RU2453727C1 - Horizontal turbine wind-powered generator - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: horizontal turbine wind-powered generator comprises a support mast, on the top of which there is a fixed stator and a rotor with a vertical axis of rotation, and also a turbine with sail-type elements. The turbine represents a horizontal disc with at least two concentric rows of sail-type elements. Sail-type elements are installed with an equal pitch along one concentric circumference from the top, and along the other one at the bottom along the bearing disc surface in the form of trihedral pyramids. Pyramid bases are cut, and one of faces is open, radially directed or coaxial to the turbine radius, and forms a right or blunt angle with the disc. Pyramid-sail elements of different concentric rows have a relative isogonal displacement.

EFFECT: invention makes it possible to increase stability of wind-powered plant operation under unstable and extreme atmospheric conditions without application of an external force for start-up, and also to increase capacity, structural strength and reliability of a device.

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Description

The invention is used to generate small and medium-sized industrial and household electricity capacities from a renewable natural source, namely air flows, primarily in unstable and extreme aerodynamic conditions of the continental and close to it due to difficult atmospheric climate features.

The essence of the technical solution consists in the fact that the turbine of a wind energy device (GTV-generator) is a horizontal disk, at the top and bottom of this bearing surface in at least two concentric rows with equal pitch are installed trihedral pyramidal-sailing elements, at the base of which the corresponding through holes. One of the faces of these sailing elements is open, radially directed or coaxial to the radius of the turbine, forms a right or obtuse angle with the surface of the disk. The same elements of different rows have a relative equiangular displacement.

The invention relates to wind energy generators with an axis of rotation of the rotor that does not coincide with the direction of the wind.

From the development of technology, however, it is known that 91% of wind power plants and power modules used in practical energy belong to a different class of devices in which the axis of rotation of the rotor coincides with the direction of the wind (HAWT units with vane, mainly propeller, turbines). Such a unilaterally deformed orientation to this class of devices has led to narrowly limited areas of their application, namely, to use in a few areas with favorable weather conditions, in which atmospheric winds have a sufficient speed, stable in magnitude and direction. These territories include coastal strips and shelf in the eastern United States, Canada and China, in the northwestern countries of Europe.

In other regions of the world, especially continental, where medium-speed winds prevail, alternating with vortices and squalling gusts, often changing their size and direction, turning into obliquely rising or falling flows at the junction of atmospheric fronts, HAWT installations are used extremely rarely and have no development prospects. An insurmountable drawback of propeller wind generators is the jump in their drag when switching to work in conditions of strong winds, which reduces their efficiency by 25-30 or more percent. In such operating modes, as well as with obliquely rising or falling air flows and vortices, this class of devices completely squanders its advantages, and its organic disadvantages are exacerbated.

It has been established theoretically and experimentally that a wind turbine class with an axis of rotation of the rotor perpendicular to the wind direction (VAWT units or wind rotor turbines) is more promising in terms of operability in difficult atmospheric conditions, typical for most territories of the planet and, above all, regions with a continental climate, have today not been exhausted a resource for improving aerodynamic qualities. The first conclusion follows from the fact that VAWT installations, having a lower sensitivity threshold, do not require orientation to the wind, which is a decisive factor in conditions of unstable air flows, vortices, pulsations, and fluctuations in the atmosphere; the second conclusion follows from the principle of their action, based on the difference in the aerodynamic properties of the sailing elements in diametrically opposite positions relative to the common axis of rotation. Having, in addition to the vertical position of the rotor shaft, the second common distinguishing feature, consisting in the fact that the aerodynamic (sailing) elements of all known wind turbine turbines are coaxial to the common axis of rotation, VAWT units can be divided into two types.

