RU2392489C1 - Wind power station with vertical two-staged vortex aeroturbine with centrifugal limiters of rotation speed of aeroturbine - Google Patents

Abstract

FIELD: engines and pumps. ^ SUBSTANCE: invention refers to power engineering and can be used for conversion of wind energy to other types of energy. Wind power station (WPS) includes aeroturbine made of two vertical turbines installed one above the other and having individual load-carrying shafts connected to electric generators or other rotation energy consumers. Shaft of lower turbine is hollow, inside it there arranged is shaft of upper turbine, on the shaft surface there installed are discs in which there fixed are inner ends of blades; outer ends of blades are tightened with narrow rings-hoops; edges of blades are covered with bases in the form of discs, thus forming multiple blade turbines of opposite rotation direction. Bases of turbines are equipped with cylinders; into external cylinders there built are capacities with movable ballast. Elements of centrifugal limiters of turbine rotation speed are arranged in intermediate cylinders. WPS can be used in areas with favourable and extreme wind conditions, as well as on sea vessels and on high-rise buildings as drives for actuator screws and elevator motors in emergency cases. ^ EFFECT: increasing efficiency and reliability at the possibility of arranging electric generators in closed rooms. ^ 3 dwg

Description

The invention relates to wind power plants and can be used in the national economy in areas with favorable and extreme wind conditions. The basis of any wind farm is a wind wheel or a wind turbine, which is the drive for the electric generator. The prototype of the invention is "Aeroturbine for the use of energy of air flows", patent RU No. 232,3991 C1, publ. in Bulletin No. 20 July 20, 2008. Its main drawback is the insufficient mechanical strength of the bearing shaft-cylinder with openings on its body and the restrictions on its use in areas with high wind speeds.

The technical result of the invention is to increase the strength of the supporting structures of the wind turbine, increase the efficiency and reliability of its operation at high wind speeds, as well as the possibility of placing electric generators on the ground indoors.

A wind farm with a vertical two-stage vortex turbine with centrifugal speed limiters of the turbine contains a turbine mounted on horizontal supports and made of two vertically mounted one above the other turbines with individual bearing shafts connected to electric generators or other consumers of rotational energy through transmission systems, couplings and multiplicators or reducers, while the shaft of the lower turbine is hollow, the shaft of the upper urbins attached by bearings to horizontal bearings, disks with grooves on their circles are mounted on the surface of the shafts, in which the inner ends of the blades are mounted, made in the form of a surface cut off from the hollow cylinder by a plane parallel to the generatrix, and the outer ends of the blades are tightened together by narrow rings -wraps, above and below the ends of the blades are closed by bases in the form of disks, rigidly connected with them and with the shafts, forming multi-blade turbines, the blades of which have opposite directions bends, cylinders are attached to the base of the turbines with removable joints, while conical, bowl-shaped containers with ribs, in which movable, in the form of liquid or bulk solids, ballasts, are installed in the outer cylinders, closed by conical fairings strung on shafts, are in the middle cylinders elements of centrifugal turbine speed limiters are placed, while the cylinder of the lower turbine enters the cavity of the cylinder of the upper turbine, a belt of high-strength friction ma is fixed on the inner surface of the latter terial and permanent magnets forming a radial magnetic field, and the cylinder of the lower turbine is made in the form of a rotor with insulated conductors located in the zone of the magnetic field on its lateral surface, the upper ends of which in the form of collector plates form a horizontal collector, and the lower ends are connected by a conductive plate at the lower base rotor, and on the upper base of the lower cylinder levers are fixed with conductive plates on the bottom and friction material at the ends, rotating on the axes and holding Vai in the rest position by springs.

