distance to produce kinetic energy. turn the rotating metal belt by gravity. The second auxiliary wheel is also driven by the gravity rotation metal belt to produce rotational energy. The second auxiliary wheel preferably comprises a power transmission shaft for generating rotational energy, and is preferably connected to an energy generator for generating electrical energy. For example, a belt such as a V-belt or a V-belt is used to connect the power transmission shaft to the power generator. The distance between the axes of the movable inertia wheel and the second auxiliary wheel is preferably at least twice as large as the distance between the axes of the second auxiliary wheel and the main wheel. The movable flywheel is preferably at least four to five times heavier than the second auxiliary wheel. The flexible metal bonding device is made of a flexible metal belt or a set of joints. The mass blocks are preferably made of metal.

Thus, the automatic rotation mechanism of the present invention can use the gravity rotation metal belt to produce kinetic energy to directly drive a machine or generator of energy and produce low electrical energy. price.

BRIEF DESCRIPTION OF THE FIGURES The foregoing and advantages of this invention will be further appreciated and understood from the following detailed description of the accompanying figures, in which: FIG. 1 is a preferred embodiment of the automatic rotation mechanism of FIG. the present invention; and Figure 2 is a preferred embodiment of the gravity rotation metal belt of the automatic rotation mechanism of the present invention.

DETAILED DESCRIPTION OF THE INVENTION The following description is presently the best embodiment of the present invention. This description should not be taken in a limiting sense but was simply designed to describe the general principles of the invention. The scope of the invention will be determined by reference to the appended claims. Figure 1 illustrates a preferred embodiment of the automatic rotation mechanism of the present invention. The automatic rotation mechanism (100) comprises a main wheel (140), a first auxiliary wheel (110), a second auxiliary wheel (130), a movable flywheel (160), a parking base (170) ) and a gravity rotation metal belt (120). The gravity rotation metal belt (120) passes around the first auxiliary wheel (110), the second auxiliary wheel (130) and the movable flywheel (160), and the main wheel (140) is positioned under the gravity rotating metal belt (120) to support the gravity rotation metal belt (120). The stop pedestal (170) is located under the movable inertia wheel (160) for retaining the gravity rotation metal belt (120) and the movable flywheel (160). Upon initiation of the automatic rotation mechanism (100), the stop pedestal (170) is moved outwardly to release the gravity rotation metal belt (120) and the movable flywheel (160). Since the movable flywheel (160) is heavier than the main wheel and / or the auxiliary wheel, the gravity rotation metal belt (120) and the movable flywheel (160) can descend from a predefined height. Thus, the gravity rotation metal belt (120) begins to rotate under the effect of a potential energy change. The gravity rotation metal belt (120) is comprised of a flexible metal bonding device (124) and a plurality of mass blocks (122) attached thereto. The mass blocks (122) are preferably solid blocks, for example blocks of metal, plastic, glass and / or concrete. The flexible metal bonding device (124) preferably consists of a set of hinges and / or a flexible metal strap. Since each mass block (122) has a predefined mass, the total weight of the gravity rotation metal belt (120) is greater than that of the main wheel 2904862 (140) and auxiliary wheels, typically more than 6 times the weight of the main wheel (140) and / or auxiliary wheels. The adjacent mass blocks (122) are separated from a space (126) allowing the gravity rotation metal belt (120) to articulate around the main wheel (140), the first auxiliary wheel (110). , the second auxiliary wheel (130) and the movable flywheel (160). The adjacent mass blocks (122) come into contact when the gravity rotation metal belt (120) is turned over. Thus, the gravity rotation metal belt (120) forms a lever structure between the main wheel (140) and the movable flywheel (160).

