ITNA20120015A1 - WIND POWER PLANT FOR THE PRODUCTION OF ELECTRICITY - Google Patents

Description

â € œWIND SYSTEM FOR THE PRODUCTION OF ELECTRICITYâ €

DESCRIPTION

The present invention relates to wind power plants for the production of electricity, in particular a wind power plant in which the rotating system has a vertical rotation axis and is positioned on a building roof while the multiplier and the generator are positioned below the roof inside the building itself.

As is known, a vertical axis wind power plant consists of a wind rotor which, pushed by the wind, rotates around its own axis. This axis transmits the rotation to the generator, positioned on the vertical of the wind rotor.

More specifically, the rotation axis has at one end the hub on which the wind rotor is fixed, the other end transmits the rotation inside a container where the multiplier and the electric generator are positioned. The multiplier increases the number of revolutions to an adequate value for the operation of the generator; the latter converts kinetic energy into electrical energy.

This traditional arrangement features all the components outdoors. This is the reason why the multiplier and the electric generator are kept in a container with the function of protection from atmospheric agents. The action of the latter on the electrical conductors, but mainly on the electrical generator, makes it necessary to plan verification and maintenance interventions.

The main drawback of this traditional arrangement is precisely the exposure to atmospheric agents of the machinery group of the wind power plant.

Another drawback is the need to carry out assembly and installation operations outdoors. The same problem also arises for the verification and maintenance operations, moreover, a greater difficulty in operating and a need for assistance contribute to making the management of low-power plants less economically advantageous.

Another drawback is the need to use structures to fix the entire system to the surface hosting the installation: it is necessary to avoid the possibility that the entire system can be lifted or moved by the wind.

The purpose of this invention is to provide a plant which overcomes the aforementioned drawbacks.

This purpose is achieved by means of a system in which the rotating system is positioned on the roof of a building. The rotation is transmitted, through the roof, inside the building where the brake and the machine group (multiplier and generator) are installed.

The main advantage of this system structure is that it allows a more comfortable placement of the brake and the machine group so that maintenance or repair operations can be easily carried out without having to climb onto the roof. This results in a reduction in costs which contributes to making low-power plants economically advantageous. This same advantage also occurs in the installation and dismantling phase where the intervention takes place only minimally on the roof.

Another advantage is to provide the brake and the machine group with greater protection from atmospheric agents than that offered by a container.

Another advantage is to use the building to lift the rotating system.

Another advantage is that of being able to install the system on pre-existing buildings using the chimneys on the roof. The chimney pot continues to perform the function for which it was intended and the wind turbine uses the chimney to transmit the rotation through the roof. This advantage translates into a reduction in installation costs in existing buildings.

Another advantage is to position the rotating system at a certain distance from the places where daily life takes place, any noises caused by the rotation of the element exposed to the wind would not be perceptible.

Another advantage is to position the rotating system on the roof of the building, minimizing its visual impact, the rest of the system is not visible.

Another advantage is that there is no need to provide systems for fixing the system to the surface hosting the installation.

These and other advantages and characteristics of the system will become evident to those skilled in the art from the following detailed description of one of its embodiments with reference to the attached table in which:

fig.1 is a schematic sectional view of a plant. The building has a flue B and a rotating system A. The transmission system C is located partly in the chimney B and partly in the attic where the machine group D is installed, which contains the multiplier and generator;

Fig. 2 shows a schematic view, with greater detail, of the rotating system A in the case in which the wind power plant uses a chimney as a passage through the roof. The rotating system A consists of a base G, a wind extractor E, and a wind rotor F;

Fig. 3 shows a schematic view in greater detail of the rotating system A when the wind power plant uses an exclusive passage through the roof. The rotating system A consists of a base G and a wind rotor F;

Fig. 4 shows in detail a schematic view with greater detail of the transmission system C in the case in which the wind power plant uses a chimney as a passage through the roof. The axis of rotation I has the hub M at one of its ends, the ball bearings H, the brake O, the cardan joint L and the casing N.

Referring to fig. 1, it can be seen that the wind power plant is characterized by a precise location of its components.

The installation of the system is carried out on a building. The necessary element is the presence of the roof which can be horizontal or sloping. It follows that any building can be used: building, cottage, terraced house, detached house, but also industrial shed, stable or shed. The rotating system A with vertical axis is installed on the roof. As regards the passage of the mechanical transmission C through the roof, in the case of an opening specifically provided for the wind power plant, the rotating system A consists of a base G and a surface exposed to the wind F (fig.3). On the other hand, in the case of a pre-existing chimney pot in the building: fireplace, stove, kitchen, air intake, faecal vent: the chimney pot itself must be replaced by a rotating system A with a base G, a wind extractor E , a wind rotor F (fig 2).

The energy that the plant is able to produce is a direct consequence of the size of the surface exposed to the wind, its aerodynamic efficiency and the strength of the wind. The rotating system A represents one of the most important elements in a wind power plant. The present invention relates to the plant in its generality and not individually to the rotating system. On the market there are different types of rotors with helical shape, consisting of curved surfaces or consisting of flat blades arranged in space so as to represent a certain surface exposed to the. The only conditions required are that the rotating system A has a base G which does not rotate so as to allow fixing to the roof and a rotating element on which to fix the hub of the rotation axis. The issue of delivered power will be dealt with later.

