BE1017044A6 - Wind turbine, has rotors with guide plates extending horizontally at outer periphery and vertically at inner periphery next to vertical rotation axis - Google Patents

Abstract

The turbine has a vertical rotation axis and comprises modules (M1, M2) arranged in different levels one above the other, each module comprising a rotor (A, B) and fixed vertical guide plates (F) extending around the periphery of the central shaft on which the rotor is mounted. Additional fixed guide plates (G0-G4) are positioned horizontally at the outer periphery of the module before extending vertically towards the inner periphery.

Description

A wind device with a vertical axis of rotation and a horizontally placed rotor.

The invention relates to a wind device with vertical axis of rotation. It consists of different modules.

Each module is equipped with one rotor blade mounted horizontally. The vertical axis of rotation is surrounded along its periphery by fixed vertically placed guide plates. Between these vertical guide plates fixed guide plates placed horizontally to vertically are mounted so that with an alternating wind direction the air flow optimally takes place towards the rotor. The wind device is composed of a different number of modules according to the needs and location conditions. This device allows electrical energy to be regenerated.

In the WaHpr of environmental issues and the falling reserves of fossil fuels, there is a great need for alternatives to generate electricity. The use of turbines powered by fluid is known in the current state of the art. Such turbines are usually provided with a horizontal axis and tuibin blades are mounted which are set in motion by the wind. Turbine blades with a specific shape such as a convex configuration are used for this purpose, the purpose of which is to limit the turbulence of the air flow.

The use of turbines with a vertical axis is also known. The problem now arises, however, that with a changing wind direction the guidance of the air flow does not always take place optimally.

Our invention therefore has for its object to realize a device which allows the air flow to be guided to the rotor in an optimum manner, regardless of the wind direction. Both the position of the guide plates and the number are important here.

The number of vertically placed guide plates is preferably between 2 and 16.

The layout and modular construction of the various components makes it possible to use them for both industrial and domestic use.

The modules can be tailor-made depending on the intended application, wind strength and location. This offers an advantage.

We have determined experimentally that the number of vertically placed guide plates determines the number of necessary rotor blades used. The number of rotor blades is therefore considered as a function of the number of vertical guide plates.

As a result of the aforementioned, the angle at which the vertically placed guide plates are arranged around the vertical axis of rotation becomes dependent on the number of applied guide plates. In addition, the width of the vertical guide plate is determined by the radius of the rotor or vice versa.

The guide plates, arranged horizontally to vertically, are fixed between the vertically placed guide plates in such a way that the wind current, regardless of the wind direction, moves optimally to the rotor.

The structure of the rotor determines the direction of rotation of the rotor. The rotor is constructed according to the principle of traditional windmills with a horizontal axis, with the difference that rotor blades are added.

Due to the structure of the various modules, the air flow moves from the 1 * "to the 2" * ®, to the roof construction of the wind installation. In this way, each parent module benefits from the surplus of remaining wind power (energy) from the underlying module. This offers an advantage.

Lifting the roof structure and the generator module can be inserted as many intermediate modules as necessary. This offers an advantage.

In the case of large structures, the roof construction of the wind device can be equipped with solar panels. This offers an advantage.

The design and modular construction of the various components makes it possible to install them on a flat roof or on a roof with a certain slope. The wind device can also be used without problems in places with continuous wind displacement between, among other things, buildings, the so-called tunnel effect.

A specially designed module is made to measure according to the roof construction of the building.

The invention and its operation are then explained in detail with the aid of a Figure 1. It comprises the different types of modules with the vertically arranged guide plates and the number of horizontally to vertically arranged guide plates in side and top view.

Figure 1: Top and side view of a wind device. Ex. : 10 vertically placed guide plates.

The wind device has one rotor (A) per module M1 and M2. This rotor is equipped with horizontal rotor blades (C1-C2). A series of fixed vertically positioned guide plates (F) are provided around the periphery of the rotor shaft. These vertical guide plates are flat plates that extend at a certain angle and at a certain distance from the central rotor axis.

The roof finish of the wind device has one rotor (B). This rotor is equipped with horizontal rotor blades. This rotor is not necessary. For large versions, solar panels can be installed on the roof finish.

The direction of rotation of the rotor depends on the structure and construction of the rotor and not on the guide plates.

If we consider, according to the plan view in Figure 1, that the circumference of a circle is divided into 10 equal imaginary language pin, we obtain a polygon with 10 equal angles of 36 °. In this way we obtain the imaginary lines on which the vertically placed guide plates (F) are positioned.

Each outer extremity (F1) of the vertical guide plate (F) always lies on the same imaginary line that connects the center point O of the rotor shaft as the inner extremity (F2) of the same vertically placed guide plate (F). The inner extremity (F2) starts at a certain distance OF2 from the central rotor axis.

The module M1 is the generator module or roof module of the building. This module can be adjusted depending on the angle of inclination of the roof construction of the building on which the wind device is installed. With a flat roof, the generator can be located in this module. For a roof with a certain slope, the generator is located under the roof of the building (under H).

