FR2975545A1 - Flat device for generating electric current from e.g. wind, has coil unit whose coils are uniformly distributed on supporting part such that magnetic elements are aligned with coils during rotation of plate relative to supporting part - Google Patents

Abstract

The device (1) has a supporting part (4) receiving a coil unit (3), which generates induced electric current. A circular plate (6) i.e. disk, is rotatably mounted on the supporting part for receiving a magnetic unit (2). The magnetic unit comprises magnetic elements (20), which are uniformly distributed on the plate in a circle. The coil unit comprises coils (30), which are uniformly distributed on the supporting part opposite to the circle such that the magnetic elements are aligned with the coils during rotation of the plate relative to the supporting part.

Description

The present invention is in the field of electric power generation. The invention relates to an electric generator device.

The invention will find a particular application, but in no way limiting, in the production of electrical energy by conversion of wind or hydraulic energy. To do this, the generator device according to the invention will be coupled to wind turbine or hydraulic capture means, turbine type. In known manner, the production of electrical energy by conversion of wind or hydraulic energy is performed by turbine type devices mounted in rotation about an axis. Such a turbine forms a rotor mounted facing a stationary stator. This rotor and this stator are equipped with means so as to form an electromagnetic torque and constitute an alternator. Therefore, the rotation of said rotor generates an induced electric current proportional to its rotational speed. More particularly, the rotor acts as the inductor and, for this purpose, generally consists of a permanent magnet, generating a constant magnetic field, or of an electromagnet. On the other hand, the stator is the armature and consists of a winding of wires, in the form of winding, within which will flow the alternating electric current induced by the relative rotational movement of said rotor. Many devices use this principle to generate electrical power. More specifically, in the context of capturing and converting wind or hydraulic energy, it is necessary to obtain a minimum rotation of the rotor, of the order of several hundred revolutions per minute, to produce a usable current. . Therefore, the existing devices require a corresponding wind force or water, limiting their area of implantation as well as their period of operation, related to natural conditions. The present invention aims to overcome the drawbacks of the state of the art by proposing an electric current generator, intended to be coupled with a wind turbine or hydraulic, and which generates a usable electric current for low energy sensed , especially for a wind below 30 km / h. Therefore, it is possible to expand the areas of such wind turbines, while enjoying increased operating times. In addition, the materials and design of this generator significantly increase electrical efficiency for a lower manufacturing cost. In addition, the efficiency obtained is increased by minimizing the friction between the various elements, in particular the rotor and the stator. In addition, the flat configuration of such a generator limits the resistance to rotation of said rotor, and even allows a superposition of several rotors. Arranged horizontally, such a generator can in particular be coupled to a turbine so as to create a vertical axis wind turbine. To do this, the generator device according to the invention comprises magnetic means and wound means of generations of an induced electric current, said magnetic means and said wound means being mounted vis-à-vis and in relative rotational movement. relative to each other, so as to electromagnetically induce said electric current within said wound means. Such a generator is characterized in that said device is flat and comprises a support receiving said wound means and a plate rotatably mounted on said support, said plate receiving said magnetic means, and in that said magnetic means are presented under the form of magnetized elements regularly distributed on said plate along a circle, while said wound means are in the form of coils distributed regularly on said support according to and opposite said circle, so that during rotation of said plate relative to said support, at least one magnetized element is always aligned with a coil.