The brake O has the task of stopping the rotating system if the wind exceeds the cut off threshold (limit beyond which there is the risk of damaging the regret). It acts directly on the axis of rotation I and must be positioned higher than the cardan joint L in order to limit twisting of the axis of rotation and avoid work loads on the cardan joint which could cause it to break.

The rotating system A is installed to completely cover the roof opening, the multiplier and the generator are installed directly in its vertical. The axis of rotation I has at one end a hub M which is fixed to the rotor F, transmits the rotation through the roof, transferring it to the multiplier. The axis is held in vertical position by H ball bearings which allow it to rotate but not translate. If an existing chimney pot is used, it is advisable not to install a multiplier and generator inside the chimney so as not to attenuate the draft. A cardan joint connects the axis of vertical rotation I coming from the rotating system with another axis P which brings the rotation to the machine group D. Inside the chimney B, a container in the shape of a tube N must be positioned which contains and protects the moving components of the transmission system C from dust and / or combustion residues present inside the chimney B. Then a pipe, integral with the chimney itself, which starts from the hub M, descends at the center of the chimney B a curve in correspondence with the cardan joint L and exits from the chimney B. After exiting the chimney, the rotation axis P extends the transmission system until it reaches the machine group D.

Wind power plants differ enormously in size and power output. The size of the turbines has grown with the increase in consumption. We have gone from the 50 kW machines of the early 1980s to the gigantic 3 MW turbines. The preference for increasingly larger wind generators has gradually made those of small and medium power (up to 500 kW) disappear from the market. The reasons for the renewed interest in mini and microturbines arise in particular application areas not served by the electricity grid such as remote mountain or island settlements, or in stand-alone users.

A further boost to the use of renewable energies comes from the increase in the cost of energy which contributes to making micro-wind applications increasingly economically viable even in plants connected to the grid and used for supplementary supplies.

A vertical axis wind power plant having an area exposed to the wind of 1 m? manages to provide a power of 0.5 kW. The use of a rotating system A with a larger surface exposed to the wind increases the energy obtained, moreover more systems can be installed on the same building, (in which case the installation costs are further reduced as the different systems use a single inverter). The goal of the plant is clearly the supply of renewable energy with a view to diversification. The energy autonomy of the building is an objective that must be achieved with a series of parallel paths, one of which is the adoption of the system described.

The embodiment of the device according to the invention constitutes only an example susceptible of numerous variations. In particular, the rotating system A can have any shape, the generator can be of any type such as the brake O and the multiplier, the transmission system C will have characteristics depending on the structure of the building. The components described can also be replaced by other mechanically equivalent ones, for example the ball bearings H can be replaced by magnetic bearings, the cardan joint L can be replaced by a toothed wheel system so that a single element modifies the ™ axis and multiplies the rotation.

Similarly, the position in which to install the individual components of the wind power plant depends on the morphological characteristics of the building. As anticipated, if the machine group D can be positioned directly on the vertical of the rotating system A, the system is simplified by eliminating the cardan joint L, the protective tube N and the horizontal section P of the rotation axis .

Any additions and modifications may therefore be made to the plant object of the present invention without however departing from the scope of protection of the invention.

Claims (11)

â € œWIND SYSTEM FOR THE PRODUCTION OF ELECTRICITYâ € CLAIMS 1) Wind power plant for the production of electricity, consisting of a vertical axis rotating unit (A), a transmission system (C), a brake (O), a multiplier and an electric generator. The system has the characteristic of being installed on a roof that has an opening dedicated to venting the ventilation / venting / heating system. The two systems share the same openness, each continuing to work independently. The aforementioned system components have compatible and specific characteristics for the described actuation. 2) The wind power plant referred to in point 1, characterized by the fact that the rotating unit (A) is installed on a building roof, the brake (O), the multiplier and the generator are installed below the roof, the transmission system (C) transmits the rotation through an opening in the roof itself. 3) The wind power plant referred to in the previous points, characterized by the fact that, if the opening of the roof of the building referred to in point 2 is the terminal element of a ventilation / venting / heating system, the transmission (C) is contained in a cylindrical container (N). 4) The wind power plant referred to in point 3, characterized by the fact that the cylindrical container (N) referred to in point 3 is integral with the chimney. 5) The wind power plant referred to in the previous points, characterized by the fact that the base (G) of the rotating unit (A) is fixed to fully cover the opening referred to in point 2. 6) The wind power plant referred to in the previous points, characterized by the fact that the rotation of the axis of the transmission system (C) is allowed and protected by ball bearings (H). 7) The wind power plant referred to in the previous points, characterized by the fact that, if allowed by the morphology of the building, the generator is installed vertically in the rotating group (A). 8) The wind power plant referred to in point 7, characterized by the fact that, if allowed by the morphology of the building, the transmission system (C) has a vertical axis (I). 9) The wind power plant referred to in the previous points, characterized by) the fact that, if the morphology of the building does not allow the installation referred to in point 7, the transmission system (C) has a vertical axis (I) and a non-vertical axis (P). 10) The wind power plant referred to in point 9, characterized by the fact that if the morphology of the building does not allow the installation referred to in point 7, the transmission system (C) has the axes referred to in point 9, linked together with a gimbal / gear wheel system (L). 11) The wind power plant referred to in the previous points, characterized by the fact that the braking system (O) acts in the vertical axis (I) of the transmission system (C).