FR2514833A1 - Ducted wind driven turbine - has pivoting vanes in convergent inlet to control turbine speed - Google Patents

Abstract

The ducted wind turbine has an inlet with a convergent conical section, a cylindrical centre section containing the turbine, and a divergent outlet section (8). The inlet has vanes which pivot to control the speed of the turbine and limit the air pressure in the conical convergent section. The vanes are mounted on axes (9) to pivot into the wind, and a vertical fin (6) controls the direction of the duct. The duct is mounted on a roller train to allow pivoting on the ground.

Description

 The present invention relates to a wind turbine, the power of which is directly linked to the nozzle effect and the conventional blades of which are replaced by one or more ring blades supporting fins, of the same type as those used in a turbine. reactor.

 I) In the wind turbines known to date, apart from the different types of wind turbine engines at horizontal or vertical, no one calls for the use of the nozzle effect.

 As a result, and particularly for wind turbines with a horizontal aerator of the 2 or 3 pale propeller type, the energy results of which are the best @@ 3 to date, the main problem, which has caused in @@ in most cases abandoning projects, is the breaking of pale. it should be said that the diameter described at the end of the blade is on average 30, even 50 m in the realizations of power (100 to 1000 KW).

As a result, the constraints at the foot of the blades are enormous and the incipient fractures more often make it necessary to abandon the project.

The maximum recoverable power is defined by the Betz limit, which is: Pw = 0.37 SV3 (S = surface in m
V = wind speed in m / s, 0.37 = constant).

We immediately see that the power is proportional to the cube of the wind speed. The formula giving the maximum power recoverable by an aer @ engine made up of a propeller of diameter D is equal to: Pw = 0.29 (0.29 = constant, D = diameter propeller, V = wind speed,
Pw = power in W). We see that this power is proportional: to the square of the diameter,
to the cube of the wind speed.

In all cases, we see that the power is proportional to the cube of the speed you wind.

 the purpose of the wind turbine of the invention is to overcome the drawbacks of large diameter propellers with the risks of rupture that are known. In addition, the use of a nozzle makes it possible to increase the speed of movement of the air and therefore reduce the diameter of the propeller in large proportions, this at equal or even greater power.

- The wind turbine, object of the invention, consists of a
converging air inlet cone trunk or ad collector
mission. This truncated cone is connected to a cylindrical part
in which are placed, concentrically to it,
a turbine type propeller and a generator. In back
the cylindrical part, <iii ti @ of divergent cone
is used for aerodynamic air flow.

- In the converging truncated cone or intake manifold
sion, shutters allow, in case of blows tie winds
or speeds of -nts too erai..ìes, to limit the
pressure at the bottom of the truncated cone or ad collector
mission and, by that very fact, to be able to regulate the speed
of rotation of the tur @@ e.

- The converging truncated cone assembly (intake manifold
sion), cylindrical part, pl @ s divergent truncated cone,
constitutes a nozzle.

- The volume of air recovered @@ é by the converging truncated cone
or intake manifold being very important by rap
port to the section of the cylindrical part, it follows
an increase in the speed at which the air starts to grow
in this cylindrical part.

In the cylindrical part located at the bottom of the trunk
converging cone, the air flow speed is
very higher> the initial speed at the entry of the
cone; the multiplication factor of up to 6,
or even exceed it. This is due to the fact that the surface
of the circular section (where the aeromotor is located) eJt
reduced in a ratio of up to 6 and even the
protrude from the cross-sectional area
taper of the converging cone trunk.

Therefore, the propeller so placed, not at the entrance of the
trunk of cone co @ vergent, but in the cylindrical part
that placed at the exit of this truncated cone, it is therefore
the on 'this of this section which will enter in the calculation
of the power of the wind turbine.

The air flow speed will not be that at
the entrance of the converging truncated cone (wind speed)
which will be taken into account, but the vitess @ au ni
calf of the cylindrical part (speed increased by one
multiplication factor of up to 6). As
The power is directly proportional to the cube of
speed, we immediately see the benefit of increasing
this one.

- The nozzle-aerogenerator assembly to be oriented
facing the wind, this orientation can be obtained, either
by direct control from a vertical drift,
either by an electric motor-reduction unit controlled
electronically.

- The entire structure of the wind turbine is mounted on
a circular crown; this one, provided with wheels, per
puts the best orientation to the wind. The whole being
articulated on a pivot axis.

- The structure of the entire wind turbine can be realized
traced in wire mesh; the covering of this trellis
Lily being either polyester or sheet metal or even fabric
above coated, of the coated nylon or polyester fabric type
pvc or polyurethane. li is not excluded to realize
the whole in glass-resin laminate, or better in sand
wich glass-resin and polyurea foam hane or balsa, or
both of them.

The realization entirely in reinforced concrete can be equal
envisioned for very large powers.

