RO129910A2 - Magneto-electric generator for average and weak wind turbines - Google Patents

Abstract

The invention relates to a magneto-electric generator for average and weak wind turbines with embedded generator. According to the invention, the generator comprises modules () with two circular rows of n plate-type stator magnets () with North-South radially-oriented polarization on length, equidistantly arranged on a non-magnetic crown-support () and a row of n solenoids, with or without core, interconnected in series or parallel in an adequate manner in order to generate a biphase or a single-phase alternating current, fixed in a non-magnetic crown-support (), with a circular gap of 5...15 mm between solenoids and stator magnets () for rotating a disk () with marginally and equidistantly arranged magnetic shields () with a space between them corresponding to the dimension of a magnetic shield (). The solenoids are either double solenoids () formed as a pair of identical solenoids () adjacently arranged with the axis of symmetry perpendicular to the plane thereof, each solenoid () being placed between a pair of North-South poles of the pair of stator magnets () and being serially connected with the anti-parallel turns, or simple solenoids () with a length equal to the length of the stator magnets () and adjacently arranged with the axis of symmetry parallel to the North-South polarization thereof. The electric current is generated by the magnetic flux variation produced at the level of solenoids () by the alternating interposition of some magnetic shields () between the solenoids and the stator magnets (). The magnetic shields () can be made of pyrolytic graphite, of lamellar magnets () in repulsive arrangement as against the magnets () and shielded on the side facing the lamellar magnet with a thin diamagnetic and/or ferromagnetic shield () or of magnetic lamella () fixed between two magnetic, diamagnetic or pyrolytic graphite type shields () or attached to a magnetic shield () made of thicker pyrolytic graphite for shielding against the corresponding stator magnet ().

Description

Magneto-electric generator for medium and low wind wind

The invention relates to a magneto-electric generator for medium and low wind wind turbines with built-in generator.

It is known the classic magneto-electric generator of wind turbines, made from a circular row of static electric current induction solenoids connected in series and in parallel and two rows of rotary magnets parallelepiped or discoidal, polarized on faces, which fit the circular row of solenoids. stator, disposed equidistantly on the ferrous support, with a pole towards the stator solenoids and attractive to each other, so that by their rotation they generate variable flux _Β magnetic fluxes, of opposite opposite direction, at the solenoids level, for induction of alternating electric current , I and an electrical voltage E = -dC> B / dt. In turn, the induced electric current I, however, generates an Indus magnetic flux, Φ | , which - according to Lenz's law, is opposed to the cause that generated it, ie the magnetic flux ului _Β , meaning the field lines of the two fluxes, Φ _Β and Φ |, being mutually opposite.

The moment M _F of the brake force of rotation so produced is considerable and significantly higher speed of revolution higher, so that the wind turbines of the magneto-electric generator built over 800W, the wind conditions relatively weak, 5 m / s and tending to the value of 3m / s, as a result of the moment of inertia of the rotor with magnets, produce an insignificant electric current, due to the low speed of rotation, or actually no longer rotate after attaching the magneto-electric generator.

To eliminate this inconvenience, it should be decreased when the braking force _F M to the rotation, for a given speed, the moment of inertia of the rotor or magnet or, preferably, both.

A constructive solution of a magneto-electric generator that is suitable for achieving the aforementioned functional conditions is presented in the electronic book: "Practice guide to free energy devices" by Patrick Kelly, on page 3.27, (http: //www.free-enerqv -info.co.uk/index.html), which presents a magneto-electric generator (author: Donald Lee Smith), using two discoidal stator parts with cylindrical magnets arranged circularly in plastic tubes, perpendicular to the plane of the disc and in mutual repulsion of coaxial magnets on the two stator parts, with solenoids arranged on stator magnets, solenoids on two coaxial magnets being attached, between the two stator parts with magnets and solenoids being rotated a plastic disc drilled, with holes circularly arranged and equidistant at the distance from the axis with the distance at which the stator magnets are on the respective stator side, between the holes of this disk being made a magnetic screen of powder of magnetic material with neodym. At relatively easy rotation of the disc, these magnetic screens periodically interrupt the magnetic field lines between the coaxial magnets of the two stator parts, thus generating a variable magnetic flux, generating electric current, at the solenoids level of the stator magnets. It is mentioned as an ideal material for the magnetic screens, the zirconate W, (terfelon D), but which is expensive.

Although it is stated about the realization of this generator at the commercial level, there are no details regarding the power of the generator but it does mention the existence of a high efficiency compared to the classic electric generator version.

It is also known, in this sense, of the manufacture of such magnetic-electric generators, and a screen of diamagnetic mixture magnetic field deflector, (US 2006/0083931 A1), a similar magnetic property having the magnetic screens of pyrolytic graphite, which has a high coefficient of diamagnetism compared to ordinary graphite.