The specified technical result is achieved by the fact that, as shown in figure 1, the wind turbine consists of two similar turbines, vertically placed one above the other, having individual bearing shafts 25, 26. The shaft 26 of the lower turbine is hollow. Inside it passes the shaft 25 of the upper turbine, connecting with the first shaft 26 through the bearings 23. The shaft of the upper turbine 25 is attached to the horizontal bearings 22 through the bearings 23. Therefore, it is the bearing shaft of the entire two-stage air turbine. On the shafts 25, 26 there are several disks or thin cylinders 18 with grooves 17 on their circles. In the grooves 17 are fixed the inner ends of the blades 7, made in the form of a surface cut off from the hollow cylinder by a longitudinal plane parallel to its generatrix. It can be metal, plastic or made of composite materials. But it must be flexible. The planes of such material are fixed in the grooves 17 on the disks 18. Then their outer ends are bent and fixed in several places along the length of the turbine with narrow hoop rings 8. This technology of fastening the blades greatly simplifies their manufacture and gives them the desired cylindrical surface. Between the shaft 25 (26), the disks 18 and the inner ends of the blades 7, as shown in FIG. 2, a free central space is formed. As a result, the air flow passing through the entire turbine, as in a whirlwind, involves essentially all the blades, which significantly increases the efficiency of the turbine. In addition, when an air stream passes through the inter-blade spaces in the bends of the blades, an additional reactive force appears, which also increases the efficiency. At the ends of the turbines, bases are mounted in the form of disks 6, rigidly connected to the ends of the blades 7 and the shafts 25, 26. Thus, the lower and upper multi-blade turbines are formed in which the blades have opposite bends. Cylinders 4 are attached to the bases 6 by removable joints 24. Outer cylinders 4 are closed by hollow conical fairings 3 strung on shafts 25, 26. Movable 21 and fixed 19 ballasts can be placed in the cavities of these cylinders and fairings. As mobile ballast can be used a liquid, for example water with antifreeze, or bulk solids. Moreover, the capacity for them is the upper cylinder with a conical, cup-shaped bottom and the cavity of the fairing on the lower turbine. In these tanks, ribs 20 are mounted that carry the ballast during the rotation of the turbine. On the middle cylinders 4 are mounted elements of speed limiters for rotation of the turbine. In this case, the cylinder of the lower turbine enters the cavity of the cylinder of the upper turbine. On the inner surface of the cylinder of the upper turbine are attached a belt 14 of high-strength friction material and permanent magnets 11, forming a radial magnetic field. The cylinder of the lower turbine is made in the form of a rotor 10 with the shorted upper ends of the conductors forming horizontal collector 10-3 with their plates 10-2 (Fig. 3). The lower ends of the conductors 10-1 at the lower base of the rotor are interconnected by a conductive plate 9. The conductors 10-1 themselves are isolated from each other and are located on the side surface of the rotor in the area of action of the radial magnetic field created by permanent magnets. On the upper base of the cylinder 10, as shown in figure 3, 1, are mounted on the axles 15, made in the form of brackets, movable levers 13, held out of position by springs 16 attached to the brackets 15-1 (figure 1, 3). The ends of the levers 13 are made of high-strength material with a high coefficient of friction, and conductive plates 12 are mounted on the bottom of the levers 12. The shafts 25, 26 of the turbines through transmission systems 27 controlled by 29 and bypass clutches 30, multipliers or gearboxes 2 are connected to electric generators 1 or other consumers of energy rotation.

The principle of operation of a wind power plant is as follows. Under the influence of the air flow acting on the concave and convex sides of the blades 7, the moment of rotation of the turbines is created. But since the turbine blades have oppositely directed bends, the turbines rotate in different directions. An air turbine has three methods of limiting rotation speed: dynamic, electrodynamic, and mechanical, which are included in series in the braking process. All of them are based on the use of centrifugal force acting on the movable ballast 21 and levers 13 during the rotation of the turbines. The dynamic braking method is permanent. Its essence is as follows. When the turbines rotate, water (movable ballast 21) rises upward along the conical bottom of the tank to the side walls of cylinder 4. Since the mass of water and the radius of rotation relative to the axis of the turbines change, the moment of inertia of the movable ballast also changes. Its maximum value will be when the entire mass of ballast is ejected onto the cylinder walls. The angular speed of rotation of the turbines will decrease in proportion to the value of the moment of inertia. The decline of water will begin. Its moment of inertia will decrease. The rotation speed will increase. Such a process of controlling the speed of rotation of the turbines will continue until the moment of balancing of the external torque from the wind pressure and the moment of inertia of the moving ballast. Essentially, this stabilizes the rotation speed of the entire air turbine.

