UA60494C2 - Wind-driven powerplant - Google Patents

Abstract

A wind-driven powerplant has a vertical shaft with support installed in vertical support, and installed on it in horizontal positions two pair of blades with rotary flaps placed one over another in cross positions, at that the blades of each pair are fixed with rotary flap in mutually normal planes with displacement of central axis of blade with respect to axis of rotary flap. Each blade is equipped with counterweight equalizing its moment of rotation with respect to the axis of rotary flap, with repulsion elements, it is fixed on the flap adjacently to vertical shaft with possibility of interaction with support. Each rotary flap consists of two horizontal rotary shafts installed on one axle with gaps between the ends of those, connected to each other with elastic link and surrounded with horizontal cylinder fixed with respect to the vertical shaft. At that one end of horizontal shaft isconnected to cylinder with pair of shifted in long direction bearings, and the supports with respect to vertical shaft and counterweights with repulsion elements with respect to rotary horizontal shaft of flap are installed in such way that interaction of support and repulsion element is performed at blade position with respect of horizontal shaft of flap in horizontal plane.

Description

Description of the invention

The invention relates to the field of energy and is intended for obtaining electrical energy at the expense of 2 kinetic energy of the wind.

A wind energy installation is known, which includes mounted on a vertical shaft with flaps, on the periphery of which there are folding rectangular blades, supplied with limiters made in the form of flexible links, one end of which is connected to T-shaped racks placed on the periphery of the flaps, and the other - corresponding upright blades |11. 70 The blades, which are turned on the windward side, perceive the energy of the wind, and the windmill begins to rotate, transmitting the rotation to the generator. The blades, which are directed at an acute angle to the air flow, reduce their swept surface and do not interfere with the rotation of the windmill. However, folding blades do not have the necessary reliability and make a lot of noise when folding and unfolding.

A known wind energy installation containing flat blades placed on horizontal axes of rotation, 12 fixed radially on an upright shaft, horizontally placed supports, radially fixed from above and/or below relative to the horizontal axes on the shaft in the plane of their placement at distances smaller than the size of the blades from the horizontal axes, while the horizontal axes are fixed on the blades above their central part (21.

However, in this installation, the horizontally placed supports, which are part of the frame frame, experience wind loads that bend the installation.

Frames rotating against the wind create an additional braking moment, which reduces the power of the wind power plant.

A wind energy installation is also known, which contains a vertical shaft placed in a vertical support and two pairs of main rotating blades with stops and cross-shaped swings arranged horizontally on it |Z). with

In this installation, when the air flow affects the rotating blades, due to their rigid attachment to the wings, one of each pair of blades, rotating under the influence of the air flow, reaches the stops, and the opposite blade at this time takes a position along the air flow. At the same time, the air flow affecting the surface of the rotating blades, which have reached the stops, creates a torque, under the influence of which the upper part of the vertical shaft rotates, and from it the generator. M

But in this wind energy installation, a significant part of the wind energy is not rationally spent, that Ge"! leads to a decrease in generator power. The fact is that the rotation of the blades around the swing axis under the influence of the air flow occurs due to the displacement of the central axis of the blade relative to the swing axis. WITH

The air flow acting on the wide part of the blade relative to the swing axis is greater than the air flow acting on the narrow Ha») part of the blade, which leads to the rotation of the blade. It is obvious that the weight of the wide and narrow parts of the blades is not the same. at

Due to the displacement of the axis of the blade, and therefore the center of gravity relative to the axis of swing, a state of stable equilibrium exists in the absence of wind for a pair of opposite blades. The moment of the center of gravity of a pair of blades must be overcome by the air flow in order for the blades to start moving. Thus, part of the air flow is spent on "overcoming the moment of gravity, which reduces the torque that is transmitted to the generator. In addition, in the well-known Z 70 installation, part of the air flow is spent on turning the blades to the position necessary for interaction with the air flow: one blade is transverse, and the opposite one is along the flow.

From" The closest in terms of the technical essence of the proposed invention is a wind energy installation, which contains a vertical shaft placed in a vertical support and horizontally installed on it two pairs of blades with stops and cross-shaped rotary flaps placed one above the other, and the blades of each pair are fixed with a rotary swing in mutually perpendicular planes with displacement of the central axis of the blade b relative to the axis of the rotary swing, - each blade is equipped with a balancing moment of its rotation relative to the axis av! rotary swing with a repulsive element by a counterweight fixed on the swing adjacent to the main vertical shaft with the possibility of interaction with a stop containing a permanent magnet, and the outer edge of the blade shk is made with a bend of the sides relative to the axis of the rotary swing in opposite directions |4). (Te) 20 In this wind power plant, each blade is balanced relative to the axis of the rotating shaft by a counterweight. Due to this, the braking moment due to the presence of the moment of attraction of the turning swing is eliminated, and

T», the rotational power transmitted to the generator increases. The placement of the counterweight near the vertical shaft also serves to reduce the braking moment. In this installation, in addition to balancing the moment relative to the axis of the rotary shaft, the counterweight also performs the function of interaction with the stop, ensuring the transmission of power moment 25 to the vertical shaft.