It is also known by the patent application RO 2013-00187, a magnetic-electric generator for medium and low wind wind consisting of two circular rows of n stator magnets arranged equidistantly on a disc-support and a row of n solenoids with or without core, fixed in a circular crown made of epoxy resin, with a circular space of 5 + 15 mm distance between solenoids and stator magnets, rotating a rotor disc with magnetic screens arranged marginally and evenly, fixed on a common fixed axis in two bearings in the central area of the support discs which are fixedly fixed to the crown with solenoids by means of fixing axles. Solenoids may have a magnet core repulsive to stator magnets, in this case magnetic screens being ferromagnetic, magnetic or diamagnetic powders - pyrolytic graphite, or they may be coreless, in which case magnetic screens may be lamellar magnet repulsive in front. of adjacent stator magnets and framed by two thin magnetic screens of which at least the thin magnetic screen from the stator magnets is made of permalloy, mu-metal or ferritic stainless steel. Stator magnets can be arranged relative to one another attractive coaxial, rotor disks being arranged in this case parallel-symmetrical, or coaxial repulsive, rotor disks being arranged in this case parallel offset by the quasi-angular length of a screen made in this case from pyrolytic graphite or equivalent. The solenoids are interconnected in series or in parallel in an appropriate manner to obtain a two-phase alternating current. In a simplified embodiment, the stator magnets are replaced by magnetic crowns or magnets arranged as solenoid cores, the magnetic screens being in this case pyrolytic graphite material.

The technical problem solved by the invention consists in the creation of a magneto-electric generator with solenoids and stator magnets and a rotor with magnetic screens arranged circularly spaced from the type mentioned above, but multimodular, with a better use of the space and energy of the field of stator magnets, for obtaining a greater power of electricity at gauge values and optimum rotor rotational power, corresponding to a better efficiency of converting mechanical energy into electricity.

The magneto-electric generator for medium and low wind wind according to the invention solves this technical problem by the fact that, it consists of modules with two circular rows of n stator plates type NS with radially oriented length NS, arranged equidistantly on a crown- non-magnetic support and a row of n solenoids with or without core, interconnected in series or in parallel adequately to obtain a two-phase or single-phase alternating current, fixed in a non-magnetic corona support, with a circular gap of 5 -: - 15 mm distance between solenoids and magnets, rotating a rotor disk with magnetic screens arranged marginally and evenly, with space between them corresponding to the size of a magnetic screen. The solenoids are either double solenoids, formed as a pair of identical solenoids, arranged adjacent, with the axis of symmetry perpendicular to its plane, each solenoid being between a pair of NS poles of the pair of stator magnets and being joined by the antiparallel spirals, or simple solenoids. of length equal to that of stator magnets and arranged adjacent to the axis of symmetry parallel to their NS polarization. The electric current is generated by the variation of magnetic flux produced at the level of the solenoids by the alternate interposition of some magnetic screens between them and the static magnets that frame the solenoids. Magnetic screens may be pyrolytic graphite, lamellar magnet repulsively disposed of stator magnets and screened on the side thereof with a diamagnetic and / or ferromagnetic thin magnetic screen or magnetic blade fixed between two diamagnetic thin magnetic screens, pyrolytic or attached graphite type. by a thicker pyrolytic graphite magnetic screen, shielding from the corresponding stator magnet.

In one embodiment, the double solenoids are cylindrical and have a magnetic core of axially polarized cylindrical magnet, repulsively and coaxially arranged against the stator magnets that are identical to the cylindrical magnets, and the magnetic screens are made of permalloy or powder magnetic sheet. magnetic from NdFeB, fixed between two pyrolytic graphite-type diamagnetic thin magnetic screens, the thickness of the magnetic screen being calibrated to the limit of non-introduction of braking forces of their rotation through attraction with stator magnets.

- In another particular embodiment, the stator magnets are arranged with parallel polarizations, and the magnetic screens are made of magnetic powder magnetic sheet with Nd attached to a thicker pyrolytic graphite magnetic screen, shielding from the corresponding stator magnet and the magnetic screens of one rotor disk are offset from those of the other rotor disk with a magnetic screen width chosen quasi-equal to the distance between two adjacent double solenoids.

- In another embodiment, the magnets of the stator magnet pairs are all type plate with polarization along the length that is radially oriented but the solenoids are simple solenoids with or without magnetic core, of equal length to that of the stator magnets and arranged adjacent to the axis. of symmetry parallel to their NS polarization, in some non-magnetic corona-support crown housings.

- in another embodiment, with double solenoids with parallel axes perpendicular to the plane of the support crowns and with the antiparallel or simple spirals - with radial axes, the crowns with stator magnets are missing, existing pairs of static magnets polarized on their faces instead. with antiparallel polarizations as the core of the double solenoids and are mutually repulsive with respect to the stator magnets of the adjacent support crowns, the magnetic screens being formed of pyrolytic graphite or ferromagnetic magnetic sheet or neodym magnetic powder, fixed between two thin magnetic screens, pyrolytic graphite, about 1/2-M / 3 thickness from the thickness of the magnetic blade.

The advantage of using this type of magneto-electric generator consists in the fact that being multimodular, it can be realized with a high power, over 1 kW, corresponding to the electricity needs of an individual household, by the mechanical action of a wind turbine or hydraulics with a rotational power of magnetic screens significantly lower than in the case of rotating magnets relative to stator solenoids, due to the considerably smaller weight of magnetic screens and a braking magnetic interaction with the total magnetic field, smaller, corresponding to a better efficiency of converting mechanical energy into electricity.