According to other features, said plate may have a circular shape and that said magnetized elements are distributed around the periphery of said plate. Advantageously, said support may comprise rounded housings within which said coils are held. Preferably, said support may comprise a central axis on which is rotatably mounted said plate, said plate being braced relative to said support. In particular, said axis is integral with at least one turbine. In addition, said support and said plate can extend vertically or horizontally. According to one embodiment, the device according to the invention comprises at least one additional plate 20 equipped with magnetic elements or coils, said additional plate being aligned, adjacent or superimposed, reciprocally to said support or to said plate. According to another embodiment, it comprises at least three coils and at least four magnetized elements. Thus, the generator according to the invention makes it possible to obtain an improved electrical efficiency, starting from about ten volts, from a low rotation, of about ten revolutions per minute, in particular between 15 and 30 revolutions per minute. Other characteristics and advantages of the invention will emerge from the following detailed description of non-limiting embodiments of the invention, with reference to the appended figures in which: FIG. 1 represents a perspective view of a first embodiment; Figure 2 shows a partial perspective view from below of Figure 1; - Figure 3 shows a partial perspective view of a second embodiment; - Figure 4 shows a top view of the support equipped with twelve coils; and - Figure 5 shows a top view of the support of Figure 4 surmounted by a plate equipped with sixteen magnets. The present invention relates to a device 1 of electric current generator. Such a device comprises magnetic means 2 and wound means 3. Combined, these means 2 and 3 allow the generation of an induced electric current. In particular, the relative displacement of the means 2 and 3 with respect to each other makes it possible to generate, by electromagnetic induction, an electric current within the wound means 3. More precisely, said displacement of the means 2 and 3 between them is effected by rotation. In addition, said magnetic means 2 are located opposite said wound means 3. Therefore, said means 2 and 3 are in a circular path, so that one or the other of said means 2 or 3 pass in front of corresponding means. According to the preferred embodiment, said magnetic means 2 are movable while the wound means 3 are fixed. Thus, during the passage of the magnetic means 2 in front of the wound means 4, the perpetual magnetic field generates the induction of an electric current within the winding. To do this, the poles of the magnetic means 2 are oriented along the axis of the wound means, namely the longitudinal axis around which the winding of the wound means 3 is carried out. According to one embodiment, the south pole of the magnetized elements 20 located at the top plate 6 is upward, while the north pole is downward, facing the coil means 3. According to the preferred embodiment, the orientation of the magnetic element poles 20 is alternated from one magnet to another. Thus, if a magnet has its north pole opposite the wound means 3, then the adjacent magnets have their south pole vis-à-vis. During rotation, this alternating arrangement of the poles of the magnetized elements 20 makes it possible to generate an alternating current. Advantageously, said device 1 is flat. In sum, it does not have a tubular shape, the magnetic means 2 surrounding the wound means 3, or vice versa, but the magnetic means being disposed adjacently, on the side or superimposed, below or above, with respect to said means 3. This flat device can be horizontal, as shown in the figures, but also vertical or inclined. According to an essential characteristic, the generator device 1 comprises a support 4 receiving said wound means 3. The latter may be in the form of coils 30. As such, said coils 30 are in the form of a hollow tube around which is wound by winding turns of at least one wire made of a conductive material, in particular enamelled copper, each wire being isolated by a peripheral sheath. In particular, each coil 30 may have a diameter of 5 to 7 centimeters, for a winding of 500 turns or turns. According to the preferred embodiment, particularly visible in the detail of FIG. 4, said support 4 comprises rounded housing 5 inside which said coils 30 are held. In sum, said coils 30 are each mounted fixed and held at 5. According to the preferred embodiment, said coils are embedded in said housing 5 by an insulating material, in particular a composite, such as a resin. According to a preferred embodiment, each coil 30 may receive at its center a core or a core of metal material, magnetizable, such as steel, and acting as an air gap by increasing the magnetic flux that passes through it.

Advantageously, a plate 6 is rotatably mounted on said support 4. According to the preferred embodiment, said support 4 comprises a central axis 7 on which is rotatably mounted said plate 6. In addition, the latter being braced relative to said support 4. In sum, the plate 6 extends parallel to said support 4, the axis 7 being orthogonal. Moreover the axis 7 passes through the center of the support 4 and the plate 6. In addition, said plate 6 receives said magnetic means 2. In sum, the latter are secured to the plate 6. To do this, said magnetic means 2 are in the form of magnetized elements 20. Note that these magnetized elements 20 may be perpetual magnets, provided with a north pole and a south pole.