The present invention will be better understood using an embodiment of a nozzle wind turbine, shown schematically, by way of nonlimiting example, in the accompanying drawings in which
Plate 1-4
Nozzle wind turbine placed on a cliff with (3) representing the adjustable nozzle. (ó) The drift used to orient the assembly (4) the arrows materializing the wind upstream of the wind turbine (5) downstream. (1) the cliff. (2) the sea.

Plate 2-4
Section of a nozzle wind turbine in which there are
(4) arrows showing the wind.

 (3) the converging trunk of cone or trunk of admission cone.

(7) the cylindrical part with its aerator, rator equipped with
his turbine.

 (8) the divergent or exit truncated cone.

 (9) the pivot block used to orient the assembly.

(6) the drift allowing an orientation towards the wind of
the wind turbine.

 (11) the wire mesh structure.

(10) the support wheels allowing the orientation (12) the ground of the site.

Plate 3-4
Schematic view of a nozzle wind turbine (3) converging truncated cone or air intake.

(7) aerogenerator with its blades, placed in the part
cylindrical nozzle.

(8) divergent truncated cone used for air evacuation
with the best aerodynamic flow.

(6) vertical drift plane used for the orientation of the
seems from the wind turbine.

(13) the load shedding flaps allowing, depending on the
wind speed, limit the volume of incoming air
in the cylindrical part and, thereby, the thrust
due to the wind on the whole structure.

These shutters can also be placed on the walls
side of the inlet cone trunk. The mass volumi
as air passing through the cylindrical part; action and
the blades, is limited and always a function of the
wind speed, therefore power.

(9) orientation pivot of the assembly.

(10) undercarriage assembly allowing the structure
to pivot on the floor.

Plate 4-4:
Front view of a nozzle wind turbine with (3) converging truncated cone or wind intake.

(7) cylindrical part of the nozzle with its aerogenerator
equipped with its blades.

(6) vertical drift plane allowing the orientation of
the whole wind turbine.

(14) reinforcing structures, both vertical and horizontal.

(15) boundary between the fixed and mobile part.

(16) spoiler allows ground winds to be recovered
through the trunk of admission one and thereby
sing the air from passing under the structure.

 The nozzle wind turbine, the subject of the invention, finds its application in all cases where, for different reasons, wind energy is used: electricity production, pumping, etc ... and in particular for the production of large electrical power, several megawatts.

However, models of average power @ @ intended for particular uses, are more advantageous than the elastic wind turbines.

 I) the pa @@ iculières applications, as a center of energy production for a municipality, a region, or a coupling of several wind turbines with nozzles to the network, allow the recovery (i'e free energy e @ inexhaustible .

 Of course the invention is not limited to the embodiments described above and shown, from.

which other variants can be provided without departing from the scope of the invention.

Claims (5)

R E V E N D I C A T I O N S  1) wind turbine with nozzle constituted by a converging truncated cone (3) or by admission1 of a cylindrical part (7) in which the wind generator is pleasant concentrically with its turbine made up of blades, and of a truncated cone divergent (8) intended to promote the aerodynamic flow of air, characterized by the fact that load-shedding flaps (13) allow the speed regulation of the turbine and limit the pressure of the air in the trunk of converging cone (.3). The assembly is mounted on a pivot axis (9) used for orientation facing the wind. A vertical fin (6) is used to supply the wind turbine. The entire nozzle wind turbine is mounted on a running gear (10) allowing the structure to pivot on the ground.  20) Nozzle wind turbine, according to claim 1, characterized in that the nozzle consists of a converging truncated cone (3) or inlet, a cylindrical part (7) comprising the aerogenerator and a divergent truncated cone (8) for aerodynamic air flow.  30) A nozzle wind turbine according to claims 1 and 2, characterized in that the converging cane trunk (3) has, on the top and the sides, flaps (13) used for shedding said truncated cone from a certain wind speed and, sitar there, to the speed regulation of the turbine of the wind turbine.  4) Wind turbine according to claim 1, characterized in that the increase in air flow speed at the turbine of the wind turbine, is obtained by the nozzle effect.  5) A nozzle wind turbine according to claims 1 and 3, characterized in that the variation of the air passage sections, between the inlet of the converging truncated cone (3) and the cylindrical part (7), allows a increased air flow speed.  60) nozzle wind turbine according to claim 1, characterized in that the entire wind turbine is mounted on a pivot axis (9) which allows orientation facing the wind.  70) A nozzle wind turbine according to claim i, charac @ erized in that a drift plane (6) allows its orientation facing the wind.  80) Nozzle wind turbine, according to claims 1 and 2, characterized in that the wind turbine assembly rests on a running gear (10) allowing it to pivot around the pivot axis (9) for its orientation  90) Nozzle wind turbine according to claim 1, characterized in that the power being directly proportional to the cube of the air flow speed, the nozzle effect allows, in addition to an increase in power, to use a turbine of small diameter and not a propeller of several tens of meters in diameter.