GF) But with strong gusts of wind, this installation can fail. This is due to the fact that all its elements have a rigid connection with each other. In particular, during the interaction of the stop with the repulsive element between them, as well as in the area of the connection of the flap with the blade, mechanical stresses may occur with a strong air flow, which will lead to breakage in the specified places. If these areas are mechanically strengthened so that they can withstand all, even stormy winds, then such a wind energy installation will have a large cost, weight, material consumption, inertia, which will make it ineffective.

In addition, the rigidity of the structure leads to the fact that with strong gusts of wind, the blades with blades begin to rotate too quickly around the upright shaft, which is also undesirable, because it leads to rapid mechanical wear of the rotating elements, a decrease in the service life, as well as to an increased frequency of voltage 62, which produces an electric generator connected to the shaft.

The task of the invention is to increase the mechanical reliability of the installation and prevent increased rotation frequency during strong gusts of wind.

The task is achieved due to the fact that the wind energy installation, which contains a vertical shaft with stops placed in a vertical support and horizontally installed on it two pairs of blades and rotating flaps placed one above the other in a cruciform manner, and the blades of each pair are fixed with the rotating flap in mutually perpendicular planes with a shift of the central axis of the blade relative to the swing axis, each blade is equipped with a counterbalancing moment of its rotation relative to the swing axis with a repulsion element by a counterweight fixed on the swing adjacent to the vertical shaft with the possibility of /o interaction with the stop, - each swing consists of two rotating horizontal shafts , which are installed on one axis with a gap between their ends, connected by an elastic connection and covered by a horizontal cylinder fixed relative to the upright shaft, and each end of the horizontal shaft is connected to the cylinder by a pair of longitudinally shifted bearings, and the stops relative to the chain-suspended shaft and the counterweight with repulsion elements relative to the rotating horizontal swing shaft are set so that /5 the interaction of the stop and the repulsion element is carried out when the blade of the horizontal swing shaft is in the horizontal plane.

In addition, the elastic connection between the ends of the horizontal swing shafts is made in the form of a cylindrical spring, which covers the specified ends of the horizontal shafts on the outer surface.

In the proposed wind power plant, when wind gusts exceed the nominal speed, the mechanical loads are automatically extinguished due to the elastic connection between the ends of the horizontal swing shafts. At the same time, the vertically located blade rotates around the axis of the horizontal swing shaft in the direction of the wind, the plane of the blade on which the wind acts decreases. Due to this, there is a decrease in the turning moment and the swing speed relative to the upright shaft, which does not lead to its mechanical overload. with

Fig. 1 schematically shows the general view of a wind power installation, which is affected by the wind (its direction is shown by arrows), which does not exceed the permissible speed; i) in Fig. 2 - a general view of the wind energy installation, which is affected by the wind, which exceeds the permissible speed; in Fig. 3 - view A-A in Fig. 1.

The wind energy installation contains a vertical shaft 2 placed in a vertical support 1 with stops Z and "g" and two pairs of rotary vanes 4, 5 and 6, 7 are horizontally installed on it. with swing 8 and blades 6 and 7 with swing 9 are fixed in Me mutually perpendicular planes with a shift of the central axis of the blade relative to the axis of the rotary swing. Due to this, each blade, for example 4, has two parts 4a with a smaller plane and 46 with a larger plane relative to the axis of rotation 10. Each blade is equipped with a counterweight 11, which balances the moment of its rotation relative to the axis of rotation 10. The counterweights 11 are supplied with repulsion elements , for example, permanent magnets (not shown in Fig.) inserted in the middle of the counterweights, and placed with the possibility of interaction with stops C, in which permanent magnets of the opposite polarity are also installed. The counterweights are fixed on the swing adjacent to the vertical shaft 2. Each rotary swing consists of two horizontal rotary shafts 12 and 13, which are installed on the axis of rotation 10 with a gap 14 between their ends, respectively 15 and 16. The ends of the shafts 12 and 13 are connected to each other by an elastic connection, for example, a cylindrical spring 17, which covers the ends 15 and 16 of the horizontal shafts 12 and 13. The ends of the shafts 12 and 13 are covered by a horizontal cylinder 18, which is fixed relative to the vertical shaft 2.

