RU2263815C1 - Vertical rotation shaft rotary windmill - Google Patents

Abstract

FIELD: wind power engineering.

SUBSTANCE: proposed rotary windmill with vertical rotation shaft consists of support truss having at least three supports, upper and lower crossmembers connecting supports to form rigid structural unit, upper and lower support platform with holes in center and connected to cross members. Upper and lower bearing housings are secured on upper and lower support platform coaxially with holes which accommodate upper and lower bearings installed, respectively, on upper and lower ends of shaft of rotor arranged inside support truss between support platforms for rotation. Windmill is provided with working members in form of blades. Blades are made as part of hollow sphere or hollow cylinder. Support of truss are rigidly secured on base frame. Invention is aimed by increasing efficiency and improving serviceability of rotary windmill owing to provision of rigid truss, failless service life owing to reduction of vibration of structure at use of rigid truss, increasing power of rotary windmill with vertical shaft of rotation owing to increased sizes of rotor both in diameter and height using rigid truss.

EFFECT: increased efficiency, power output and service life.

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Description

The technical field to which the invention relates.

The invention relates to wind turbines, and more particularly to rotor-type wind turbines with a vertical shaft of rotation.

The level of technology.

Known two-support rotor-type wind turbine with a vertical shaft, in which the bearings are located on both sides of the rotor. The bearing mounted on the lower end of the shaft is fixed in the truss, and the bearing mounted on the upper end of the shaft is fixed in the cross, from which there are extensions to the ground that support the entire structure in an upright position (see Wind heats the house // Young technician. 1988, No. 3, p. 76-80).

The advantage of this design is low metal consumption and ease of manufacture. However, it has significant disadvantages.

1. Under the influence of wind force on the rotor, a bending of the shaft will occur and, as a result, the static unbalance of the rotor.

2. When the rotor rotates under the influence of wind as a result of shaft deflection, a dynamic unbalance occurs, bending the shaft even more.

This wind turbine has inherent drawbacks due to the significant mobility of the crosspiece, in which the upper bearing housing is installed together with the bearing itself, which entails the deformation of the cross itself, the flexure under its own weight, the deformation of the soil.

The second disadvantage is connected with the connection of the lower end of the rotor shaft with the working mechanism - the axis of the rotor shaft changes its position in the vibration frequency mode and problems arise even when using soft couplings, while additional losses of the wind turbine power from distortions and friction are relevant.

The third disadvantage is the limitation of the size of the rotor both in diameter and in height.

As a result of static and dynamic imbalance, the shaft at the joint with the bearing experiences strong alternating loads, which lead to the fact that the shaft near the bearing breaks.

An increase in shaft strength gives a positive effect only for low-power rotor wind turbines with small rotor sizes, and for high-power wind motors an increase in shaft strength only exacerbates the problem.

Also known is a wind power plant containing at least one additional wind turbine located in a housing consisting of at least one upper and one lower horizontal frames uniformly spaced along the height of the wind turbine and interconnected by vertical supports that are rigidly connected by transverse rods (see RU 2142573 C1, 6 F 03 D 9/02).

The first disadvantage of this device is that the thus distributed wind turbines screen each other.

If you install wind turbines at considerable distances, then connecting them with the upper and lower horizontal frames loses all meaning. Such wind turbines in their design should be autonomous.

The second disadvantage of this device is that the air pressure created in front of the second row of wind turbines reduces the pressure difference between the air flow before and after the first row of wind turbines, which impairs their operation.

For a given power plant, it is necessary to consider only one cell in which the wind turbine is installed. It is mounted in a rectangular vertical frame. The axis of the wind wheel drum is attached at its ends to the upper and lower sides of the rectangular frame. The rectangular frame itself cannot be held upright on its own. In this device, all the frames occupy a vertical position only due to their group installation and connection by rigid transverse rods. In order for a separate rectangular frame to occupy a stable position, it must be equipped with braces connected to the ground. However, this solution does not provide the required structural rigidity necessary for the operation of the drum wind turbine.

The proposed solution to the problem is that the rotor should rotate inside a rigid structure in the form of a special truss.

Closest to the claimed invention is a rotor-type wind turbine with a vertical shaft, containing a rotor, in which the working bodies are blades made as part of a hollow cylinder, mounted on a shaft, at the ends of which are installed upper and lower bearings located in the bearing housings. The lower bearing housing is installed in a rigid structure, and the upper bearing housing is fixed in a crosspiece, to the ends of which are connected stretch marks fixed in the soil (Klimov O., Klimov V. Sensation! Rotary, spiral-vortex // Technique - Youth. 2003, No. 2 , p. 36-37). This wind turbine has all of the above disadvantages.

The present invention eliminates all of the above disadvantages.

Disclosure of the invention.

The technical result that can be obtained using the present invention is to increase the efficiency and increase the operability of the rotor wind turbine by supplying it with a rigid truss, increase the trouble-free service life by reducing the vibration of the whole structure when using a rigid truss, to the possibility of increasing the power of the rotor wind turbine with vertical shaft of rotation by increasing the size of the rotor both in diameter and in height, using a rigid truss.

The technical result is achieved in that a rotary wind turbine with a vertical shaft of rotation, containing a rotor, whose working bodies are blades made in the form of a part of a hollow cylinder or part of a hollow sphere, mounted on a shaft, at the ends of which are installed upper and lower bearings located in the upper and lower bearing housings, is equipped with a support truss, consisting of at least three bearings, interconnected in one rigid structural unit by upper and lower rungs, to which are attached respectively, the upper and lower bearing pads with holes in the center, the upper and lower bearing housings of the upper and lower bearings are attached to the bearing pads coaxially with the holes so that the rotor with the upper and lower ends of the shaft with the upper and lower bearings placed on them is installed in these bearing housings and It is placed inside the supporting truss between the supporting platforms with the possibility of its rotation.

