A collapsible wind turbine includes a turbine with a vertical axis (A). The turbine is supported by a vertical pylon, pivotably mounted about a hinge, and by linking members connecting the rotation shaft of the turbine to the pylon while maintaining a separation therebetween. The wind turbine includes: —an electricity generator of which the axis of rotation is perpendicular to the longitudinal axis of the pylon, the generator being secured to the ground; and—at least one flexible link connecting and synchronising the rotation of the generator with the rotation shaft of the turbine by linear travel of the flexible link in a closed-circuit path, so as to drive the rotation shaft of the generator by the movement of the turbine. The present structure is, in particular related to land-based wind turbines in a cyclone-prone area.

BACKGROUND

The present invention relates to a collapsible wind turbine comprising a turbine with a vertical axis. The turbine is supported by a vertical pylon, mounted pivotably about a hinge, and by linking members connecting the rotation shaft of the turbine to the pylon and maintaining a separation therebetween.

The wind turbine comprises:an electric generator, the axis of rotation of which is perpendicular to the longitudinal axis of the pylon, the generator being secured to the ground, andat least one flexible link connecting and synchronizing the rotation of the rotation shaft of the generator and the rotation shaft of the turbine by linear travel of said flexible link in a closed-circuit path, so as to drive the rotation shaft of the generator by the movement of the turbine.

The field of the invention is in particular that of land-based wind turbines, and more particularly of wind turbines installed in isolated areas and/or areas at high risk of earthquakes and/or exposed to extreme winds, or even cyclones.

Electricity generation is a crucial issue at present. Technologies for generation from renewable energy sources have been developed on the one hand in order to diversify the sources for supplying energy and on the other hand in order to generate electrical energy ecologically. Thus, wind turbines have been developed and installed in particular on land where there are no or very few obstacles and there is an easily accessible electricity network.

In the field of wind turbines in general, two types of installation are known: wind turbines of the horizontal axis type (called HAWT for “horizontal-axis wind turbine”) and wind turbines of the vertical axis type (called VAWT for “vertical-axis wind turbine”).

Wind turbine installations in areas prone to cyclones have also been developed. These wind turbines generally have the additional feature of a mast that can be collapsed to the ground in order to protect them from projectiles and wind force, beyond a certain threshold.

Document FR2920206 is known, which describes a wind turbine of the horizontal axis type comprising a collapsible mast mounted pivotably about a hinge arranged in an intermediate position between the lower and upper ends of the mast, the lower part of the mast forming a counterweight. The wind turbine comprises an electric generator located close to the ground, a transmission chain, extending inside the mast, which can be used to transmit the movement of the rotor to the generator.

Document FR2912450 is also known, which describes a wind turbine of the horizontal axis type comprising a support mast hinged to the ground and supporting an impeller with a horizontal axis, a hoisting mast, a hoisting cable connecting the hoisting mast to the ground, and an operating device suitable for varying the length of the cable so as to selectively collapse and raise the support mast. The hoisting mast is hinged to the ground independently of the support mast, and is suitable for following the support mast and collapsing completely until horizontal once the support mast has collapsed.

These embodiments have the drawbacks of having heavy hoisting devices which are complex and expensive.

Document U.S. Pat. No. 5,252,029 is also known, which describes a wind turbine of the vertical axis type comprising a hollow rotor shaft mounted vertically on a support structure with two, three or four rotor blades in a troposkein configuration on the rotor shaft in order to turn the shaft in response to the wind energy and to drive a generator in order to generate electrical energy. The turbine comprises an erecting hinge and a hoisting mast which allows the turbine to be raised by cable with the aid of a simple winch mounted at or near ground level.

This embodiment has the drawbacks of having a complex and expensive mechanical link, because of the presence of several coaxial shafts and oversized rolling bearings at the base of the mast.

An aim of the invention is to overcome, in full or in part, the drawbacks of the prior art. An aim in particular is both to reduce the wind turbine manufacturing and/or installation costs and to improve the reliability of wind turbines intended for isolated areas and/or areas at high risk of earthquakes and/or exposed to extreme winds, or even cyclones. Another aim of the invention is to make it easier the maintenance of wind turbines.

