ITTE20130005A1 - WIND AXLE GENERATOR WITH VERTICAL AXIS ADJUSTABLE EXTERNAL SHELL WITH EFFICIENCY AND SAFETY OPTIMIZATION FUNCTION. - Google Patents

Description

Description of the invention entitled "Vertical axis wind generator with orientable outer shell with the function of optimizing efficiency and safety"

DESCRIPTION

The present invention relates to a vertical axis wind power generator. More specifically, the invention relates to a vertical axis wind generator equipped with an adjustable outer shell which improves its operating efficiency and which, together with the introduction of other apparatuses, guarantees greater safety in use compared to wind generators with vertical axis currently on the market.

One of the typical problems of wind generators is that of safety: in the event of very strong wind, in fact, it is possible that the generator, or parts of it, break under the action of the wind and constitute a danger to things or people. This problem often does not allow the installation of the generator in certain areas or requires the stipulation of expensive insurance policies.

Thanks to the outer shell proposed in this invention, on the other hand, it is possible to counteract the action of external agents.

The present invention will now be described, by way of illustration, but not of limitation, according to a configuration which provides for an impeller with three blades, an outer shell with a very simple shape and other components defined so as to illustrate the operation of the system. It is possible to have impellers of different shapes, with more or less blades, or external shells of different shapes, possibly with very accurate aerodynamics, and with openings, hatches and fins for the orientation of different shapes and sizes. The same considerations apply to all the other components, including those of commercial derivation, which are represented here in simplified form, with the sole purpose of illustrating the operation of the system.

The power that the system can generate is variable, and depends on the size of its components.

create wind generators that deliver low power, for domestic use, or medium-high power, for commercial or industrial use.

Figures 1 and 2 show representations of the system in isometric view, from two different angles, while figure 3 shows a sectioned isometric view, to highlight all the components of the system.

The main components of the generator are as follows:

1. Impeller

2. Rotating outer shell rotating around the impeller axis

3. Security hatch

4. Directional anemometer

5. Basic support

6. Anchoring system of impeller and external shell to the base support

7. Alternator

8. System for handling the shell by means of a control device

Figure 4 shows an exploded view of the system, which shows the main elements of the wind generator.

One function of the rotating outer shell is to direct the wind towards the impeller, regulating its flow and increasing its speed.

The shell is in fact equipped with an orientation system (in the illustration of the invention a fin was hypothesized, without thereby limiting the possibility of using other methods) which allows its orientation (the shell rotates around the axis of the impeller ) so that the opening for the air inlet is always in the orthogonal position to the wind direction, thus guaranteeing the maximum exploitation of the energy source. In this way the wind always comes into contact with the impeller in a direction almost orthogonal to the axis of rotation of the same. The wind is channeled into the front part of the outer shell and therefore assumes the speed, direction and regularity of the flow in such a way as to access the impeller in optimal conditions to transfer its energy to the generator.

Figure 5 shows the operating principle of the impeller: the wind, represented by the larger arrows, transfers its energy to the impeller, which thus rotates around its axis. The alternator, connected to the impeller shaft, produces electricity.

Thanks to the presence of the outer shell, it is possible to orient the direction of the wind and manage the directions of impact on the impeller and away from it. The air, indicated in the figure by arrows, enters the system from the opening on the outer shell with a certain orientation, and exits with a new direction, after having transferred energy to the impeller. The wind energy is transferred to the impeller thanks to the deviation of the air flow, and not, as in the systems currently on the market, due to aerodynamic effects.

The shape of the impeller determines the operating regime of the system, just as the number of blades can influence its efficiency. As previously written, the invention is described here for illustrative but not limitative purposes, therefore it is possible to have impellers of different shapes and sizes, with more or less blades.

Figure 6 shows two representations in isometric view and with the external shell in transparency in order to illustrate the functions of this component.

If the wind changes direction, thanks to the orientation system the system is equipped with, the outer shell will rotate so as to find itself with the opening for the air inlet perpendicular to the wind direction.

For illustrative but not limitative purposes, figure 7 shows a possible electromechanical system for managing the rotation of the outer shell: the anemometer reads the wind direction and this information is processed by a PLC that drives an electric motor (indicated with n.9 in figure 7) until the shell is in position with the inlet opening of the wind perpendicular to the direction of the wind itself. Other methods can be used to achieve the same goal.