A brief description of the drawings.

The drawing shows a rotary wind turbine with a vertical shaft of rotation, the rotor of which is installed between the bearings of the support truss and is fixed by the upper and lower ends of the shaft by means of bearings and bearing bearings on the respective bearing platforms.

The implementation of the invention.

A rotary wind turbine with a vertical shaft of rotation consists of a support truss 1, consisting of at least three supports 2; upper 3 and lower 4 rungs connecting supports 2 to a single rigid structural unit; upper 5 and lower 6 bearing pads with holes in the center attached to the crossbars 3 and 4; on the upper 5 and lower 6 bearing platforms, coaxially with the holes, the upper 7 and lower 8 bearing housings are mounted, in which the upper 9 and lower 10 bearings are mounted, installed on the upper 11 and lower 12 ends of the shaft 13 of the rotor 14, located inside the support truss 1 between supporting platforms 5 and 6 with the possibility of rotation; 15 - working bodies, blades, made in the form of a part of a hollow sphere or in the form of a hollow cylinder. The supports 2 of the farm 1 are rigidly fixed to the foundation 16.

The wind turbine operates as follows.

When the wind flow on the working bodies 15, having the form of a part of a hollow sphere or hollow cylinder, powerful transverse forces arise (Magnus effect), significantly exceeding the force of direct wind pressure. Under the influence of direct wind pressure and these transverse forces, the rotor 14 rotates, leaning the ends of the vertical shaft 11 and 12 on the upper 9 and lower 10 bearings located in the upper 7 and lower 8 bearing housings, which are rigidly connected to the upper 5 and lower 6 bearing pads with holes in the center and aligned with them, attached to the upper 3 and lower 4 rails, which prevents deformation of the upper and lower bearing pads 5 and 6 themselves, as well as distortions and clamps of the rotor 14 in the upper and lower bearings 9 and 10, thereby reducing loss u friction energy, which increases the efficiency of the wind turbine and increases its reliability. The upper 3 and lower 4 rungs are rigidly connected to the supports 2, and therefore, with the entire structure of the support truss 1, rigidly attached to the foundation 16, which provides reliable fastening of the entire structure to the ground. A rigid connection of the upper 5 and lower 6 support platforms, upper 3 and lower 4 crossbars and supports 2 into a single rigid structural unit prevents bending of the vertical shaft 13, which reduces the static and dynamic unbalance of the vertical shaft 13, increasing its service life, and also provides a stable position its axis in vibration frequency mode. Thus, the rotor 14 is in a stable position during rotation, and the lower end 12 of the vertical shaft 13 can be connected to any operating mechanism by means of a soft or rigid coupling. The vibrations created by the dynamic forces during the rotation of the rotor 14 are perceived by the entire support farm 1 and are damped, which removes restrictions on the rotor size both in height and in diameter, and this makes it possible to build powerful rotor-type wind turbines.

The advantage of the claimed wind turbine over the prototype is that the support farm 1 provides:

- rigid fixation of the position of the ends of the vertical shaft and damping of the vibration of the rotor caused by dynamic forces during its rotation;

- reduces the loss of mechanical energy of a rotating vertical shaft by eliminating distortions, pinches, clamps, increased friction between articulated parts and assemblies, and thereby increases the efficiency of a rotary wind turbine with a vertical shaft of rotation and increases its efficiency, i.e. extension of service life;

- rigid fixation of the position of the ends of the vertical shaft of the rotor allows you to connect any actuator to the lower end of the vertical shaft by means of either a rigid or soft coupling;

- vibration damping by a rigid frame allows you to completely avoid accidents, increase the service life of a rotary wind turbine with a vertical shaft of rotation, determined only by the wear of its components and parts;

- a rigid support truss removes restrictions on the size of the rotor both in diameter and in height, and therefore allows the construction of powerful rotor-type wind power plants, for example, to drive powerful electric generators. The metal consumption of the structure due to the support truss increases, but for powerful wind turbines the specific metal consumption will decrease.

Comparative analysis allows us to conclude that, in comparison with the prototype and other considered wind turbines, the claimed rotor wind turbine with a vertical shaft of rotation, containing a rigid support truss, has a number of significant advantages that ensure the reliability of its operation, increase the efficiency of use of wind energy, as well as the ability construction of rotor wind turbines with a vertical shaft of rotation of increased power.

An analysis of the known technical solutions in the studied area and in related areas allows us to conclude that there are no signs in them that are similar to the features of the claimed device that perform the same functions.

The economic efficiency from the use of the claimed device is that:

- increases the reliability and service life of a rotary wind turbine with a vertical shaft of rotation;

- the efficiency of using wind energy increases;

- it is possible to create a powerful, reliable rotary wind turbine with a vertical shaft of rotation.

Claims (1)

A rotor wind turbine with a vertical shaft of rotation, comprising a rotor, whose working bodies are blades made in the form of a part of a hollow sphere or part of a hollow cylinder, mounted on a vertical shaft, at the ends of which there are upper and lower bearings located respectively in the upper and lower bearing housings characterized in that it is equipped with a support farm consisting of at least three supports connected to each other in one rigid structural unit by upper and lower rungs, to which respectively, the upper and lower bearing pads with holes in the center are replicated, and the bearing housings of the upper and lower bearings are attached coaxially with the holes to the bearing pads so that the rotor with the upper and lower ends of the shaft with the upper and lower bearings placed on them are installed in the bearing housings and placed inside the supporting truss between the supporting platforms with the possibility of its rotation.