Each end of the horizontal shaft is connected to the cylinder 18 by a pair of bearings 19, which are shifted along the axis 10. ;" Stops Z relative to the upright shaft 2 and counterweight 11 with repulsion elements relative to the rotating horizontal shaft, for example 13, are set so that the interaction, for example, contact, of the stop C and the repulsion element of the counterweight 11 is carried out when the blade 5 of the horizontal swing shaft 8 is located in the b horizontal plane.

The rotary shaft 2, which is installed in the end hub 20 perpendicular to the support 1, is connected to the electric generator of the wind power plant (not shown in the figure). "5" The wind power plant works as follows.

In the absence of an air flow, the blades with counterweights are in a state of unconditional equilibrium with respect to the axis and, swing. At the same time, the vertical shaft does not rotate. When the wind appears, blade 4 takes a position across, and blade 5 - along the direction of the wind, turning the blade 8 around its axis 10 (Fig. 1). The rotation of the blade 4 around the axis 10 occurs due to the difference in the planes of the two parts 4a and 46, which occurs under the influence of the wind. Due to the connection of the shafts 12 and 13, which is carried out with the help of a cylindrical spring 17, when rotating around the axis 10, the blade 5 is also rotated in the same direction. with a stop З between their permanent magnets, an electromagnetic force of repulsion arises, which allows to soften or eliminate the mechanical shock and reduce the noise that is generated in the process. Due to the difference in the force of the wind acting on the horizontally located blade 5 and the vertical blade 4 , a moment appears and vertical shaft 2 leads to rotation through the hub 20 of the electric generator.

In stormy weather, if the air flow exceeds a critical value, the wind power plant continues to perform its functions (Fig. 2). At the same time, due to the large force acting on the vertically located blade 4, it makes a further turn (shown by a solid line) around the axis 10, although the blade 5, which is surrounded by the air flow, is in a horizontal plane because the counterweight 11 rests on the stop 3. 65 Further rotation of the blade 4 occurs with the mutual rotation of the shafts 12 and 13 due to the tension of the cylindrical spring 17. The greater the storm wind, the more the spring 17 will be stressed and the blade 4 will rotate around the axis 10. With such rotation, the effective area of the blade 4 for the wind decreases, and due to this, the force of the wind on it and the torque of swing 8 are reduced. The reduction of the torque, in turn, reduces the speed of rotation of the shaft 2, keeping the speed within permissible limits.

By choosing the stiffness of the spring 17, you can adjust the relative inclination of the blade 4 relative to the blade 5 according to the strength of the stormy winds in the region.

We offer a model wind power plant manufactured, experimentally tested and showing good performance.

Sources of information: 70 1. Patent of the Russian Federation Mo2059877, MKPb6 gO301/00. Imprint 10.05.96 Bul. Mo13. 2. Description of the invention to the application of the Russian Federation Mo94031431, ICPE RO303/00. Imprint 20.06.96 Bul. Mo17 3. A. p. USSR Mo1746054, MKP RO303/06. Imprint 07.07.92 Bul. Mo25. 4. Patent of Ukraine Mo31757A, MKP GO303/00. Imprint 15.12.2000, Bull. Mo7-III (prototype).

Claims (2)

19 Formula of the invention 1. A wind power installation containing a vertical shaft with stops placed in a vertical support and horizontally mounted on it two pairs of blades and 2r rotary flaps placed one above the other in a cruciform manner, and the blades of each pair are fixed with the rotary flap in mutually perpendicular planes with a displacement of the central axis of the blade relative to the axis of the rotary swing, each blade is equipped with a balancing moment of its rotation relative to the axis of the rotary swing with a repulsive element by a counterweight fixed on the swing adjacent to the upright shaft with the possibility of interacting with a stop, which differs in that each rotary swing consists of two rotating horizontal shafts that are installed on one axis with a space between their ends connected by an elastic connection and covered by a horizontal cylinder fixed relative to the vertical shaft, and each end of the horizontal shaft is connected to (o) the cylinder by a pair of longitudinally shifted bearings, and the stops are relatively upright shaft and counterweights with repulsion elements relative to the rotating horizontal swing shaft are installed so that the interaction of the stop and the repulsion element is carried out when the blade is located relative to the horizontal swing shaft in the horizontal plane. 2. Wind power plant according to claim 1, which is characterized by the fact that the elastic connection between the ends of the horizontal 9 shafts is made in the form of a cylindrical spring, which covers the specified ends of the horizontal shafts on the outer surface. "c) (Se) - and? (22) ((c) sh» se) s» ime) 60 b5