The invention is further illustrated in connection with FIGS. 1-15, which represents: FIG. 1 is a vertical section view of one half of the magneto-electric generator according to the invention; FIG. 2, side view of a quarter rotor disc attached, of the magneto-electric generator in the first variant;

V 2 0 1 3 - 0 0 3 3 5 - 3 θ -®4- 2013

FIG. 3, a detailed view of a magnetic screen part of figure 2 of the generator in the first embodiment of variant I;

FIG. 4, a vertical section view of part of a generator module in the second embodiment of variant I;

FIG. 5, a vertical section view of part of a generator module in the second embodiment;

FIG. 6, top view of a linearly developed part, of a module in the third example of making the first variant of the generator;

FIG. 7, top view of a linearly developed part, of a module in the fourth embodiment of the first variant of the generator;

FIG. 8, top view of a linearly developed part, of a module in the third embodiment of the second variant of the generator;

FIG. 9, connection of the generator solenoids to obtain two-phase alternating current or DC;

FIG. 10 is an enlarged view of detail A of Figure 6;

FIG. 11, side view of a part of the support crown with platelet-type generator stator magnets; -fig.12, vertical section view of the generator in the third, simplified version;

FIG. 13, side view of a part of the support crown with double solenoids with bar magnet magnets of the generator of the first or third variant, in the case of the use of rotor screens without lamellar magnets; FIG. 14, top view of the marginal part with spacer rings of reciprocal positioning of two choroanesuport, one with stator magnets and one with double solenoids, of the generator in the first variant;

The magneto-electric generator G according to the invention has several modules M arranged with rotors on a common axis 4 and each made up of a circular row of 6- 6 'double solenoids with axis of symmetry parallel to axis 4 or single, 6 ", with axis of radial symmetry, inserted into the b-places of a non-magnetic 2-carrier crown and two circular rows of 5, 5 'stator magnets with a NS-polarization plate radially oriented, which fit them, arranged mutually attractive or mutually repulsive, and inserted into each a crown-support 1, respectively-1 ', in some recesses thereof, as well as a rotor having two rotor discs 9, 9' arranged parallel to the common axis 4 and having some magnetic screens 7, (7 ') special marginally arranged and equidistantly on non-magnetic discs c, (c '), with space between them corresponding to the size of a magnetic screen 7, (7'), rotor discs 9, 9 'enclosing double solenoids 6-6' or single 6 'to interrupts or periodically reverses the magnetic flux at their level.

Magnetic screens 7, (7 ') may be of pyrolytic graphite or other equivalent material, field deflector, or lamellar magnet e, (e') repulsively disposed with magnets 5, respectively-5 'and shielded on the side thereof. with a thin magnetic screen d, (d ') ferromagnetic, of permalloy sheet, mu-metal or ferritic stainless steel of thickness calculated corresponding to an interaction force with the stator magnet 5, (5') adjacent-minimum, or from deflector diamagnetic material field pyrolytic graphite or nickel oxide antiferomagnetic type. The thickness of the lamellar magnet e, (e ') is below 10mm and varies depending on the power of the 5, 5' stator magnets and the thickness of the thin magnetic screen d, (d ') is up to 1/3 of the thickness of the lamellar magnet e, (e') if it is ferromagnetic and up to ¹ / z of the thickness of the lamellar magnet is, (e ') if it is diamagnetic. The width of the magnetic screen 7, (7 ') is chosen (quasi) equal to the distance between the centers of two adjacent 6-6' or single 6 "double solenoids.

Also, the generator module M may have in one embodiment and (or only) a row of magnets 11-11 'or 12 arranged as the core of solenoids 6-6', respectively-6 ", in which case the magnetic screens 7, 7 ', are in this case from prolific graphite or magnetic sheet f, (f') from magnetic powder with Nd or ferromagnetic - from permalloy or mu-metal framed by two diamagnetic blades h, (h '), as in fig. 4. The shaft 4 is fixed in two bearings 3, 3 'fixed in a cage i' in the central area of some caps j, j 'fixed by a non-ferromagnetic cylindrical body k of a housing 10 through which the wires r of the solenoids pass. double 6-6 'or single 6', over which - after the proper interconnection of the r-wires, a ferromagnetic housing 8 of thin sheet is attached by means of circular spacers m, m '.

The thickness of the magnetic screen 7, 7 'is calibrated to the limit of non-introduction of braking forces of their rotation through attraction with 5, 5' or 11-11 'or 12 magnets.

In the case of the use of stator magnets 5, (5 ') longer than 70mm, so stronger, to use magnetic screens 7, (7') with lamellar magnet e, (e '), it is preferable to shield the pole of its repulsive interaction with the stator magnets 5, (5 ') to be made by a magnetic sandwich assembly d' of the permalloy or mu-metal ferromagnetic blades of less than 1mm thick and pyrolytic graphite blades of maximum 1mm thickness except the last blade from the stator magnets 5, (5 '), which is preferable to be chosen thicker, 2 + 5 mm. If variable thickness blades are used, the thickness of the ferromagnetic blades closer to the stator magnets 5, (5 ') must be decreasing, (smaller). The advantage is the possibility of reducing the total screen thickness q-2013-00335--

0 -04- 2813 magnetic 7, (7 ') by successive use of several ferromagnetic layers of "tightening" of magnetic field lines to lamellar magnets e, (e').

Double 6-6 'or single 6 "solenoids are arranged at the IOmm of each other and are interconnected in series or in parallel, then connected to an appropriate controller / inverter 13, known in itself, for adjusting / modifying the power parameters. electrical supplies provided.