SUMMARY

According to the invention, at least one of the abovementioned aims is achieved with a collapsible wind turbine comprising:a turbine with a vertical axis and cross flow, the turbine comprising blades moved by the wind,an electric generator, the generator shaft of which rotates about a generator axis, driven in rotation by the turbine,a structure for holding the turbine, which comprises at least one vertical pylon, with a longitudinal axis, and a pivot hinge, said pylon being connected to the ground by said hinge and being mounted pivotably about said hinge according to a folding axis, typically horizontal, between a substantially vertical working position and a collapsed position, which is for example substantially horizontal.

According to the invention, the wind turbine comprises:top and bottom link members, which rigidly hold the turbine by its axis of rotation and maintains a separation between it and the pylon, the axis of rotation of the turbine being parallel to the longitudinal axis of the pylon, andat least one flexible transmission link connecting and synchronizing the rotation of the rotation shaft of the generator and the rotation shaft of the turbine by linear travel of said at least one flexible link in a closed-circuit path, such that the movement of the turbine drives the generator by its rotation shaft.

The wind turbine according to the invention has the advantages of limiting the mass of the wind turbine at its top and of lowering the centre of gravity of the wind turbine, which has the result of reducing the mechanical stresses in the pylon and therefore of reducing the quantity of material needed to produce said pylon, because of the reduction of the weight compared with horizontal-axis wind turbines and wind turbines with a troposkein configuration. Among other things, the reduction of the weight in general, and at the top of the pylon in particular, has the effect of making it easier to erect or tilt the pylon and/or of using a simpler and/or less expensive hoisting device. The wind turbine according to the invention thus proposes an improved reliability and a reduced manufacturing and installation cost compared with the collapsible wind turbines of the prior art.

By cross-flow turbine is meant a turbine arranged and configured to receive a flow of air in a direction substantially perpendicular to the axis of rotation of the turbine. Here, the turbine used has a substantially vertical axis of rotation.

Typically, the turbine comprises several rigid blades, distributed around its vertical axis, which extend between the top linking member and the bottom linking member. Each blade has, for example, a vertical part at a distance from the axis and rigidly connected to the centre of rotation by its end.

According to an embodiment, the turbine comprises at least two blades. The blades extend in a vertical direction. Each blade extends at each of its two ends by an arm. The blades extend mainly in a longitudinal direction and the arms extend mainly in a transverse direction. The blades describe cylinders when rotating. The arms are connected to shaft elements by pivoting links forming the axis of rotation of the blade. According to a first example, the turbine comprises two blades. According to a second example, the turbine comprises three blades.

Preferably, the wind turbine comprises a single turbine. The turbine comprises two blades extending vertically which are arranged diametrically opposite with respect to the axis of rotation of the turbine, each blade comprising an upper arm and a lower arm extending to the axis of rotation from respectively a top end and a bottom end of said blade, each arm extending substantially horizontally.

Each linking member holds one end of an axis of rotation of a turbine. The top and bottom linking members extend from the pylon. The bottom linking member holds the lower end of the axis of rotation of the turbine. The top linking member holds the upper end of the axis of rotation of the turbine. The top and bottom linking members respectively comprise a rotation shaft element such that each shaft element has a pivot link with an axis with respect to a linking member.

For example, a linking member can be a rib or a spar. It extends substantially transversely and/or horizontally.

The linking members make it possible to hold each turbine by a pivot link. They make it possible to eliminate the need for a central drive shaft.

Preferably, in the case where the wind turbine comprises a single turbine, each top and bottom linking member comprises respectively a top shaft element and a bottom shaft element, which are coaxial with each other, and the turbine comprises a top hub and a bottom hub in such a way that the upper arms of the blades are secured to the top hub and the lower arms are secured to the bottom hub, the top and bottom hubs being mounted rotatably about the top shaft element and the bottom shaft element respectively.

Preferably, the electric generator is placed at the foot of the vertical pylon and is joined to the ground. This feature makes it possible not to have to raise the electric generator while the pylon is being erected. Moreover, the generator can be constantly protected from excessive winds or projectiles thrown by these excessive winds.

The generator axis extends in a direction which is parallel to a horizontal plane such as the ground, and/or perpendicular to the longitudinal axis of the pylon when the latter is in a vertical operating position. Preferably, the generator axis extends in a direction which is parallel to the folding axis of the hinge. This feature makes it possible not to have to take down the link of the rotation shaft of the generator because the latter pivots at the same time as the pylon.

According to a preferred embodiment, the axis of the generator is substantially coaxial with the folding axis of the hinge.

