RU2766497C1 - Wind farm - Google Patents

Abstract

FIELD: wind power engineering.SUBSTANCE: invention relates to wind power engineering and wind into mechanical energy of rotation of a blade system with its subsequent conversion into electrical energy. Wind-driven power plant includes a fixed support frame fixed between three radially located structures. Shaft is made with possibility of rotation around the vertical axis and is functionally connected to the electric generator. Blade system is fixed on the shaft. Support frame is fixed to the fixed rigidly fixed vertical axis. Area of one blade of the blade system is selected from 5 to 1000 m2. Blade of the blade system can be made of various shapes, for example, in the form of a sail. Preferably, the vertical axis is hollow and has holes for conducting communications.EFFECT: increased rigidity and stability of the wind farm structure.4 cl, 2 dwg

Description

The technical solution relates to wind energy and is designed to convert the kinetic energy of the wind into mechanical energy of rotation of the blade system with its subsequent conversion into electrical energy.

From the prior art, a technical solution "Wind power plant" is known, containing a housing and a working shaft installed in the housing with the possibility of free rotation around a vertical axis, a wind wheel mounted on the shaft, made in the form of a truncated cone, with blades fixed along the generatrix of the cone. The body contains a stand-bracket and a base. RF patent for utility model No. 155147, IPC F03D 3/06, F03D 11/00, published on September 20, 2015

Common features of the known solution and the proposed solution are:

- the presence of a frame,

- the presence of a shaft made with the possibility of rotation and functionally connected to the electric generator,

- the presence of a blade system fixed on the shaft.

Distinctive features of the given solution and the proposed solution are:

- execution of the frame with the possibility of fastening between three radially located structures

- the presence of a fixed rigidly fixed vertical axis, to which the support frame is fixed,

- the shaft is mounted for rotation on the specified vertical axis.

The disadvantage of this solution is the low power of the wind power plant, since the proposed housing design and options for fixing the shaft and the wind wheel do not provide structural rigidity and stability of the wind power plant sufficient to use blade systems with large blade areas.

The technical solution is known from the prior art, chosen as the closest analogue, "Wind power plant" according to the RF patent for the invention No.

Common features of the above solution and the proposed solution are:

- the presence of a frame made with the possibility of fastening between three radially located structures,

- the presence of a shaft made with the possibility of rotation and functionally connected to the electric generator,

- the presence of blades fixed on the shaft.

Distinctive features of the given solution and the proposed solution are:

- fixed rigidly fixed vertical axis, to which the support frame is fixed,

- the shaft is mounted for rotation on the specified vertical axis.

In the known solution, to ensure the rigidity and stability of the structure with large areas of blades, the construction of a bulky support frame is required, which can lead to a high material consumption of the wind farm structure, since in order to achieve the height of the structure, where the potential of wind energy becomes most effective and approaches almost constant action with very slight fluctuations, the construction of a structure with a height of several tens and even hundreds of meters is required. At the same time, such a frame must have sufficient rigidity and stability to withstand the loads from the effects of the wind flow.

The task of the proposed solution is to overcome the shortcomings of the known solutions and to create a wind power plant with high efficiency and reliability.

The technical result of the proposed technical solution is to increase the rigidity and stability of the structure of the wind farm.

The claimed technical result is achieved by the fact that the wind power plant, including at least one support frame, made with the possibility of fastening between at least three radially located structures, a shaft made with the possibility of rotation and functionally connected to the electric generator, and a blade system mounted on the shaft, additionally contains a fixed rigidly fixed vertical axis, to which the support frame is fixed, and the shaft is mounted with the possibility of rotation around the specified vertical axis. The area of one blade of the bladed system is chosen from 5 to 1000 sq.m. The blade of the paddle system can be made in various shapes, for example, in the form of a sail. Preferably, the vertical axis is hollow and contains openings for conducting communications.

The placement of the support frame between at least three radially located structures with its fastening to a fixed rigidly fixed vertical axis and the placement of the shaft with the possibility of rotation around this axis ensures the rigidity, stability and reliability of the entire structure, which allows the use of blade systems with large parameters, for example, the area of one blade is from 5 to 1000 sq.m., which reduces the oscillatory loads on the design of the wind power plant, at the same time increases its efficiency and increases power.

Moreover, fixing the support frame between at least three radially arranged streamlined structures makes it possible to increase the efficiency of the wind power plant, since the air corridor created by three radially arranged structures allows the formation of enhanced wind flows in any direction to affect the blade system even at such heights. placements where wind currents are not yet characterized by a constant action.

The shaft of the wind power plant, made with the possibility of rotation of the fixed axis, is structurally connected to the electric generator by any method known from the prior art to transfer the rotation caused by the action of the kinetic energy of the wind on the blades of the blade system into the mechanical rotational energy of the elements of the electric generator to convert it into electrical energy. In this case, the electric generator itself can be either directly connected to the rotating shaft, or placed separately using a known method of transmitting rotation. The shaft can be mounted both directly on the fixed axle and on the frame by any known method, for example, using bearings.