The first orthogonal type of VAWT plants includes turbines similar to high-power wind farms (patent RU No. 2331793), a wind rotor with ladle wing blades (patent RU No. 2276283) and a generator (patent WO No. 2007/121904). A feature of all these devices is the changing windage (streamlining) of the aerodynamic elements under the influence of the incoming air flow. Their stable operation is possible exclusively in an ideal environment, when the wind speed has an optimal value, is constant in magnitude and direction. The slightest deviation of wind speed in one direction or another causes malfunctioning or delay in the operation of mechanisms and knots for winding sails onto drums, closure of wing blades, and a change in the aerodynamic elements streamlining. In a real atmosphere with its vortices and turbulences, phenomena of increasing vibration and destructive resonance occur. In the indicated wind rotors, the turbines are attached to the rotor shafts by means of frame structures, radial traverses or crosses. Their insufficient rigidity and strength can lead to the destruction of turbines and deformation of rotors during strong, stormy and hurricane winds. It is only necessary for such units to stop for the time of calm and weak winds, as its new launch becomes impossible without the use of external force. Otherwise, the turbines will endlessly oscillate with respect to the vertical axis of rotation.

The second non-orthogonal type should include such constructions of the same class of wind turbines as Savonius blades (website: www.enersis.ru, section “VRTB - Bolotov wind rotor turbine”), rotor wind turbine (patent RU No. 22210000), whose sailing elements fixed directly to the vertical rotor shaft. A typical representative of non-orthogonal windrotors or one of the modifications of the Savonius blades is a turbine with vertically elongated cup-shaped sailing elements (US patent No. 20090167028). The fastening of its bowls to the rotor shaft is enhanced by the presence of a horizontal disk. During the operation of such a turbine, the exhaust air has no way out of the volume of the cups and is forced out by free flows, as a result of which the wind energy is wasted irregularly, there are chaotic eddies and pulsations, flutter disruption of air jets from the edges of sailing elements. The design is subjected to strong damaging vibrations and alternating loads. The presence of a mounting non-perforated disk impairs the aerodynamics of the turbine, which, along with the insignificance of the area swept by it, does not allow to develop a power of more than 1-2 kW.

In order to achieve power of practical interest, non-orthogonal VAWTs are made in the form of towers, which makes it possible to obtain a developed surface of sailing elements and a large area of a swept surface of a turbine. However, as a result of this, the rotor shaft turns out to be long and torsional, which is aggravated by the difference in aerodynamic modes in height: laminar at the base of the shaft and increasing turbulent closer to its top. Due to the high total frontal drag of the sailing elements, tower wind turbines are prone to tipping over under the pressure of the wind. In addition, due to the large number of longlines or the height of monolithic sailing elements hung on the shaft, its weight becomes so significant that there is a need for the use of external force to overcome the inertia of the massive turbine-rotor structure and begin its predetermined rotational movement.

In order to avoid the beating of the generator shaft, an obligatory technological requirement for all wind turbines is the thin static and dynamic balancing of the turbine-rotor assembly. However, due to the design features of the windrotors (the cantileverness of the sailing elements at the ends of the frames, traverses and crosses of orthogonal turbines, the effect of vibrations of a stretched string observed during the operation of long shafts of tower installations), this condition cannot be fulfilled ideally. The beating of VAWT mechanisms cannot be avoided. The amplitude of vibrations of the mobile nodes of wind power stations is so significant that their shaking is easily observed visually.

The values of the coefficient of utilization of wind energy for orthogonal and non-orthogonal windrotors fluctuates within a narrow range of 25-35%, which indicates a slight difference in the aerodynamic properties of the sailing elements in their diametrically opposite positions and low efficiency of the conversion of kinetic energy of the wind into the mechanical energy of a rotating rotor shaft. It is recognized that, until now, a fairly simple and rational solution has not been found for VAWT system designs.

The aim of the invention is to ensure the stable operation of wind turbines in unstable and extreme atmospheric conditions without using external forces to start the installation, increasing the strength and reliability of the wind generator.

The task for small and medium-sized household or industrial consumers (up to 20 kW) is realized by the fact that the sailing elements of the GTV generator are radially and concentrically aligned in the horizontal plane common to them all. The supporting structure for them is not the peripheral sides of the turbine frame, crosshead or directly long rotor shaft, but a horizontal disk, which is a more rigid and durable structure. Moreover, the disk has triangular holes made with a uniform pitch in at least two concentric rows. One of the sides of the mentioned openings necessarily coincides or is parallel to the radius of the hard disk, they are also displaced in different concentric rows by a certain equal angle relative to each other and are equipped with sailing elements. The last of these components of the horizontal turbine design are made in the form of trihedral pyramids with an open base, which coincides in shape and size with the holes in the hard disk and combined with them. Also open is one of the sides of the pyramidal-sailing elements, which is located at a right or obtuse angle to the surface of the supporting disk and coincides with the radially directed or coaxial radius of the disk with the edge of the through holes in it. In one of the concentric rows, pyramidal-sailing elements are installed on top, and in the other row - below the hard drive.