In a variant I, according to the invention, the magneto-electric generator G for medium and low wind wind, has the module M formed as in figures 1-2 of two 1,1 'support crowns, non-magnetic with a circular row of n stator magnets 5, respectively- 5 'inserted equidistantly in some places of the coronaisisport 1, respectively-1' and attractively arranged, with NS polarizations antiparallel, for a pair of 5-5 'stator magnets. The support crowns 1, Γ with stator magnets 5, 5 'fit a row of n double solenoids, 6-6', formed as a pair of identical solenoids: 6, 6 ', arranged adjacent in places b of a non-magnetic corona support 2, with axis of symmetry perpendicular to the plane of the support crown 2, each between a pair of NS poles of the pair of 5, 5 'stator magnets and aligned with the antiparallel spirals, with a circular space of 5M5 mm distance between 6-6' double solenoids and magnets 5, respectively -5 '. Through this space is rotated by a circular row of magnetic screens 7, respectively-7 'arranged marginally and equidistantly, with space between them, on a non-magnetic disk c, (c') fixed on a common axis 4, which together with the magnetic screen 7, (7 ') forms a rotor disk 9, (9').

The non-magnetic discs c, (c ') to which the magnetic screens 7, (7') are attached can be made of aluminum, harness, bronze, plexiglass or other non-magnetic material but it is preferable to be made of non-metallic material, for example-from plexiglass or made of glass fiber reinforced epoxy resin.

In one embodiment of embodiment I, according to FIG. 1, the double solenoids 6-6 'are coreless and the magnetic screens 7, (7') are made of pyrolytic graphite, field deflector, or lamellar magnet e, <e ' ) disposed repulsively to magnets 5, respectively-5 'and screened on the side thereof with a thin magnetic screen d, (d') diamagnetic- of pyrolytic and / or ferromagnetic graphite - of permalloy, mu-metal or ferritic stainless steel of thickness calculated corresponding to an interaction force with the stator magnet 5, <5 ') adjacent-minimum and with the edges about 5mm larger than the lamellar magnet e, (e'), for fixing it with some n in the non-magnetic disk c, (c ') respectively. The lamellar magnet e, (e ') is made up of two parts and e ₂ , (e / and e ₂ ') face polarized and marginally attractive and the thin magnetic screens d, (d ') can be supported by a circular lower edge common, as in fig.2.

As shown in FIG. 1, the uncoated parts of the central magnetic screen e, (e ') reverse the direction of the magnetic field lines at the level of the double solenoid winding 6-6' when the magnetic screens 7 and 7 'pass through it, thus inducing induction current I, alternatively, biphasic, which can be used by means of suitable voltage stabilizers and current converters, which can be transformed into a continuous current of lower voltage but of higher intensity by means of rectifier diodes v inserted in the circuit of each phase, as in figure 9.

In order to obtain current of the same power but with higher voltage and lower intensity, the solenoids are interconnected according to the two phases, but by the separate insertion of the solenoids with even number and those with odd number, corresponding to the second phase.

In another particular embodiment of embodiment I, according to FIG. 4, the double solenoids 6-6 ', have a core of 11-11' magnet polarized on the faces and repulsively disposed towards the corresponding poles of the stator magnets 5, 5 ', and the magnetic screens 7, (7 '), are in this case from prolitic graphite or magnetic sheet f, (f') from magnetic powder with Nd (NdFeB, etc.), ferrite or ferromagnetic material (mu-metal, permalloy) fixed between two thin magnetic screens h, (h ') millimeter diamagnetics, (below 1cm thick) of pyrolytic graphite, their thickness being experimentally adjusted, through successive tests, to obtain a maximum effect of optimal shielding with minimum interaction forces between the screen. magnetic 7, (7 ') and stator magnets 5, (5') and magnets 11, (1Γ) respectively.

The role of the magnetic blade f, (f ') is to tighten the magnetic field lines and thus decrease their intensity at the 6-6' double solenoid level, with additional magnetic shielding, including the magnetic blade f, (f '), being given by thin magnetic screens h, (h ') of pyrolytic graphite.

The easy movement of the screen 7, (7 ') between the stator magnets 5, (5') and 11, (1Γ) is also due to the fact that their residual magnetic attraction on the magnetic plate f, (f) placed between them is achieved with equal opposing forces, which cancel each other out.

As shown in FIG. 4, the field lines of the poles of a pair of stator magnets 5-5 'and of a magnet 11 (11') parallelepiped or cylindrical, add up to the solenoid 6, (6 ') turns. When interposing a pair of magnetic screens 7, 7 'between the double solenoid 6-6' and the pair of magnets 5, 5 ', they reduce the magnetic flux Φ _Β at the level of the double solenoid turns 6-6', this variation generating an electric current + l, given by an electromotor voltage + e = -ΔΦ / Δί, and upon returning to the initial state, an electric current of the same value but of the opposite direction is generated, -I.

^ -2013-00355-

0> 4- 2013

Magnetic screens 7 and 7 'are placed planar-symmetrical, in these embodiments of variant I of the generator.

In another embodiment of embodiment I, with the 6-6 'coreless double solenoids, the magnetic screens 7, (7') are made of pyrolytic graphite or magnetic sheet f, (f) from magnetic powder with Nd (NdFeB, etc.) fixed between two thin magnetic millimeter screens h of pyrolytic graphite, as in Fig. 4 or attached by a magnetic screen h "of thicker pyrolytic graphite, shielding from the stator magnet 5, (5 '), as in fig. 5, and the rotor discs 9, 9 'are disposed on axis 4 with the magnetic screens 7 and 7' offset by a width of magnetic screen 7 chosen (quasi) equal to the distance between two adjacent 66 'double solenoids, the magnets of the stator magnets 5 - 5 'being arranged with parallel NS polarizations, in this case, as in fig. 6.