If, despite the opposition of the dynamic method of braking the rotation of the wind turbine, its speed continues to increase, then when the centrifugal force reaches a value greater than the compression force of the springs 16, the levers 13 begin to turn on the axes 15. The levers 13 slide along the collector plates 12 along the collector 10-3 and close the upper ends 10-2 of the conductors 10-1 on the cylinder 10 (see figure 3 the position of the lever 13-2). Under the influence of the magnetic field created by the permanent magnets 11, current arises in the conductors 10-1 and the rotor magnetic field appears. The latter, interacting with a magnetic field from permanent magnets, causes the rotor to rotate after the magnetic field from permanent magnets. That is, in the opposite direction from the direction of rotation of the lower turbine, thereby creating a braking can rotate the entire air turbine.

If the dynamic and electrodynamic braking methods are not able to counteract the wind pressure, then the mechanical braking method comes into effect. The levers 13, while continuing to rotate on the axes 15, their ends come in contact with the friction belt 14 on the cylinder 4 of the upper turbine. Mechanical turbine rotation is braked by friction. The greater the angular velocity of rotation of the turbines, the closer the levers 13 are pressed against the friction belt 14, braking the rotation of the entire air turbine (see the position of the lever 13-3 in figure 3). In this way, the electrodynamic and mechanical methods of limiting the speed of rotation of the wind turbine are sequentially activated. Figure 3 shows the positions of the 4 levers 13: the initial position of the lever 13-1, the moment of closure of the plates 10-2 of the collector 19-3 by the lever 13-2, mechanical braking by the lever 13-3 and the sequence of actions of the lever 13-4 when braking . It should be noted that the dynamic braking method for the upper and lower turbines can be different in magnitude, while the other methods of braking the rotation of the turbines are interconnected and inherent in the whole air turbine.

Of course, in areas with favorable wind conditions, only the mechanical braking method can be used, as an emergency option for limiting the speed of rotation of an air turbine. A dynamic method of speed limitation is needed as a stabilizer of its rotation speed. A two-stage turbine with versatile rotation of the turbines significantly reduces the torque generated on the supports, which allows them to be used on moving objects. For example, on ships such air turbines can be used by loading on the propellers, not only in emergency cases, but also constantly - in order to save fuel. Such wind turbines can be installed on the roofs of high-rise buildings as drives of local electric generators providing energy to the elevator economy or consumers of the entire building. The parallel connection of several wind turbines will enable the use of high-power generators. At the same time, electrical installations will be placed in rooms isolated from the weather.

Claims (1)

A wind power station with a vertical two-stage vortex wind turbine with centrifugal speed limiters of a wind turbine, containing a wind turbine mounted on horizontal supports and made of two vertically mounted one above the other turbines with individual bearing shafts connected to electric generators or other consumers of rotation energy through transmission systems, clutches multipliers or gearboxes, while the shaft of the lower turbine is hollow, the shaft of the upper turbines attached to it by bearings to horizontal bearings, disks are installed on the surface of the shafts with grooves on their circles, in which the inner ends of the blades are mounted, made in the form of a surface cut off from the hollow cylinder by a plane parallel to the generatrix, and the outer ends of the blades are pulled together narrow hoop rings, above and below the ends of the blades are closed by bases in the form of disks, rigidly connected with them and with the shafts, forming multi-blade turbines in which the blades are opposite to the direction bends, cylinders are attached to the base of the turbines with removable joints, while conical, cup-shaped containers with ribs in which movable, in the form of liquid or bulk solids, ballasts are built into the outer cylinders, closed by conical fairings strung on shafts cylinders placed elements of centrifugal turbine speed limiters, while the cylinder of the lower turbine enters the cavity of the cylinder of the upper turbine, a belt of high-strength friction is fixed on the inner surface of the latter material and permanent magnets forming a radial magnetic field, and the cylinder of the lower turbine is made in the form of a rotor with insulated conductors located in the magnetic field zone on its lateral surface, the upper ends of which in the form of collector plates form a horizontal collector, and the lower ends are connected by a conductive plate at the lower the base of the rotor, and on the upper base of the cylinder of the lower turbine levers are fixed with conductive plates on the bottom and friction material at the ends, rotating on exclusive to them alone, and held in the rest position by springs.

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