Preferably, the wind turbine comprises:a rotor wheel, rotationally joined to the rotation shaft of the turbine,a generator wheel, rotationally joined to the rotation shaft of the electric generator,a deflection device of the path of the at least one flexible link, arranged between the rotation shaft of the turbine and the rotation shaft of the generator.

The rotor wheel, the generator wheel and the deflection device are arranged in order to receive the at least one flexible link and to couple the rotation of the generator to the rotation of the rotor. The deflection device forms, for the at least one flexible link, a deflection which is arranged on the path of the flexible link.

The deflection device makes it possible for the at least one flexible link to follow a path along a horizontal plane of the rotor wheel and a substantially vertical plane which descends towards the bottom of the pylon. The deflection device makes it possible for the at least one flexible link to follow a path along the pylon and along one of the linking members.

Preferably, the rotor wheel is arranged on a bottom linking member, which makes it possible to reduce the length of the closed-circuit path of the at least one flexible link.

According to an embodiment, the deflection device comprises two idler wheels, which are coaxial with each other and rotatable about a deflection axis of rotation which is perpendicular both to the axis of rotation of the turbine and to the generator axis.

Preferably, the at least one flexible link is arranged on the outside, at least, of the pylon. This feature makes it possible to make the manufacture, installation and maintenance of the wind turbine easier.

For example, the at least one flexible link can be produced in the form of a timing belt, cable or chain.

In the preceding and in the remainder of the specification, by “wheel” is meant any wheel or pulley arranged and configured to receive a belt or a cable, or any toothed wheel arranged and configured to receive a chain and able to cooperate by adherence and/or engagement therewith.

According to an embodiment of the wind turbine, the diameter of the rotor wheel is at least twice as large as that of the generator wheel. The rotor wheel has a circumferential surface and therefore a surface of contact with the at least one flexible link making it possible to ensure the transmission of the torque by adherence and/or engagement between the turbine, via the rotor wheel, and the at least one flexible link.

Preferably, the wind turbine comprises a braking device, comprising:a brake actuator,a brake disc rotationally linked to the rotor wheel, andat least one brake lining arranged between the brake actuator and the brake disc.

The brake actuator is arranged and configured to act, during braking, by friction on the brake disc via the at least one brake lining.

Whatever the embodiment, the turbine is located at least three metres and/or at least one or even two times the height of the turbine away from the ground.

According to an embodiment, the wind turbine comprises a hoisting device. Preferably, the hoisting device comprises a winch, at least one cable connected both to the winch and to the top of the pylon, and a hoisting arm secured to the pylon in a perpendicular position. For example, the hoisting arm is secured to the base of the pylon.

Optionally, the turbine comprises a pull line connecting the two blades to each other and extends substantially horizontally to approximately halfway up the turbine. This feature makes it possible to hold the blades.

Optionally, the wind turbine comprises at least one photovoltaic panel secured to the pylon.

Again optionally, the wind turbine comprises a control unit arranged and configured to remote-control, in an automated manner, the electric generator and/or the winch of the hoisting device and/or the brake actuator of the braking device.

DETAILED DESCRIPTION

The embodiments which will be described in the following are in no way limitative; in particular, variants of the invention will be able to be implemented which comprise only a selection of features described hereinafter in isolation from the other features described if this selection of features is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art. This selection comprises at least one, preferably functional, feature without structural details, or with only a part of the structural details if this part alone is sufficient to confer a technical advantage or to differentiate the invention with respect to the state of the prior art.

In particular, all the variants and all the embodiments described can be combined together if there is no objection to this combination from a technical point of view.

FIGS. 1, 3 and 4illustrate a collapsible wind turbine10of the vertical axis type (called VAWT for “vertical-axis wind turbine”) and with cross flow. The wind turbine is arranged and configured to collapse from a first, vertical position, called the operating position, to a second, horizontal position, called the protection position. The collapsible wind turbine is intended to be installed in isolated areas and/or areas at high risk of earthquakes and/or exposed to extreme winds, or even cyclones. In case of risk, it is thus possible to collapse the wind turbine to the ground in order to protect it, for example from projectiles propelled by the wind. It also becomes easier to dismantle it if necessary.

Tie rods, cables or guy wires (not shown) are used to hold the wind turbine in position with respect to the ground and to prevent it from swaying.

With reference toFIGS. 1 and 2, the wind turbine10comprises a turbine30having a vertical axis of rotation A. The turbine30comprises two blades32. The turbine30comprises two blades32which extend vertically and, during operation, are subjected to the action of the wind in order to make the turbine rotate. The blades32extend parallel to the axis of rotation A of the turbine and are arranged diametrically opposite with respect to said axis of rotation A.

