ITAO20090001U1 - WIND FLEXIBLE AERODYNAMIC WIND GENERATOR (PAF). - Google Patents

Description

DESCRIPTION of the utility model having as TITLE:

"FLEXIBLE AERODYNAMIC BLADES GENERATOR (PAF)" ,.

SUMMARY

The wind generator in question is of the aerodynamic blade type with main development parallel to the rotation axis (blades having their largest dimension parallel to the rotation axis). The aerodynamic blades are flexible (like "sails", therefore able to change their curvature) C linked to the axis of rotation of the generator through a device (subject of the claim) which allows to optimize the incidence with respect to! relative wind that touches them, in order to obtain a resultant of the aerodynamic forces always generating the maximum possible torque with respect to the rotation axis itself.

State of the art at the time the description is filled in:

Compared to similar wind generators currently on the market (with aerodynamic blades with main development parallel to the rotation axis of the generator), the flexibility of the PAFs and the aforementioned device allow to increase Γ amplitude of the sectors around the rotation axis in which the aerodynamic blades generate power, active.

DESCRIPTION

Table No. 1 shows the section perpendicular to the rotation axis 0 of the generator * (through the rotation of this axis O it is possible to use the mechanical energy generated by means of the PAFs, represented by the arcs, of circumference having one of the ends in the points A),

Direction and relative wind direction are indicated by black arrows,

Π direction of rotation around the O axis is counterclockwise. The speed of rotation around the O axis must be low enough to be able to consider negligible the effects of centrifugal forces on the PAF compared to the effects of the aerodynamic forces acting on them,

Each PAF has an extremity constrained to an axis A, around which the PAF is free to rotate. The excursion of the other end of each PAF is limited by elastic bodies (in table N, 1 stylized in the shape of a spring) or better by bodies with variable elongation according to the dislocation of each PAF, to optimize the incidence with respect to the wind. relative.

Each elastic / extensible body has one end constrained to an R axis, around which it is free to rotate.

All axes A are constrained to the axis of rotation O and rotate with respect to it following the dotted circular trajectory. Each A axis always maintains the same relative position / distance with respect to the other axes Λ.

All the B axes are constrained to the rotation axis O and rotate with respect to it following the dashed circular trajectory (which could in any case have a radius, with respect to O, different from that of the trajectory of the A axes, in order to optimize the incidence of the PAF relative to the relative wind). Opti axis R always maintains the same relative position / distance with respect to the other B axes. However, it must be possible to move the B axes closer / further away from the A axes by moving them along the dotted trajectory in order to modify the incidence and therefore the aerodynamic efficiency of the PAFs. . By superimposing the AO and BO spokes of the same body "PAF - elastic body", the PAFs can be placed in the "flag" condition and thus minimize aerodynamic drag and torque with respect to the O axis (in the event of excessive wind, for example),

The two squared sectors are those within which there is the flag-waving of the PAFs with a change in their tack. In these sectors, PAFs do not generate counter-clockwise torque.

Claims (1)

CLAIMS 1) Each flexible aerodynamic blade shown in table N. I has only one constrained end, an end around which the PAF is free to rotate. In order to optimize the incidence of the PÀF with respect to the relative wind, the excursion of the other end of each PAF is conditioned by the elongation of an elastic / extensible body, which in turn is bound to the PAF for one end, while for the other is only free to rotate.