In order to understand the proposed solution, it is necessary to clarify that radially located structures mean structures placed in the direction of the radius, relative to a fixed vertical axis, around which the shaft rotates and are not limited to such a placement option, when all structures are placed at the same distance from the axis of rotation and at the same distance from each other. Structures can be placed at different distances from the axis of rotation of the shaft, and at different angular distances, for example, to perceive the prevailing winds in the selected area.

Calculations and created mathematical models showed that the optimal height of buildings is from 5 to 800 m, and the height of the location of the first blade system is 5-15 m. Blade systems can be located one above the other on the shaft. The parameters and number of blade systems, including the area of one blade and its shape, with this arrangement are calculated separately for a specific building height. For example, large blades can be used at low altitudes to better absorb low-strength winds, and as altitude increases, the blade area may decrease.

The design of the wind power plant in such a way that the rotation of the blade system occurs around the vertical axis allows you to increase the efficiency of the wind power plant and its reliability, since such an arrangement will perceive its kinetic energy equally well with any change in wind direction. The support frame, fixed to the fixed axis, will experience less load from the wind flow, the entire structure will have greater rigidity and stability.

Additionally, the wind power plant can be provided with an air fairing, configured to redirect the air flow entering it, redirecting it into the blades, thus increasing the efficiency of the wind power plant. The air fairing can be fixed on the frame.

The essence of the proposed solution is explained with the help of figures, which conditionally represent one of the options for the design of a wind farm.

Figure 1 shows a top view.

In Fig.2. side view shown

In figures 1 and 2, the positions have the following designation: 1 - support frame, 2 - shaft, 3 - bladed system, 4 - fairing, 5 - fixed vertical axis.

The use of the proposed technical solution is carried out as follows.

Three structures are erected by any known methods, in particular, multi-storey buildings, made in such a form that allows wind flows to flow around them smoothly. The structures can be placed both at an equal distance from each other, and at different ones, in such a way that a space is formed between them in the center for the location of the wind farm. A vertical rigidly fixed axis (5) is erected between the structures, for example, in the form of a reinforced concrete structure. Axis (5) can be hollow and contain holes for placement inside the axis (5) and the output of communications, for example, electrical cables for connecting the shaft to the generator and other equipment. Next, a support frame (1) is attached to the frames of structures and axis (5) at a pre-calculated height, for example, for an 80-storey building, the height of the lower blade system can be equal to 8 meters. Then the shaft (2) is installed with the possibility of rotation around the fixed axis (5), while the shaft (2) can be installed in such a way that it transfers the mass to the axle (5), or to the frame (1), or simultaneously to the axle ( 5) and frame (1). The shaft is functionally connected to an electric generator. A paddle system (3) is placed on the shaft (2). The parameters and number of blades are calculated based on the wind indicators of the area, energy needs, the height of structures, etc. The air corridor formed by three structures makes it possible to amplify air flows of any wind direction, which, meeting with the streamlined parts, will be directed to the central part, where the blade system (3) is located, capable of receiving the kinetic energy of the wind and transmitting movement to the shaft (2) and to the electric generator where rotational energy is converted into electrical energy. According to mathematical calculations, this wind farm, containing 7-8 blade systems, located one above the other on a shaft mounted on a frame between 80-storey buildings, can provide the electricity needs of three 80-storey buildings, generating at least 7.5 MW from each blade system . Electricity storage devices can be additionally connected to the electric generator. Additionally, the wind farm can be equipped with an air fairing (4) made with the ability to redirect the air flow entering it, redirecting it into the blades.

The presented figures and description of the design do not exhaust the possible options and do not limit in any way the scope of the proposed technical solution. Other versions are possible within the scope of the claimed formula.

The claimed solution provides the conversion of the kinetic energy of the wind into the mechanical energy of rotation of the blade system with its subsequent conversion into electrical energy and can be used in any area for a stable supply of electricity to consumers using renewable energy sources. Such sources are environmentally friendly, create a minimal burden on the environment and are safe for humans.

Claims (4)

1. A wind power plant, including at least one fixed support frame, fixed between at least three radially located structures, a shaft made with the possibility of rotation and functionally connected to an electric generator, and a blade system fixed on the shaft, characterized in that it contains a fixed rigid a fixed vertical axis, to which the support frame is fixed, and the shaft is mounted for rotation around said vertical axis. 2. Wind power plant according to claim 1, characterized in that the area of one blade of the bladed system is from 5 to 1000 sq.m. 3. Wind farm according to claim 1, characterized in that the vertical axis is hollow. 4. Wind power plant according to claims 1 and 3, characterized in that the vertical axis is made hollow with holes for communications.

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