Figure 1 shows a General view of the disc GTV generator, where the cross section of the pyramid-sailing structural elements for clarity is shown in the frontal plane; figure 2 and 3 is a longitudinal section of the pyramidal-sailing elements of the upper and lower concentric row, respectively; figure 4 is a top view of a horizontal disk turbine with a valid layout of the pyramid-sailing elements in concentric rows under the optimal angular displacement.

The device consists of a support mast 1, on top of which there is a generator 2. On the vertical rotor shaft 3 of the generator, a hard disk 4 with triangular through holes 5, made in at least two concentric rows with a uniform pitch, is mounted in a horizontal plane. Identical pyramidal-sailing elements 6 are installed above and below the holes in different concentric rows.

Under the pressure of the wind and as a result of the difference in aerodynamic performance of the diametrically located sailing elements 6, a resulting driving force arises on the front of the air flow, which generates torque on the vertical rotor shaft 3 of the generator 2. The rotor 3 is rotated, the generator 2 starts to generate electrical energy.

Due to the greater aerodynamic difference between the prototypes of the sailing elements than the prototypes when their pyramidal shape is selected in the positions facing the wind with an open face and a sharp edge deflected from the wind, a large resulting force acts, creating more torque on the rotor shaft and generator power at the same energy of the air. The same factor, along with the smaller mass and inertia of the turbine, the optimal threshold of its sensitivity, allow the wind turbine to start working without the use of an external force.

Placing the pyramid-sailing elements on the hard drive provides greater strength and reliability of the turbine of the wind generator. It becomes technically more realistic to balance and thereby drastically reduce the runout of the turbine. Horizontal, as in propeller windmills, cantileverness of a rotating shaft and vertical cantileverness of turbines, as in orthogonal wind rotors, have been eliminated. There is no significant spacing of the rotor bearing bearings characteristic of the tower type of VAWT installations.

The horizontal position of the disk turbine creates a condition for the operation of the pyramid-sailing elements in a narrow aerodynamic mode homogeneous narrow layer of air flow. The same, i.e. the stable nature of the operation of the GTV generator is served by the sensitivity threshold of the turbine-rotor unit, which is average in a number of known from the development of technical means of wind energy. The turbine of the proposed device does not respond to minor fluctuations and pulsations of the atmosphere, it works smoothly and stably. In turn, this parameter of the turbine positively affects the uniform pitch of the placement of sailing elements in concentric rows and their relative equal-angle displacement, as shown in figure 4.

When the operating conditions of the GTV generator are excessive for wind speed, there is no sharp jump in the frontal resistance of the turbine, since the pyramid-sailing elements have streamlined shapes on its three sides, and a smooth exit of the air flow through the through holes in the horizontal disk of the turbine assembly is provided on the fourth.

The slope of the edge of the pyramidal-sailing elements towards the wind contributes to the installation’s operation in oblique ascending and rising air flows. Moreover, if a warm atmospheric front rises, the elements located on the turbine hard disk will be mainly involved, and with a cold falling front - from the bottom of the same disk. This circumstance necessitates at least two concentric rows of the elements mentioned here.

In addition to the basic design, which is described in detail above, the turbine of the GTV generator in the areas of light winds (4-6 m / s) can be made in the form of a frame covered with durable fabric or plastic. In territories with squalls and storms, the supporting surface of the pyramid-sailing elements is strengthened and, for example, is formed of two horizontal disks fastened together by stiffeners.

Claims (1)

A horizontal-turbine wind generator containing a support mast, on top of which a fixed stator and a rotor with a vertical axis of rotation are placed, a turbine with sailing elements, characterized in that the turbine is a horizontal disk with at least two concentric rows of sailing elements installed with equal in steps of one concentric circle above and below the other on the supporting disk surface in the form of trihedral pyramids, the bases of which are cut out, and one of the faces is open, no directional or coaxial turbine radius and forms with the disc straight or obtuse angle, sailing-pyramidal elements of different concentric rows are offset relative ravnouglovoe.

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