LV14507B - Method and device for turn and orientation of windmill blades - Google Patents

Description

Description of the Invention

The invention relates to wind generators, in particular to a device and a method for rotating a wind generator's wing around its axis and orienting it parallel or perpendicular to the direction of the wind acting on the wing. The invention is based on the idea of using magnets to rotate the wind generator's wing around its axis and to orient it, given that the opposite poles of the magnetic field tend to zoom in and the equivalents to repel.

Analysis of prior art

Many methods of orienting the wind generator wings by rotating them around their axis are known, but they are mainly mechanical methods. The turning devices / systems are very different in construction and involve the use of different transmissions, levers and rods, but they have in common that the wind generator spindle is mounted in bearings on the rotor and can rotate with the rotor axis relative to the ground and rotate the generator. can also rotate around its axis.

The patent applications (EP 1273798, EP 1205661, EP 1580425) describe wind energy devices in which the wind perception impeller is equipped with a plurality of blades attached to a lattice support structure, which as a whole rotates about a vertical axis, said individual wings in the process of rotation of the support structure. independently of one another their position relative to the wind direction within a range from perpendicular to the wind position to a position substantially parallel to the wind direction, ie 0 to 90 degrees to the relevant plane of the supporting structure.

EP 1273798 proposes the use of locking elements to limit the angle of rotation of the wings with respect to the plane of the respective wing. Each wing is freely pivotable relative to its respective axis of rotation, which is closer to the edge of one wing, while its pivoting is further limited by a single locking member relative to which the wing can move freely.

EP 1205661 describes several variants of a wind blade impeller design rotating about a vertical axis and comprising a radially anti-axis rod system to which a rotating blade system is mounted at one or more levels along the wheel height and / or radius, that the flow of fluid acting on the blade system causes the wheel to rotate about an axis, since all the blades in the wheel rotation move from the first position with high forehead resistance (environmental braking force) to the second position with low forehead resistance, causes rotation of the impeller as a result of the effects of wind flow.

EP 1580425 describes a wind turbine impeller design comprising a plurality of blade systems which are mounted on a support plate and automatically rotate about horizontal axes in the process of operation, i.e., when moving against the wind, they automatically rotate so that the resistance decreases. It is secured by means of upper and lower bearings, which are fixed to the support plate below and above its plane. These bearings are rotatably supported respectively by upper and lower shafts, which are circularly displaced beneath and above the support plate, to which a plurality of blades are fixed in pairs by means of the respective shafts so that, for example, said pairs are displaced 90 degrees. The upper and lower gears are mounted at the ends of the respective shafts in such a way that the gears work in pairs and the bearing plate is permanently a plane of symmetry of the upper and lower half blades.

The wind turbine impeller designs with a vertical axis of rotation are also described in several Latvian patents, e.g., LV 12775, LV 12972 and EP 1348075, which is essentially an analog of LV 12775 after the patentability examination of the invention. In addition, the design of several impellers without structural details is available on the website of KRONEŠI www.kronesi.lv.

Patent LV12972 describes a lattice rotor-type wind engine comprising a windwheel with power elements in the form of turbine blades mounted on a vertical shaft and forming blade (wing) blocks evenly spaced around the rotor rim. The wind turbine proposed in this patent is characterized in that it is equipped with 2-3 rigid lattice blocks with 3-4 rigid aerodynamic turbine blades in each block, the blocks being positioned in the direction of movement on one side of the diameters connecting the peripheral blade end of the lattice and are shifted relative to these diameters by the half-length of the blade chord, while the dimensions of the blade chord forming the lattice have a size determined by a selected shading ratio of not more than 0.6.

Several patent applications of the invention (WO 2009003537, WO 2004018872, WO 2006132923, EP 0957265) provide solutions to the above-mentioned problem of rotation of wind turbine wings in the case of a vertical axis wind turbine consisting of two parts: a rotor with a turbine blade for wind capturing . turbine blades in a position in which the wind flow energy acts in the opposite direction to that of the turbine rotation and directs the wind from the inert part of the rotor to the effective part of the rotor, preventing back pressure and accelerating the flow of the wind.

Vertical axis wind turbines are also known (US 2002109358, US 20032099, whose stator contains a plurality of vertical blades tangentially fixed around the rotor assembly so that the wind flow that generates the propulsion force of the rotor is not restricted, whereas the wind flow which can brake the rotor motion DE 3631709 also defines a wind power installation comprising a tower with a turbine wheel mounted on a vertical shaft on its upper part, which is equipped with a vertical blade, which is mounted with the ability to rotate it around the turbine wheel to cover part of the turbine wheel, such as half its diameter .The rotating sleeve is rotated by the engine, partially revealing the turbine wheel from the latch. The sleeve rotation is controlled electronically depending on the wind direction. airflow against airflow is prevented pressure on the turbine, however, does not provide the most efficient way to collect and direct airflow to the turbine blades.

Summary of the Invention

The proposed device for rotating and orienting the wind turbine blade towards or to the wind, depending on the rotation phase, is characterized in that the wind generator spam (s) are fitted with permanent magnets whose N-poles are directed outwardly and move between two stationary positions, for the wind generator housing, rigid disks having electromagnets mounted on the upper and lower sectors, with the S-pole of the two stationary disks facing inward on the upper sector and inward on the lower sector the N-pole of the placed electromagnets, said electromagnetic pole being alternated by an electronic power supply system for supplying the electromagnets, depending on the phase of rotation of the wings.

Depending on where the wind generator wing magnets are located during rotation, they are either attracted or ejected by stationary disk magnets and, as these magnets move, rotate their wind generator blades around their axis and orient their flat surface either perpendicular to the wind so as to produce maximum resistance, or the plane of the wings is oriented parallel to the wind direction so as to produce minimal wind resistance, wherein said electromagnetic pole is provided by an electronic power supply system for electromagnet supply depending on the rotation phase of the wings.