Each blade32extends at each of its two ends, a top end and a bottom end, by a horizontal arm. At the top end, each blade32extends by an upper arm33. At the bottom end, each blade32extends by a lower arm31. The upper33and lower31arms are connected respectively to the blade32by a curved bend. The blades of each turbine describe a cylinder when they rotate. The arms are connected to shaft elements by pivot links forming the axis of rotation of the blade, seeFIGS. 5 and 6for the shaft element45of the bottom linking member. For example, all of the lower arms or all of the upper arms of the turbine are connected to a hub which is itself rotatable relatively about a shaft element forming the axis of rotation of the blade, the shaft element being rigidly secured to a linking member, see below. In this configuration, the central space between the blades does not comprise a rotation shaft and is completely empty.

With reference toFIG. 2, the turbine30comprises two turbine axis hubs, a top hub36and a bottom hub34. The hubs36and34are rotatable about shaft elements with a reduced height of axis A. Each upper arm33is secured to a top hub36(seeFIG. 2) and each lower arm31is secured to a bottom hub34(seeFIGS. 2 and 5). The bottom hub34is rotatable about the bottom shaft element45, seeFIG. 5.

Preferably, the hubs are produced from a metallic material and the blades are produced from a composite material, for example based on carbon fibres.

The wind turbine10comprises a holding structure40for the turbine30. Said structure comprises a pylon20extending along a longitudinal axis L. The axis L of the pylon20is substantially parallel to the axis of rotation A of the turbine. During operation, the pylon20is located in a vertical position, seeFIGS. 1 and 5.

The holding structure for the wind turbine10comprises linking members, a top linking member43and a bottom linking member41, securely connected to the pylon20which supports the rotation shafts of the turbines and maintains a separation between them and the pylon. With reference toFIG. 1, the wind turbine10comprises a top linking member43and a bottom linking member41for supporting the turbine30. The top linking member43extends substantially from the top of the pylon; the bottom linking member41extends from the pylon, in this example at approximately halfway along it. The bottom linking member is preferably located at least three metres away from the ground S. The top43and bottom41linking members thus hold the turbine at its ends by a pivot link, eliminating the need for a central drive shaft between the blades.

With reference toFIGS. 1 and 4, the holding structure for the wind turbine10comprises a pivot hinge22of the pylon20relative to the ground S, in such a way that the pylon20is connected to the ground S by said hinge. The hinge22produces a pivot link with a horizontal axis, called the folding axis R. The folding axis R is perpendicular to the longitudinal axis L of the pylon20, seeFIG. 1. According to an embodiment, the holding structure comprises a set of feet21,23secured to the ground, seeFIGS. 3 and 7. With reference toFIG. 7, each foot21,23comprises a bore provided to produce the female part of the pivot hinge22. The feet21and23are arranged with respect to each other in such a way that the bores are coaxial with each other in order to receive a pivot shaft. Moreover, the holding structure comprises a pivot shaft24, referenced only inFIG. 7. The latter is connected securely to the base of the pylon such that it extends in a direction perpendicular to the longitudinal axis L of the pylon. The pivot shaft24is mounted in the bores of the feet21and23in order to produce the pivot hinge22. The pivot hinge22makes it possible to pivot the wind turbine between a substantially vertical operating position and a substantially horizontal collapsed position.FIG. 4shows an inclined intermediate state between said positions.

With reference toFIGS. 3 and 4, the wind turbine comprises a hoisting device80in order to actuate the pivoting thereof.

The hoisting device comprises a winch81secured to the ground and a cable83connecting the top of the pylon and the winch81, seeFIG. 4. The hoisting device moreover comprises a hoisting arm82rigidly secured perpendicularly to the pylon20. With reference toFIG. 7, the hoisting arm82is secured to the pivot shaft24of the pylon20. With reference toFIG. 4, the hoisting arm82is secured to the base of the pylon, so as to create a lever arm, moving the traction point of the cable83away from the pylon20, thus making it easier to lift the wind turbine. The cable83must lean on the distal end of the hoisting arm82. The winch81is arranged at a distance from the base of the pylon and in such a way that the cable83leans on the hoisting arm82, which holds it away from the hinge22, seeFIG. 4.