If an increase of the induced current is desired, the magnetic screens 7, 7 'can be made as in the first embodiment, from lamellar magnet e, (e') repulsively disposed with magnets 5, (5 ') and shielded from the side this with a thin magnetic screen d, (d ') ferromagnetic, the poles of the opposite face being attractive to the poles of the 5', (5) opposite magnet.

In this way, when they rotate simultaneously, if the magnetic screen 7 is interposed between a stator magnet 5 and a double solenoid 6-6 ', this solenoid is below the field lines of the opposite 5' stator magnet, which closes through of the lamellar magnet and of the magnetic screen 7 and vice versa: when by rotating the rotor discs 9, 9 'a magnetic screen 7' screens the action of the stator magnet 5 'on a double solenoid 6-6' next to it, simultaneously a corresponding magnetic screen 7 de-screens the action of the magnet stator 5 correspondent on this 6-6 'double solenoid, thus reversing periodically the meaning of the field lines at the solenoid level and generating alternating current which results in a two-phase total, by interconnecting the solenoids as in figure 9.

In another embodiment, II, according to the invention, the magneto-electric generator G has the module M formed as in figures 1-2 of two non-magnetic non-magnetic support rings 1, 1 ', with a circular row of n stator magnets 5, respectively- 5 'inserted equidistantly in some places of the crowns of 1, respectively-1' and attractively arranged, with the polarizations NS north, for a pair of 5-5 'stator magnets, but these crowns-support 1, 1' fit a row of n single solenoids 6 ", of length equal to that of stator magnets 5, 5 'and disposed adjacent with the axis of symmetry parallel to their NS polarization, in places b of a non-magnetic support-crown 2, with a circular space of 5 : 15 mm distance between single solenoids 6 "and magnets 5, respectively -5 '. Through this space is rotated by a circular row of magnetic screens 7, respectively-7 'arranged marginally and equidistantly, with space between them, on a non-magnetic disk c, (c') fixed on a common axis 4, which together with the magnetic screen 7, (7 ') forms a rotor disk 9, (9').

In one embodiment of variant II, the simple 6 "solenoids are coreless and the magnetic screens 7, (7 ') are as in FIG. 5, a diamagnetic screen h "of pyrolytic graphite, field deflector, delimited in the part from the solenoids 6" by a lamellar screen f "ferromagnetic or of powder of NdFeB, of thickness calculated corresponding to an interaction force with the stator magnet 5, (5 ') adjacent-minimum, with the edges about 5mm larger than the diamagnetic screen h, for fixing it with some n in the non-magnetic disc c, (c') respectively. The lamellar magnetic screens f ”can be supported by a common lower circular edge, as in figure 2.

In another particular embodiment of embodiment II, the 6 "solenoids have a core 12 paralleled or cylindrical magnet, polarized on the ends, with the NS polarization parallel to that of the 5, 5 'stator magnets, repulsively disposed towards them, and the screens magnetic 7, (7 '), are in this case pyrolytic graphite or magnetic foil f, (f) magnetic powder with Nd (NdFeB, etc.) fixed between two thin magnetic screens h, (h') millimeter, graphite pyrolytic, about 1/3-M / 2 in thickness from the magnetic blade thickness f, (f '), as in Fig. 4, the thickness of these screens being experimentally adjusted to obtain a maximum optimal shielding effect with minimum interaction forces. between the magnetic screen 7, (7 ') and the stator magnets 5, (5') and respectively-with the magnets 12.

Magnetic screens 7 and 7 'are placed planar-symmetrical, in these embodiments of variant II of the generator.

As shown in Figure 5, the field lines of a pair of 5-5 'stator magnets and of a magnet 12 are summed at the solenoid 6' level.

When a pair of 7, 7 'magnetic screens are interposed between the 6 "solenoid and the 5, 5' magnet pair, they reduce the magnetic flux Φ _Β at the 6" solenoid turns, this variation generating an electric current + l, given by a voltage. electric motors + e = -ΔΦ / Δΐ, and upon returning to the initial state, a similar electric current of the same value but of opposite direction is generated, -I.

In another embodiment of Variant II, with simple 6 "coreless solenoids, the magnets of the 5-5 'stator magnets are arranged with the NS polarizations antiparallel, as in figure 8, and the magnetic screens 7, (7') are pyrolytic graphite, magnetic foil f, (f ') magnetic powder with Nd 2 0 1 5 - 0 0 3 3 5 - 3 0 -04 (NdFeB, etc.) fixed between two thin magnetic screens h, (h') millimetric, from pyrolytic graphite, as in Fig. 4 or lamellar magnet e, (e ') repulsively disposed with magnets 5, respectively-5' and screened on the side thereof with a thin magnetic screen d, (d ') ferromagnetic , and the rotor discs 9, 9 'are disposed on the axis 4 with the magnetic screens 7 and 7' offset by a width of magnetic screen 7 chosen (quasi) equal to the distance between two adjacent solenoids.

In this way, when they rotate simultaneously, if the magnetic screen 7 is interposed between a stator magnet 5 and a solenoid 6 ", this solenoid is below the field lines of the opposite stator magnet 5 'which close through its center and vice versa: when by rotating the rotor discs 9, 9 'a magnetic screen 7' screens the action of the stator magnet 5 'on a solenoid 6 "right beside it, simultaneously a corresponding magnetic screen 7 de-screens the action of the corresponding stator magnet 5 on this solenoid 6", reversing thus periodically the meaning of the field lines at the level of the solenoids and generating alternating electric current that results in a two-phase total, by interconnecting the solenoids as in figure 9, with the possibility of transforming into direct current through diodes. To obtain single-phase electric current, it is necessary to invert the connection ends of the odd-numbered or even-numbered solenoids.