Another very important function of the outer shell is to prevent the wind from slowing down the motion of the impeller by dissipating a large part of the energy produced, making it impossible for it to make contact with the impeller blades which are rotating in the opposite direction to that of the wind.

One of the problems of vertical axis wind turbines currently on the market is in fact that of having a loss of efficiency due to the fact that the blades, rotating around the axis of the generator, are braked when they move in the opposite direction to that of the wind. from the wind itself, thus causing a reduction in the rotation speed with consequent efficiency of the system.

The rotating outer shell, preventing the wind from hitting the blades that rotate in the opposite direction to that of the wind itself, leads to an improvement in the efficiency of the generator.

The rotating outer shell can be applied to any vertical axis wind generator, dimensioning it appropriately according to the geometry and characteristics of the generator.

Another important function of the rotating outer shell relates to the security of the system. In case of too strong wind, measured by an anemometer or other similar instrument present on the external shell or near the system, the total or partial closure of the safety door is activated, depending on the wind speed, preventing the impeller rotates too quickly, which could be damaged or come out of its seat.

This allows the system to be used even in very strong wind conditions.

The shell and the impeller are anchored, by means of special retention systems, to the base support of the system. These systems, while ensuring the free rotation of the shell around the axis of rotation of the impeller in order to capture the wind (with the n.12 in figure 8 is represented a possible method to allow the free rotation of the outer shell), prevent it detachment from the support base.

For illustrative but not limiting purposes, it has been hypothesized, to explain this important innovation concerning the safety of the system, that the outer shell is bound to the impeller by means of vertical joints (the free rotation between the impeller and the revolving outer shell can be guaranteed by bearings or other systems).

In figure 8 and figure 9 some details are shown.

The impeller (indicated with n.1 in figure 8), in turn, is vertically constrained to the base support (n.5 in figure 8) which, being fixed with screws or chemical anchors or other suitably sized systems to a fixed base (for example, the roof of a house, a reinforced concrete base or a steel structure anchored to the ground or other support), constrains both the impeller and the rotating outer shell in the direction of the rotation axis. For illustrative but not limitative purposes, Figure 8 shows a possible retention system which, while allowing the shell and impeller to rotate freely, prevents them from detaching from the base support.

Inside the base support there is a guide (detail n.6 in figure 9) in which a special wheel is inserted, called safety device (indicated with n.6), which has the purpose of blocking any translation of the impeller. and of the shell along the direction of the rotation axis. On the axis of the impeller there are in fact some rings (indicated with the n.10 in figure 8) whose position along the axis is adjustable (they have been represented in such a way that they are easily visible in the drawing) which, acting as stops, prevent the axle from passing through the wheel. This therefore prevents any accidental translation along the axis of rotation. Similar locking systems can be used to prevent the upward translation of the outer shell.

In addition to what has been described above, for further safety, it has been hypothesized to also use pins (indicated with the n. 11 in figure 8) that prevent, in extreme cases, the wheel from coming out of the base support.

The one shown is only one of the possible systems that can be used to ensure safety and to constrain both the impeller and the outer shell to the base support. Other methods can be used to achieve the same end.

Claims (1)

Claims of the invention having as title "vertical axis wind generator with orientable outer shell with efficiency and safety optimization function" CLAIMS 1. The adjustable outer shell allows for the management of the inlet and outlet directions of the wind from the impeller: in this way the transfer of energy from the wind to the generator occurs due to the change in wind direction and not only for aerodynamic effects; 2. The adjustable outer shell can rotate in such a way that the wind reaches the impeller, through a special opening on the outer shell, always in an optimal way, orienting and optimizing the air flow to have the maximum possible efficiency; 3. The adjustable outer shell channeling the air flow that acts on the impeller prevents the wind from braking the impeller itself, affecting the blades that move in the opposite way to the direction of the wind and thus reduces energy losses : the efficiency of the generator will therefore be better than the generators currently on the market; 4. The adjustable outer shell is equipped with an automatic partial or total closure system of the wind inlet duct, in order to optimize the speed of the air flow on the impeller or to avoid damage to the impeller itself in the event of excessive wind. loud. The safety of the generator will therefore be considerably better than the systems currently on the market; 5. The adjustable outer shell and the impeller are firmly fixed, by means of special safety systems, to a base, which is in turn securely fixed to the generator application site: in this way, in the event of catastrophic atmospheric events, it is considerably increased the safety of the generator compared to traditional generators currently on the market.