GR1009168B - Low-torque mechanism using a pendulum for producing electric energy - Google Patents

Abstract

Novelty: a power mechanism-generator using one or more pendulums for the generation of electric energy is disclosed. Function mode: the rotary kinetic energy of a motion source (e.g. motor or propeller) converts into linear (9,7,6,5) and sets into motion an arm-pendulum 3 or a group of arms-pendulums. At least one power generation pair 1 (magnet/coil is placed on the arm of the pendulum 3 urging the strong permanent magnet 1A found inside the non-magnetic cylinder 2A to pass through the coil 2 so that electric voltage appears at the ends of this last. The placement of the power generation pairs (coil/magnet) on the arms of the pendulum (the magnets being freely moving inside the non-magnetic cylinder 3A) restricts and isolates the braking action due to the Lent’s effect creating strong resistance to the rotary motion of the magnet’s rotor (magnet 1A) and not to the start point (shaft) 11,Z, and allows the power generator to operate with low-torque motion sources. Embodiment: the invention finds application -except in traditional motion sources- to low-torque motion sources (e.g. small motors, propellers etc) allowing their use in multiple applications. A simple utilization is its application to the roofs of residences for covering the needs in electricity of the residents (placement of a propeller on the shaft 11 of the wheel 10 and of a power generator on the roof of the residence at a point where the velocity of the wind is up to 0,5 metres /sec).

Description

MECHANISM - GENERATOR IN PENDING GENERATOR ARRANGEMENT FOR

POWER GENERATION WITH LOW TORQUE REQUIREMENTS

The present invention relates to a mechanism for generating electricity in a pendulum arrangement. Any power source, especially low and very low torque power sources, can be applied to the mechanism and generate electricity. The mechanism can also be portable.

The mechanism has low torque needs and can work in connection with multiple sources of movement, e.g. engine, motor, wind, etc., converting kinetic energy into electrical energy.

Although there are hundreds of types of power generation mechanisms, this particular mechanism has an advantage over all the existing ones due to its unique and innovative design, which allows the production of electricity even when connected to very low-torque drive sources. This can happen since in the specific mechanism with the use of the Magnet/Coil generator pair applied to a pendulum arm, which the mechanism uses. By using the pendulum arm in the mechanism even the slightest movement from the point of inertia causes the magnets to move inside the non-magnetic tube surrounded by a coil and generate electricity. Because the magnets are not directly statically connected to the mechanism they move freely within the non-magnetic tubes fitted to the end of the pendulum arm at the same time as the generating coils and thus do not add significant resistance, derived from Lenz's law, to the source of motion eg motor, impeller, etc. Lenz's law has no reaction to the source of motion with the arrangement of the generator pair on the arm of the pendulum allowing the use of a source of motion with very low torque such as air below 0.5 meters per second. However, at the point of energy production, in the power generating pair, during which the magnets move in the non-magnetic tube and create voltage and electricity flow in the coils, Lenz's law applies and the speed of their movement decreases. At the same time, due to this disturbance from the position of equilibrium (equilibrium) of the arrangement of the magnets and the coils, an opposing force tries to prevent the magnets from moving and to stop them. This resistance does not adversely affect the point of motion since the movement of the pendulum and the generation of electricity in the coils mounted on the pendulum shaft are completely independent. The driving force only has to overcome the inertia of the weight of the shaft, and the pendulum with the electric pairs and then maintain the linear oscillation of the pendulum shaft.

With the linear movement of the pendulum the centrifugal and gravitational force act on the magnets to move them from their position relative to the coil. This change in the magnetic field creates a voltage in the inelastic coils and thus electricity.

The most common mechanism on the market involves the rotary motion of a magnetic rotor inside a fixed stator that has the winding of the power generating coils. The biggest problem with these mechanisms is that during the rotation of the rotor the Lenz effect creates a strong resistance to the rotational movement of the magnetic rotor, a resistance which the source of movement must compensate with more energy and torque. To overcome this resistance, large torque values are required which does not allow the use for energy production with low torque sources and at the same time limits the production of electricity.

In the present invention, the kinetic energy is converted into linear energy and moves a pendulum or a group of pendulums. The pendulums can be single or double and each one of them has, at its ends, non-magnetic tubes with one or more coils wrapped around them. Permanent magnets are placed inside the non-magnetic tubes. The oscillation of the pendulum causes the magnets inside the tubes to move and pass through the coils. Whenever there is movement of the magnets in relation to the coils, the perturbation of the magnetic field creates an AC voltage at the ends of the coils (Faraday's Law).

The drive of the power generating mechanism includes a large (10) and a small (8) gear. The large one receives movement from the torque source, eg impeller or motor, and transmits it to the small one. The small gear is mounted on a disc (9) which has an eccentric shaft. The eccentric shaft converts through two metal links (6,7) the rotary movement into linear and moves a lever (5) which is connected to the main suspension axis of the pendulums (Z,11,3). Due to this design the mechanism moves and generates electricity, even with very small torque sources. The mechanism does not need a large torque to move because it does not have to overcome a large inertia nor the braking governed by Lenz's law. The only resistance to movement is the inertia of the shaft at the point of movement (11 and Z) which comes from the weight of the pendulum mechanism.