Also, the 5 or 5 'stator magnets on a 1, (1') stator support can be arranged and attractive to each other, unless rotor magnetic shields with lamellar magnet e, (e ') are used in both variants, as in FIG. 7 and 8, with the difference that the spiral position of the 6-6 ', 6-order number 6 solenoid windings is reversed (the connections of these solenoids with the odd number solenoids are reversed).

- instead of pyrolytic graphite, superconducting ceramics can be used at room temperature or - with a lower result, a diamagnetic magnetic field deflector mixture according to the document US 2006/0083931 A1. Also, 6-6 'or 6 "single solenoids can also have a ferromagnetic core.

Also, for the 7, 7 'magnetic screens, with poorer results, the combination of a pyrolytic graphite diamagnetic screen and a silver-plated copper instead of a ferromagnetic screen can be used, because the magnetic flux induced by the residual field lines that have passed by the pyrolytic graphite screen, induce at the level of the silver-plated copper screen as opposed to a magnet 5, (5 '), electric microcurrents that generate a magnetic flux of the opposite direction to that of magnet 5, (5'), that is, shielding of the flux of the magnet to the solenoid 6-6 ', (6 "), correspondent.

Any other magnetic screen that achieves efficient shielding with minimal interaction force with stator magnets can also be used; for example W-zirconate or Fe powder screens.

-Also, instead of the circular set of 5, 5 'stator magnets, two radially polarized circular crown magnets can be used, which has the advantage that by creating a homogeneous magnetic field throughout the rotation of the 7, 7' magnetic screens, it is greatly reduced the braking force generated by a possible improper calibration of the magnetic screens 7, 7 'from the magnetic screen e, respectively e' and the thin ferromagnetic screen d, (d ') attached, due to the lack of field inhomogeneities.

- In a simplified version, III, according to figure 12, the support crowns 1, 1 'with the 5, 5' stator magnets of an IVI module of the generator, are missing, these being replaced with 11-11 'magnets polarized on the faces, arranged mutually repulsive or with 12 cylindrical or parallelepiped magnets polarized on the ends, disposed reciprocally repulsive, inserted inside the solenoids 6-6 ', respectively-6 ", and the magnetic screens 7, (7') are made of pyrolytic graphite or magnetic foil. , (f) from magnetic powder with Nd (NdFeB, etc.) or from permalloy or mu-metal, fixed between two thin magnetic screens h, (h ') millimeter, pyrolytic graphite, about 1 / 2- ^ 1 / 3 of the thickness of the magnetic blade f, (f '). the windings of the solenoids 6 and 6 'from the same axial direction must be symmetrical with respect to the rotor disk 9 of them. As a magnetic screen 7, (7 ') can also be used as W zirconate, but this is expensive.

Preferably, the total thickness of a magnetic screen 7, (7 ') does not exceed 8mm and the distance between them and a magnet 5 or 5', as well as the distance between them and the solenoids 6-6 ', or 6 "is as long as possible. small, preferably about 1mm.

Also, the width of a magnetic screen 7, (7 ') can be chosen and double the width of a 6-6' or 6 "solenoid if three-phase current is desired through their proper interconnection.

Magnets 5, 5 'can be large in principle, but to avoid strong interactions between them, they can have parallelepiped dimensions of (5CU80) x (25 + 50) x (10 ^ -30) with polarization parallel to the length, 6-6 'double solenoids or 6 "single solenoids with corresponding dimensions, approximately equal.

The thickness of the wire and the number of turns of a solenoid can be determined experimentally, depending on the value of the induced current and the desired voltage, with the safety rule: 2A / mm ² , the preferred number of turns per solenoid being about 100 turns.

- For a good stability of fixing the rotor discs 9, 9 'on the axis 4, with the support ring with 6-6' or 6 "solenoids between them at the preset distance, they can be used, by fixing on the axis 4-as in fig. 8, some spacer bushes o, o 'which fit in pairs the rotor discs 9, 9' having a washer g for fastening with rivets of the non-magnetic discs c, (c ') of the respective rotor disc, the spacer bushes o' having ^ -2013-00335- ³ · · * - aa the outer end of the washer in contact with the bearing 3, respectively-3 'fixed on the end of the shaft 4, on which is finally a screw nut p, (p'). Also, the body of the spacer bushes o, o 'can be fixed by the shaft 4, whose body can also be of square section, by means of rivets n, which also give the correct reciprocal angular positioning of the rotor discs 9, 9', and for a prohibits the stable re-established pattern of the support crowns 1, Γ with stator magnets 5, 5 'and 2 - with 6-6' or single 6 "double solenoids, on the edge of which is a t-ring, respectively - made of aluminum, 1-3 mm thick, with screw holes s and cylindrical body k of housing 10.

For the mounting in the housing 10 of the support crowns 1, Γ and 2 to be made suitable, with the positioning of the solenoids 6-6 'or 6 "next to a pair of stator magnets 5, 5', the edge of the ring-spacer t, t adequately profile, in the form of rectangular or triangular teeth with spaces equal to their width, so that by intersecting the edges of the spacer-rings t, the support-rings 1, T and 2 are positioned and angled in the appropriate functional way, corresponding to the example of the chosen generator (fig. 14). At the same time, the spacer rings t, effectively resist the force of interaction between the 5 and 5 'stator magnets.