According to the embodiments, these magnetized elements 20 may be in the form of polygonal magnets or cylindrical magnets. According to the preferred embodiment, each magnet has a rectangular parallelepiped shape, with 50 millimeters wide by 50 millimeters long and a thickness of 8 millimeters. Such a magnet has a pulling force of 145 Kilo Newton. According to one embodiment, these elements 20 are evenly distributed on said plate 6 along a circle.

In addition, said elements 20 are integral with the face of the plate 6 located opposite the coils 30. According to another embodiment, not shown, said elements 20 are fixed within orifices passing through the plate 6 .

According to the preferred embodiment, said plate 6 has a circular shape, such as a disk or a plate, and that said magnetized elements 20 are distributed around the periphery of this plate 6. In short, the elements 20 are distributed around the periphery of the plate. plate 6, according to identical sectors of the circle around the center of the plate 6, and therefore of the axis of rotation 7. Advantageously, the positioning of the coils 30 and the elements 20 is carried out in a similar path. In particular, the coils 30 are evenly distributed on said support 4 according to and opposite said circle. As for the elements 20, the coils 30 are therefore positioned on said support 4 in a similar circular path and in identical sectors of circle, namely at equivalent angular intervals. This particular distribution of the coils 30 and the magnetized elements 20 in the same circle is such that in the course of rotation of said plate 6 relative to said support 4, at least one magnetized element 20 is always found aligned in whole or in part with a coil 30. Preferably, several magnetized elements 20, in particular four in number, are always aligned with several coils 30, reciprocally four. In sum, when the plate 6 rotates about the axis 7, the elements 20 pass in front of the coils 30 and at least one element 20 is aligned with a coil 30. Therefore, no matter the angle of rotation of the plate 6 relative to the support 4, a current is always induced within at least one coil 30. According to particular embodiment, provided minimum, the device 1 comprises at least three coils 30 and at least four magnetized elements 20. Therefore the center of the coils 30 is spaced every 120 degrees, while the centers of the elements 20 are every 90 degrees. According to the preferred embodiment shown in Figures 4 and 5, the coils 30 are 12 in number, while the magnetized elements 20 are sixteen in number. The coils 30 are therefore distributed over the circle every 30 degrees, while the elements 20 are distributed every 22.5 degrees. Therefore, several elements 20 are always found in front of several coils 30, thereby increasing the production of induced current.

In the latter case, it will be noted that the coils 30 may be electrically connected by a specific circuit. In particular, a first coil is connected to the coil located two or three coils further, upstream or downstream relative to the distribution path on the circle. This connection can be made in series. According to the preferred embodiment, the coils 30 being twelve, three circuits in series of four coils are made alternately, connecting the input wire of a coil to the output wire of the previous coil in the circuit. The output of each circuit is connected to a single neutral pole, while the input of each circuit is connected to a single pole so as to generate a three-phase alternating current. In addition, at the output, a rectifier bridge makes it possible to obtain a continuous single-phase current.

It will be noted that each plate 6 or additional plate may be made of a metallic material, in particular steel. According to the preferred embodiment, said steel is "soft", "semi-soft" or "medium-hard", namely that it is less resistant and lighter than conventional steel, because of its lower content. carbon. This material supporting the magnetized elements 20 being capable of being magnetized, improves the transmission of the magnetic field of said magnets, or even increases it. Furthermore, each support 4 of the coils 30 may be made of steel, but rather incorporate a non-magnetic material, such as aluminum. In addition, the housing 5, but also the other cuts and machining can be operated by laser cutting, increasing the accuracy and minimizing the games. As mentioned above, said support 4 and said plate 6 can extend vertically or horizontally.