As soon as the pendulum (3) starts to move, instead of braking, it assists the movement and the source of movement, e.g. motor, etc. only has to maintain the oscillation of the pendulum. The mechanism is applicable to small and large energy production systems. The performance of the mechanism is directly related to the number and size of electrogenerative pairs, the diameter of the non-magnetic tubes and the power of the permanent magnets, but also the configuration of the coils and the speed and torque of the connected drive source.

The mechanism-generator in an electric pendulum arrangement for generating electricity is innovative due to the arrangement and placement of the electric couple and the freely moving magnet (IA) inside the non-magnetizable cylinder which isolates and minimizes the braking resulting from Lenz's law allowing the use of the mechanism with sources of movement such as low power motors, propellers in locations where the wind speed is very low, up to 1.5 meters per second, in water flow points with very low speed without the need for any elevation difference that is needed today the existing hydroelectric production systems and not only. The system can also be operated manually or by applying the motion to a simple bicycle wheel. It could also replace the large volume of batteries in electric vehicles or even free them from recharging.

The generator mechanism in a generator pendulum arrangement is shown linearly in Figure 1 and the generator pair in Figure 2.

In figure 1 we have a section of the generator mechanism. (1) is the power generation cylinder, which includes the coils (2) and inside the permanent magnets (1A fig. 2). The cylinder is fixed to the pendulum shaft (3) of non-magnetizable metal. The double pendulum that we have in figure 1, could also be single. The suspension of the pendulum is done on a shaft (11) with a bearing, the shaft has a permanently welded blade (5), which is connected by a loose fire connection to the blade (6) and this to the blade (7). The blade (7) is loosely connected by fire to the disk (9), at an eccentric distance, simulating the movement of a crankshaft. This is where the conversion of rotary motion to linear motion is achieved. This disk has a concentrically mounted gear (8), which is permanently welded to the disk (9). The gear (8) is driven by the larger gear (10), which is firmly mounted on the shaft (11). On the same axis, the source of movement and torque supply, e.g. motor, impeller, etc., is permanently placed. The movement could be transferred from the source of movement to the disc (9) and with a belt.

In figure 2 we have a section of the electro-generating pair, a magnet that moves freely inside a non-magnetizable tube around which there is a winding of an electro-generating coil (1). The power generation coils (2) are placed around the non-magnetizable cylinder, eg a plastic tube. The permanent magnets (1A), inside the cylinder (1), can be connected to each other with a shaft (5A) made of non-magnetizable material (5A). At the ends of the shaft (5 A) conical dampers (2 A) are placed, corresponding dampers (2 A) are placed on the sealing plugs (4 A). The sealing plugs (4 A) are placed on the ends of the non-magnetized cylinders (1). For safety reasons, the generator is placed in a box (14) made of non-magnetizing material. The box (14) is sealed and prevents moisture, rain and dust from getting inside the generator.

An indicative place of application of the invention of the mechanism - generator in an electric pendulum arrangement for the production of electricity is the placement on the shaft of the disk (10) of an impeller, the wings of which are immersed in a low-flow irrigation water channel of a remote community, and the movement from the impeller to allow the linear movement of the pendulum giving electricity supply for the needs of the community.

Claims (6)

1. Generator mechanism in an electro-generating pendulum arrangement characterized by moving one or more electro-generating pairs (2), (permanent magnet (1A) or magnets in a non-magnetizable cylinder (3 A) e.g. plastic tube, with external coil winding (2) or coils) placed on the shaft (3) of one or more pendulum arms connected to a shaft (11) that moves the power generating pairs (I) in a reciprocating (linear) movement that comes from connecting the mechanism to a source, e.g. motor, impeller, etc., with torque sufficient to overcome the inertia of the mechanism (fig. 1) and maintain the movement of the pendulums, causing the free magnets (1A) to move inside the non-magnetizable cylinder (3A) relative to the coil (2) by changing the magnetic field resulting in a voltage being created at the ends of the coil(2) or coils. 2. A method of generating electricity characterized by being composed of electro-generating pairs (1), containing freely moving permanent magnets (1A), mounted on one or more pendulum arms (3) connected to a rotating shaft (11, G) which simultaneously moves the permanent magnets (1A) and the coils in linear motion (2). 3. Generator mechanism in an electric pendulum arrangement (fig. 1) according to claims 1 and 2 characterized in that it isolates the generation of the reverse force, resulting from Lenz's law, to act only on the freely moving magnet (1A ), inside the non-magnetic tube (3A) of the magnet / coil pair (1) placed at the ends of the pendulum arm (3), allowing the generator mechanism to produce electricity with sources of movement (eg motor, impeller, etc.) low torque. 4. Generator mechanism in a generator pendulum arrangement according to claim 1 and 2 characterized by being made of non-magnetizable (eg stainless steel, plastic, aluminum, etc.) parts. 5. Generator mechanism in an electric pendulum device according to claims 1, 2, 3 and 4 characterized by allowing connection to any source of movement (eg motor, impeller, etc.) and to transfer the kinetic energy in linear motion to the pendulum arm ( 3) and generate electricity. 6. A generator mechanism in an electric pendulum arrangement according to claims 1, 2, 3, 4 and 5 characterized in that the reverse force resulting from Lenz's law on magnets (1A) and not the rotary motion in the pendulum arms ( 3). sweat only your freely moving axes (Z,11) which transmits the