FIG. 2 illustrates a preferred embodiment of the gravity rotation metal belt of the automatic rotation mechanism of the present invention. The gravity rotation metal belt (200) preferably consists of a flexible metal bonding device (220) and mass blocks (210). The adjacent mass blocks (210) are separated by a predefined space. When the gravity rotating metal belt (200) is facing the flexible metal bonding device (220), the width of the gap (212) is proportional to the distance away from the flexible metal bonding device (220) . When the gravity rotation metal belt (200) is inverted, the width of the space (214) is reduced until the adjacent mass blocks (210) come into contact, i.e., the width of the space (214) becomes zero on the upper face of the mass blocks (210). Referring again to FIG. 1, when the stop base (170) is removed from the base of the moving flywheel (160), the mass blocks (122) of the gravity-rotating metal belt ( 120) between the main wheel (140) and the movable inertia wheel (160) contact each other. Thus, the main wheel (140) becomes a fulcrum and the movable flywheel (160) becomes the point of application of a force. The axis of the main wheel (140) and that of the movable flywheel (160) preferably form an angle of 20-30 degrees to the horizontal. Since the weight of the movable flywheel (160) and the gravitational rotating metal belt (120) is preferably greater than that of the main wheel (140) and the auxiliary wheels, the metal belt of rotation by gravity (120) and the movable flywheel (160) can descend to exert on the gravity-rotating metal belt (120) a rotation about the main wheel (140) and auxiliary wheels, when the stop base (170) is removed from the base of the moving flywheel (160). The gravity rotation metal belt (120) and the movable flywheel (160) are heavier than the main wheel (140), the first auxiliary wheel (110) and the second auxiliary wheel (130). The main wheel (140), the first auxiliary wheel (110) and the second auxiliary wheel (130) are preferably made of material and / or lightweight structure. In addition, the friction coefficients of the main wheel (140), the first auxiliary wheel (110) and the second auxiliary wheel (130) are preferably very low. Therefore, when the gravitational rotating metal belt (120) begins to rotate, the movable flywheel (160) also begins to rotate and the main wheel (140), the first auxiliary wheel (110) and the second auxiliary wheel (130) also begin to rotate. In addition, since both the gravity rotation metal belt (120) and the mobile flywheel (160) are heavy, the rotational energy can be exploited by a power transmission shaft (132). ) of the second auxiliary wheel (130). The power transmission shaft (132) can be connected to a machine directly operating power or to a belt, for example, a V-belt or a V-belt. The power transmission shaft (132) can be further connected to an energy generator (180) for generating electrical energy. The distance between the axis of the main wheel (140) and the axis of the mobile inertia wheel (160) is preferably greater than the distance between the axis of the main wheel (140) and the axis the second auxiliary wheel (130); more particularly, this distance is at least twice as great. In addition, the automatic rotation mechanism (100) may further include a third auxiliary wheel (150) for supporting the gravity rotation metal belt (120). The third auxiliary wheel (150) can effectively support the gravity rotation metal belt (120) to prevent an upper portion of the gravity rotation metal belt (120) from descending, particularly when the stop pedestal (170) ) 30 is removed from the base of the moving flywheel (160). The auxiliary wheel (150) is preferably lighter than the movable flywheel (160). According to a preferred embodiment, the mobile flywheel (160) is heavier than the second auxiliary wheel (130), the first auxiliary wheel (110) or the third auxiliary wheel about four times, and preferably about five times. Because the movable flywheel (160) and the gravity rotation metal belt (120) are very heavy, the movable flywheel (160) and the gravity-rotating metal belt (120) ) can start to turn through the potential energy change. As the movable flywheel (160) and the gravity-rotating metal belt (120) begin to rotate, the main and auxiliary wheels are rotated to produce continuous rotational power to a consumer machine. energy. The rotational energy can be produced directly through the output power shaft (132) or produce electrified energy with an electricity generator. Thus, the automatic rotation mechanism according to the present application can provide cheaper electrical energy and energy to operate the machine. As will be understood by those skilled in the art, the preferred embodiments described herein are more illustrative than limiting of the present invention. They are intended to cover various modifications and similar variations forming part of the spirit and scope of the appended claims, the purpose of which is to obtain the broadest interpretation encompassing such modifications and similar structures.

Claims (10)

  1) Automatic rotation mechanism (100), comprising: - a main wheel (140); a first auxiliary wheel (110) placed above said main wheel (140); a second auxiliary wheel (130) placed on one side of said main wheel (140); a movable flywheel (160) placed on another side of said main wheel (140), wherein said movable flywheel (160) is heavier than said main wheel (140), said first auxiliary wheel (110) ) and second auxiliary wheel (130); a gravity-rotating metal belt (120) consisting of a flexible metal bonding device (124) and a plurality of mass blocks (122) attached to the outside of said flexible metal bonding device (124), where the bulk blocks (122) adjacent form a space (126) of predefined width; said flexible metal bonding device (124) passes around said first auxiliary wheel (110), said second auxiliary wheel (130) and said movable flywheel (160); said main wheel (140) is placed under said gravity-rotating metal belt (120) to support said gravity-rotating metal belt (120); and - a cradle (170) holding said gravitational rotating metal belt (120) under said movable flywheel (160) and out of said gravity rotating metal belt (120) to lift said movable inertia wheel (160) and said gravity-rotating metal belt (120) so that when said stop pedestal (170) is removed from the base of said movable flywheel (160), said wheel movable inertia member (160) and said gravity rotation metal belt (120) descend from a predefined height to produce kinetic energy, rotating said gravitational rotating metal belt (120). 2904862 9   The automatic rotation mechanism (100) according to claim 1, wherein said second auxiliary wheel (130) further comprises a power transmission shaft (132) for transmitting rotational energy. 5   The automatic rotation mechanism (100) of claim 2, further comprising an energy generator connected to said power transmission shaft (132) for generating electrical energy.   4) The automatic rotation mechanism (100) according to claim 3, wherein said energy generator and said power transmission shaft (132) are connected by a belt.   5) The automatic rotation mechanism (100) according to claim 4, wherein said automatic rotation mechanism (100) uses a rotating lever structure and a potential energy variation to produce kinetic energy and rotate the lattice. gravity rotation metal belt (120).   6. The automatic rotation mechanism (100) according to claim 1, wherein a first distance between the axes of said movable inertia wheel (160) and said second auxiliary wheel (130) is greater than a second distance. between the axes of said second auxiliary wheel (130) and said main wheel (140).   7. The automatic rotation mechanism (100) according to claim 6, wherein said first distance is twice as large as said second distance.   The automatic rotation mechanism (100) according to claim 1, wherein said movable flywheel (160) is at least four times heavier than said second auxiliary wheel (130).   The automatic rotation mechanism (100) according to claim 1, wherein said flexible metal connecting device (124) is a flexible metal belt or a set of joints. 2904862 -   The automatic rotation mechanism (100) according to claim 1, wherein said mass blocks (210) may be made of metal, plastic, glass or concrete blocks. 5