According to the preferred embodiment, they extend horizontally. According to subsidiary embodiments, as can be seen in FIG. 2, the device 1 comprises at least one additional plate 8 equipped with magnetized elements or coils, said additional plate 8 being aligned, adjacent or superimposed, reciprocally to said support or to said plate. In sum, at least one additional plate 8 can be positioned rotating under the support 4, it is then identical to the plate 6, provided with magnets. It can also be placed with coils 30, such as the support 4, on the other side of the plate 6, then sandwiched. It is possible to overlay several supports and plates, increasing the production of electricity.

In addition, said axis 7 is integral with at least one turbine (not shown). Such a turbine has blades for allowing the flow of a fluid, air in the case of a wind turbine and water in the case of a hydraulic turbine, or even in a combination air and water, such as a turbine operating at the steam, so as to rotate said axis 7, this rotating movement operating the generator device 1 according to the invention. Note that the turbine may be vertical axis when the generator device 1 is horizontal, and vice versa.

Thus, the generator device 1, because of its flat work, without contact between the magnetized elements 20 and the coils 30, minimizes friction and improves electrical efficiency. In addition, the positioning at the periphery, on the outside of the magnetic means 2 and coiled 3, increases the rotational torque and therefore the electricity generated as a result with respect to an existing concentric centered rotation about the axis of rotation. Therefore, the more the diameter of the generator increases, the proportionally increasing the number of magnets and coils, the higher the current efficiency is important. Equipping a wind turbine or a hydraulic turbine, or even a combination of both, the generator device 1 according to the invention makes it possible to obtain a yield of at least 30% additional and from a low rotation, namely from 10 revolutions per minute. minute.

In particular, according to the preferred embodiment, the dimensional and technical characteristics have made it possible to increase the efficiency by 30% by introducing a mild steel core within the coils 30 by an additional 30% by using a winding of 500 revolutions per second. a coil 5 to 7 centimeters in diameter, an additional 30% through the steel plate that promotes the magnetism of the magnets and a further 30% by taking specific magnets, having a magnetic force of about 145 Kilo Newton's traction.

Claims (8)

REVENDICATIONS1. Device (1) for generating electric current, comprising magnetic means (2) and wound means (3) for generating an induced electric current, said magnetic means (2) and said wound means (3) being screwed together and relative to rotation relative to each other, so as to electromagnetically generate said electric current within said wound means (3), characterized in that said device (1) is flat and comprises a support (4) receiving said wound means (3) and a plate (6) rotatably mounted on said support (4), said plate (6) receiving said magnetic means (2), and in that said magnetic means (2) are in the form of magnetized elements (20) regularly distributed on said plate (6) along a circle, while said wound means (3) are in the form of coils (30) distributed regularly sure said support (4) according to and in relation to said circle, so that during rotation of said plate (6) with respect to said support (4), at least one magnetized element (20) is always aligned with a coil (30). 2. Generator device (1) according to claim 1, characterized in that said plate (6) has a circular shape and that said magnetized elements (20) are distributed around the periphery of the plate (6). 3. Generator device (1) according to one of claims 1 or 2, characterized in that said support (4) comprises housing (5) rounded within which are held said coils (30). 4. Generator device (1) according to any one of the preceding claims, characterized in that said support (4) comprises a central axis (7) on which is rotatably mounted said plate (6), this plate (6) ) being braced with respect to said support (4). 5. Generator device (1) according to claim 4, characterized in that said axis (7) is integral with at least one turbine. 6. Generator device (1) according to any one of the preceding claims, characterized in that said support (4) and said plate (6) extend vertically or horizontally. Generator device (1) according to any one of the preceding claims, characterized in that it comprises at least one additional plate (8) equipped with magnetized elements (20) or coils (30), said plate further (8) being aligned, adjacent or superimposed, reciprocally to said support (4) or to said plate (6). 8. Generator device (1) according to any one of the preceding claims, characterized in that it comprises at least three coils (30) and at least four magnetized elements (20).