- For the stability of fixing the 5, 5 'stator magnets on the support-crown 1, respectively-T, it is advisable that the distance of 5-10 mm between their adjacent edges be partially occupied by a ferromagnetic screen q, of ferrite-stainless steel or another steel with low C content, as in FIG. 11, thickness% (preferably 2/3) of the crown-support thickness 1.

Instead of bearings 3, 3 'two magnetic bearings can be used, with conical magnets in repulsion. -The assembly of the component parts of the generator is done as follows:

- the support crown 1 is inserted with the stator magnets inside the cylindrical body k of the housing 10 and is fixed with screws;

- the first rotor disc 9 is inserted with spacer bushes o, o 'on the shaft 4 and is fastened with n rivets or screws thereon and then the end of the shaft 4 is fixed in the bearing 3 in the cage i of the cover j of the housing 10;

- the support ring 2 with solenoids is inserted in the cylindrical body k of the housing 10 until it reaches the spacer ring Γ in contact with the spacer ring I of the support ring 1, with the profiled edge interlocked with the profiled edge thereof and is fastened with screws again. then the wires f of the solenoids are removed through the z-holes in the spacer ring t and from the cylindrical body k of the housing 10;

- the second rotor disk 9 'is disposed on the shaft 4 with a bushing - spacer o in contact with the bushing spacer o of the first rotor disk 9 and is fastened with rivets n or screws thereof;

- the disk crown 1 'is inserted with the stator magnets inside the cylindrical body k of the housing 10 and is fixed with screws, with the spacer ring t with the contoured edge intersected with the corresponding edge of the spacer ring t of the support ring 2 with solenoids;

- the operations are repeated by inserting the following disk crowns until the insertion and fixing of the last disk crown Γ;

-the screw j 'of the housing 10 of the cylindrical body k is screwed, with the bearing 3' of the cage i 'fixed on the corresponding end of the shaft 4 and then the electrical connections between the solenoid wires f are made, on the outside of the housing 10 and then fastens the ferromagnetic housing 10 'of protection, the wires for the collection of the generated electric current being connected to a suitable coritroller / inverter.

Coupling to a motor is preferable to a higher speed, which gives a faster variation of the magnetic flux and thus a higher power. Also, in the case of direct coupling to the motor, it is preferable to do this by means of an inertial rotor, in particular flywheel, which ensures (almost) the rotational speed constancy.

Claims (13)