In Figure 1, the module M1 is provided with five guide plates (G0-G1-G2-G3-G4) arranged horizontally to vertically. They are placed between the vertically placed guide plates in such a way that the wind current, regardless of the wind direction, moves optimally to the rotor.

The module M2 is provided in Figure 1 with four guide plates (G0-G1-G2-G3) arranged horizontally to vertically. They are placed between the vertically placed guide plates in such a way that the wind current, regardless of the wind direction, moves optimally to the rotor.

The M2 module is a transition module or intermediate module. It is placed between the roof finish of the wind device and the generator module M1. Only this transition module can occur several times. Modules are added depending on the location and wind quantity. In the example. from figure 1 these are 2 modules M2.

The roof finish of the wind device has no guide plates. This construction serves for the roof mounting and the mounting of the rotor shaft. It can, but this is not necessarily provided with a horizontally placed rotor.

Figure 1 shows the mechanism for effecting the transfer from the rotor to the generator, not shown in detail. It is obvious to a person skilled in the art that a conventional device, as known in the state of the art, qualifies for this and therefore also forms part of the scope of protection of this invention.

The rotor (A) is, according to the plan view in Figure 1, provided with 10 horizontal rotor blades (C1) and 20 horizontal rotor blades (C2). The horizontal rotor blades (C1) extend from the central transmission shaft (O) of the rotor to the outside of the structure, up to the point E. The horizontal rotor blades (C2) extend from the points E, E2 and E4 to the outside of the structure, up to the points E1, E3 and E5 respectively. This type of structure of the rotor is indicative and may take a different form.

The rotor blades in this example are made of plastic and reinforced with fiberglass and epoxy resin. It is evident to the person skilled in the art that other rotor types and materials which achieve the required properties of the aforementioned materials also fall within the scope of this invention.

Another embodiment according to the same principle as figure 1 is explained in detail with the aid of a corresponding figure 2.

Figure 2: Top view of a wind device. Example: Arrangement with vertically placed guide plates between buildings or places with continuous wind displacement. The well-known tunnel effect.

Because the wind device is placed between eg. 2 buildings, according to the principle of the tunnel effect, the wind can only come from two directions.

This embodiment differs in that the middle vertical guide plates and the associated guide plates placed in between are superfluous from horizontal to vertical.

The vertically placed guide plates F are extended from the outer extremity F1 to the adjacent wall, the adjacent additional identical wind device or the point J.

This embodiment differs in that, depending on the width between, among other things, two buildings or places with tunnel effect, several identical wind devices can be placed next to the first wind device.

In the example. Top view figure 2 there are two of these.

In the other case, a wind device with larger dimensions can be constructed. The size of the rotor is hereby adjusted proportionally.

Claims (12)

1 A wind device with a vertical axis of rotation for generating electrical energy consisting of different level modules, each comprising both its own rotor and a number of fixed vertically arranged guide plates, which are located around the periphery of the central axis to which the rotor is mounted, with inner and outer extremities and between which fixed guide plates arranged horizontally to vertically are mounted, so that with an alternating wind direction the air flow optimally takes place to the rotor. A wind device with a vertical axis of rotation for generating electrical energy according to the preceding claim and characterized in a wind direction consisting of one roof or generator module for the building and one or more middle or intermediate modules. A wind device with a vertical axis of rotation for generating electrical energy according to the preceding claims and characterized in that an adapted roof module can be used for the building both for flat roofs and for roofs with a certain angle of inclination. A wind device with a vertical axis of rotation for generating electrical energy according to the preceding claims and characterized in that the number of vertically arranged guide plates per module is between 2 and 16. According to claim 4 and characterized in that the wind penetrates frontally between the guide plates, the wind device being placed between 2 vertical walls and the space between these walls being completely filled. 6 According to claim 5 and characterized in that two or more separate wind directions are placed next to each other. A wind device with a vertical axis of rotation for generating electrical energy according to the preceding claims and characterized in that modules can be inserted. A wind device with a vertical axis of rotation for generating electrical energy according to the preceding claims and characterized in that each module consists of one rotor and that each horizontal rotor blade of that rotor starts from the central rotor axis to the outer extremity of the fixed horizontally arranged guide plates . A wind device with a vertical axis of rotation for generating electrical energy according to claim 8 and characterized in that per module consists of one rotor and that each rotor blade of that rotor is made of plastic and is reinforced with fiberglass and epoxy resin. A wind device with a vertical axis of rotation for generating electrical energy according to claim 1 or 5 and characterized in that the device is provided with a generator and is provided with a transmission mechanism. A wind device with a vertical axis of rotation for generating electrical energy according to claim 1 or 5 and characterized in that there is a roof finish for the wind device. 12. A wind device with a vertical axis of rotation for generating electrical energy according to claim 1 or 5 and characterized in that solar panels can optionally be placed on the roof finish of the wind device.