The invention is illustrated schematically in the various phases of wing rotation in Figures 1 to 4, where the following explanations are replaced by capital letters:

A - stationary magnets with N-poles facing outwards (relative to axis of rotation);

B - stationary disks, in the upper sector of which the S-pole of the electromagnet is directed inwards and in the lower sector - outwards;

C - flat surface of the wing moves parallel to the wind direction;

D - the S-pole of the electromagnet in the upper stationary disk sector is directed inwards;

E - the N-pole of the electromagnet in the lower stationary disk sector is directed inwards;

F - flat surfaces of all wind generator wings are rotated parallel to the wind direction;

G - the wings have fixed magnets with N-poles facing outwards;

E - stationary discs with opposite directions of electromagnetic poles in the upper and lower zones;

J - the wing, moving in the pre1 wind, is oriented with the flat surface parallel to the wind.

Using a magnetic method to rotate the wind generator spam (s) around its axis and to orient the flat surface of the wing perpendicular to the airflow during one part of its rotation period, and to move the wing under the influence of the wind, ie airflow, with maximum force; but moving with minimal resistance to the wind in the part of the rotation period where the plane of the wing is oriented parallel to the airflow is related to providing said electromagnetic polarity depending on the phase of rotation of the wings or the location of permanent magnets attached to the wind generator spam (s) at a given point in time. It is intended to be provided by an electronic power supply system for supplying electromagnets, which is not a simple task but a practicable task.

Example of implementation of the invention

The wind generator consists of (Figs. 1 and 2): the power of the rack is transmitted by two rotors, each of which has four (Fig. 2) wings of the wind generator, which can rotate about their axis in their place in the rotor (Fig.4). The wind generator blade is mounted on the rotor by means of bearings and can rotate both with the rotor axis relative to the ground and rotate about its axis. Each wing of the wind generator has a permanent magnet attached to it, with the Npole facing north (Fig.4). When these wing magnets move in the upper portion between two stationary disks (Fig. 4) associated with the wind generator housing and having electromagnets mounted in the upper portion of the sector and at a given moment inducing an S-pole in the wing, the N- the pole is tightened and brought closer to the S-pole of the electromagnet on a stationary disk. As a result, the flat surface of the wings is rotated and oriented perpendicular to the wind flow (Fig. 4) and the wing is moved with maximum force in the direction of the wind, thus turning the power generator at maximum torque.

When these wing magnets move in the lower part between two stationary disks (Fig. 1) connected to the wind generator housing and having the N-pole (Fig.4) facing the inward position of the electromagnet mounted in the lower part of the sector, the wing magnet N- the pole is pushed away from the stationary disk N-pole. As a result, the flat surface of the wings is rotated and oriented parallel to the wind flow and the wing with minimum resistance is rotated perpendicular to the wind direction.

In cases where the wind speed reaches storm force and the wind generator is destroyed, changing the direction of the electric current changes the position of the electromagnetic poles on the top of the stationary discs and creates an N-pole inside the disk. In this case, the flat surfaces of all the wind generator wings are rotated and oriented parallel to the wind direction and their resistance to the air flow is minimal (Fig.3).

The method and apparatus of the present invention appear to be simple in nature but electronically complex to implement an electromagnet power supply circuit. However, it should be emphasized that the decisive mechanical link between the individual elements of the machine and the inertia forces do not cause the problem of rotating and orienting the wing around its axis at the beginning and end, as would be the case if the wings are rotated and oriented around its axis only mechanically direction acting on the wing. The elements of the magnetic system used (permanent magnets and electromagnets) must be sealed so that the effects of the atmosphere (humidity, sea water, snow, etc.) cannot affect their long-term performance. The implementation of the method involves low material volume, low weight, compactness, low number of moving parts, easy maintenance and simple in-service repair. By changing the magnetic pole top of the stationary disk drive from the N-pole to the S-pole during storm and excessive wind, the flat surface of the wind generator's wings can be oriented parallel to the wind at any position relative to the ground, thus preventing the wind generator demolition of individual wings or the entire wind generator. All of this process is electronically controlled through an appropriate on / off circuit for electromagnets, based on the results of the wind generator operation process control.

Analogously to the example described above, you can create a wind generator wing rotation system using a magnetic field to place permanent magnets on stationary pillars but electromagnets on wings, or alternatively to place both magnets on the said pillars and wind turbine wings, but in the latter case an appropriate electromagnetic power supply electronic system.

Claims (2)

1. A device for rotating and orienting the wind turbine blade towards or into the wind, depending on the phase of rotation, characterized in that the wind generator spam (s) is fitted with permanent magnets whose N-poles are directed outwards and move between the two stationary wings. for stationary discs connected to the wind generator housing and having electromagnets mounted in the upper and lower sectors, the S-pole of the two stationary disks being positioned inwards in the upper sector and inward in the lower sector directed to the N-pole of the electromagnets therein, said electro-magnetic pole being provided by an electronic power supply system for supplying the electromagnets, depending on the phase of rotation of the wings. A method for rotating and orienting a wind turbine blade using the device as defined in claim 1, characterized in that, depending on where the wind generator blade magnets are located during rotation, they are either attracted to or disengaged from the stationary disk magnets and as a result, these magnets are rotated around their axis and the wind generator's wings are rotated and their flat surface is oriented either perpendicularly to the wind, thus providing maximum resistance, or the flat surface of the wings is oriented parallel to the wind direction, thus providing minimal wind resistance having said electromagnetic pole alternating depending on the wings rotation phase, provided by an electronic power supply system for supplying the electromagnets.