1. Magneto-electric generator for medium and low wind wind, consisting of modules (M) with two circular rows of n stator magnets (5, 5 ') arranged evenly on a crown-support (1), respectively- (l) ') non-magnetic and a row of n solenoids with or without core, interconnected in series or in parallel adequately to obtain a two-phase or single-phase alternating current, fixed in a non-magnetic coronaanport (2), with a circular space of 5 ^ -15 mm distance between solenoids and magnets (5) or (5 '), rotating a rotor disk (9, 9') with magnetic screens (7, 7 ') arranged marginally and evenly, with space between them corresponding to the size of a screen magnetic (7, 7 '), on a non-magnetic disk (c, c') fixed on a common axis (4) fixed in two bearings (3, 3 ') fixed in a cage (i, i') in the central area of caps (j, j ') of a housing (10) with non-magnetic cylindrical body (k), characterized in that the magnets per the stator magnets echoes (5-5 '), are plate type with NS polarization radially oriented length and the solenoids are double solenoids, (6-6'), formed as a pair of identical solenoids (6, 6 '), arranged adjacent in non-magnetic support bays (b) of the support ring (2), with axis of symmetry perpendicular to its plane, each solenoid (6, 6 ') being between a pair of NS poles of the pair of stator magnets (5, 5') and being matched with the antiparallel spirals. 2. Magneto-electric generator according to claim 1, characterized in that the double solenoids (66 ') are core-free, the stator magnets (5) and (5') have mutually antiparallel polarizations, and the magnetic screens (7, 7 ') are made of lamellar magnet (e, e ') consisting of two parts (they and e ₂ ) respectively- (e / and e ₂ ') repulsively disposed towards the corresponding poles of the magnets (5), respectively- (5 ') and shielded on the side from the stator magnets (5) respectively- (5 ') with a thin magnetic screen (d, d') diamagnetic or ferromagnetic, of thickness calculated corresponding to a minimum interaction force with the adjacent stator magnet (5, 5 '). 3. Magneto-electric generator according to claim 1, characterized in that the double solenoids (66 ') have a magnet core (11-11') polarized on the faces and repulsively disposed towards the corresponding poles of the stator magnets (5) and (5 ') having mutually polarized polarizations, and the magnetic screens (7, 7'), are of magnetic sheet (f, f) fixed between two thin magnetic screens (h, h ') diamagnetic, pyrolytic graphite type, their thickness being chosen corresponding to obtaining a maximum optimum shielding effect with minimum interaction forces between the magnetic screen (7, 7 ') and the stator magnets (5, 5') and -the magnets (11.11 ') respectively. 4. Magneto-electric generator according to claim 1, characterized in that the magnets of the stator-magnet pairs (5-5 ') are arranged with parallel polarizations, and the rotor discs (9, 9') are disposed on the axis (4) with magnetic screens (7 and 7 ') made of magnetic sheet (f, f') of magnetic powder with Nd attached to a magnetic screen (h ") of thicker pyrolytic graphite, shielding from the stator magnet (5, 5 ') corresponding to the magnetic screens (7) and (7 ') offset with a width of magnetic screen (7) chosen quasi-equal to the distance between two adjacent double solenoids (6-6'). 5. Magneto-electric generator, according to claim 3 or 4, characterized in that the stator magnets (5) and (5 ') of a support ring (1), respectively (T), are arranged with the polarization mutually opposite. 6. Magneto-electric generator for medium and low wind wind, consisting of modules (M) with two circular rows of n stator magnets (5, 5 ') arranged evenly on a crown-support (1), respectively- (T) ) non-magnetic and a row of n solenoids with or without core, interconnected in series or in parallel adequately to obtain a two-phase or single-phase alternating current, fixed in a non-magnetic corona-support (2), with a circular space of 5 + 15 mm distance between solenoids and magnets (5) or (5 '), rotating a rotor disk (9, 9') with magnetic screens (7, 7 ') arranged marginally and evenly, with space between them corresponding to the size of a magnetic screen ( 7, 7 '), on a non-magnetic disc (c, c') fixed on a common axis (4) fixed in two bearings (3, 3 ') fixed in a cage (i, i') in the central area of some lids (j, j ') of a housing (10) with non-magnetic cylindrical body (k), characterized in that the pair magnets stator magnets (5-5 '), are plate type with polarization on length that is radially oriented and solenoids are simple solenoids (6 ") of length equal to that of stator magnets (5, 5') and arranged adjacent to the axis of symmetry parallel to their NS polarization, in some non-magnetic carrier bores (b). 7. Magneto-electric generator according to claim 6, characterized in that the double solenoids (6 ") are core-free, the stator magnets (5) and (5 ') have mutually parallel polarizations, and the magnetic screens (7, 7') are made of lamellar magnet (e, e ') consisting of two parts (θ! and e ₂ ) respectively- (e / and e ₂ ') repulsively disposed with respect to the corresponding poles of the magnets (5), respectively- (5 ') and shielded on the side of these magnets with a thin magnetic screen (d, d ') diamagnetic or ferromagnetic, thickness calculated corresponding to an interaction force with the adjacent stator magnet (5, 5') - minimum. 2013- 2013-00335 · - 3 0 -04- 2 «3 8. Magneto-electric generator, according to claim 6, characterized in that the simple solenoids (6 ") have a magnet core (12) polarized on the ends and repulsively disposed towards the corresponding poles of the stator magnets (5) and (5 '). ) having the polarizations mutually parallel, and the magnetic screens (7, 7 '), are of magnetic sheet (f, f') fixed between two thin magnetic screens (h, h ') diamagnetic, pyrolytic graphite type, their thickness being chosen corresponding to the obtaining a maximum optimal shielding effect with minimal interaction forces between the magnetic screen (7, 7 ') and the stator magnets (5, 5') and (12). 9. Magneto-electric generator according to claim 6, characterized in that the magnets of the stator magnets (5-5 ') are arranged with the polarization antiparallel, and the rotor discs (9, 9') are disposed on the axis (4) with magnetic screens (7 and 7 ') made of magnetic powder (f, f') of magnetic powder with Nd attached to a magnetic screen (h ") of thicker pyrolytic graphite, shielding from the corresponding stator magnet (5, 5 ') , the magnetic screens (7) and (7 ') being offset by a width of magnetic screen (7) chosen quasi-equal to the distance between two adjacent solenoids (6 "). 10. Magneto-electric generator, according to claim 8 or 9, characterized in that the stator magnets (5) and (5 ') of a support crown (1), respectively- (T), are arranged with mutually opposite polarizations. Magneto-electric generator according to any one of claims 1-h4 or 6 ^ -9, characterized in that the stator magnets (5, 5 ') form a circular ring-like magnet (5 "). 12. Magneto-electric generator for medium and low wind wind, consisting of modules (M) with n stator magnets (11.11 ') arranged evenly on a non-magnetic support-crown and a row of n solenoids, interconnected in series or In parallel, adequately to obtain a two-phase or single-phase alternating current, fixed in a non-magnetic support-ring (2), with a circular space of 5-M5 mm distance between the support-crown, for rotating a rotor disk (9, 9 ') with magnetic screens (7, 7') arranged marginally and evenly, with space between them corresponding to the size of a magnetic screen (7, 7 '), on a non-magnetic disk (c, c') fixed on an axis (4) common fixed in two bearings (3, 3 ') fixed in a cage (i, i') in the central area of the covers (j, j ') of a housing (10) with a non-magnetic cylindrical body (k), characterized by that, the mentioned solenoids are double solenoids (6-6 ') with parallel axes perpendicular to the crown plane the support beams (2) and the antiparallel spirals, and the stator magnets (11-11 ') polarized on the faces are arranged with the antiparallel polarizations as the core of the double solenoids (6-6') and are mutually repulsive towards the stator magnets (11 -11 ') of the adjacent support crowns (2), the magnetic screens (7, 7') being made of pyrolytic graphite or magnetic sheet (f, f ') or ferromagnetic magnetic powder with neodym, fixed between two thin magnetic screens (h, h ') millimeter, pyrolytic graphite, about 1/2 - = - 1/3 of the thickness of the magnetic blade (f, f'). Magnetic screen for the magneto-electric generator according to claim 1, 2, 6 or 7, having an Iamelar magnet (s, e '), characterized in that the polarized Iamelar magnet (s, e') is shielded on the face. one side with a magnetic sandwich sandwich type screen made of ferromagnetic blades of permalloy or mu-metal below 1mm thick and pyrolytic graphite sheets up to 1mm thick, except for the last blade from the stator magnets (5, 5 '), chosen thicker.