The wind turbine comprises an electric generator70in order to convert the mechanical energy from rotation of the turbine into electrical energy. With reference toFIGS. 1, 3 and 7, the electric generator70comprises a rotation shaft71rotatable about the generator axis G. The shaft of the generator is driven in rotation by the rotation of the turbine. With reference toFIG. 1, the generator is located at the base of the pylon20and is secured to the ground S. According to a preferred embodiment, the generator axis G is substantially coaxial with the folding axis R of the hinge. This feature makes it possible not to lay down (or loosen) the mechanical transmission means between the generator and the turbine, because they are pivotable about the same axis. Advantageously, the generator can be arranged totally independently with respect to the pylon without interfering with the erecting or lowering movements thereof. Preferably, the generator is a variable speed permanent magnet generator.

The wind turbine moreover comprises a flexible link60as mechanical transmission means between the turbine and the generator, seeFIGS. 1, 3, 5 and 7. The flexible link, for example a belt or chain, is arranged and configured in order to connect and synchronize the rotation of the rotation shaft of the generator and the rotation shaft of the turbine by a linear travel in a closed-circuit path.

With reference toFIG. 5, the wind turbine comprises a rotor pulley64arranged coaxially with the bottom hub34of the turbine. With reference toFIG. 7, the wind turbine comprises a generator pulley62arranged coaxially with the rotation shaft71of the generator. With reference toFIG. 5, the wind turbine comprises idler wheels68arranged coaxially with each other and mounted freely rotatable with respect to the holding structure. The rotor pulley64, the generator pulley62and the idler wheels68are arranged to receive, on their circumferential surface, the flexible link and to cooperate therewith by adherence. The idler wheels68make it possible to produce a deflection device of the path between the bottom hub of the rotor and the pulley62of the generator such that the path of the flexible link runs along the bottom linking member (seeFIG. 5) and the part of the pylon between the bottom linking member and the base of the pylon (seeFIGS. 1 and 4).

The idler wheels68are arranged vertically and mounted pivotably linked about the horizontal axis, called pivot axis F, with respect to the bottom linking member and the pylon. The pivot axis F is perpendicular both to the axis of rotation A of the turbine and to the generator axis G. The fixed part of the pivot link is secured to the pylon20and/or to the linking member41. Preferably, the fixed part of the pivot link is secured to the pylon. The idler wheels68are arranged relative to the pylon at a height such that the axis F of rotation of the idler wheels is arranged at the same height as the bottom linking member. Moreover, the idler wheels68are arranged such that the geometric plane, containing the rotor pulley, draws a tangent to the circumference of the idler wheels. This feature makes it possible for the at least one flexible link to extend substantially horizontally between the rotor pulley and the idler wheels, and makes it possible to shift the flexible link outside the rotor pulley or idler wheels. Similarly, the plane of the generator pulley62draws a tangent to the idler wheels68. Preferably, the axial spacing of the idler wheels is less than or equal to the diameter of the rotor pulley64.

Owing to the arrangement of the vertical-axis turbine on the wind turbine, the securing of the generator to the ground and the use of a flexible link, the mass of the wind turbine, in particular at the top thereof, is reduced, which has the result of reducing the mechanical stresses in the pylon and therefore of reducing the quantity of material needed to produce said pylon, because of the reduction of the weight compared with the wind turbines of the prior art. Thus, it becomes easier to collapse and/or erect the wind turbine and/or more quickly collapse the wind turbine, for example over a period shorter than 45 minutes. For example, the time it takes to wind up the flexible link can be of the order of 5 minutes during the procedure of erecting or collapsing the wind turbine. Moreover, the strains on the hoisting device are reduced. It becomes possible to use a hoisting winch called standard or of reduced pulling power, which is therefore less expensive.

The wind turbine has the advantage of largely dispensing with expensive and delicate components, namely:the variable-pitch system (in fact, the present wind turbine has a fixed pitch and therefore operates at variable speed in line with a variable-speed permanent magnet generator),the system for orienting the nacelle into the wind (in fact, a wind turbine of the single-rotor vertical-axis type can operate whatever the direction of the wind),the multiplier (in fact, the transmission by cable will make it possible to ensure this function for driving a variable-speed permanent magnet generator),the swivel connector which ensures, on wind turbines of the horizontal-axis type, the electrical connection between the nacelle (mobile) and the mast (fixed).

With reference toFIG. 6, the wind turbine comprises a braking device90of the turbine. In the case of emergency, the braking device makes it possible to slow down, until completely stopped, the rotation of the rotor pulley so as to collapse the wind turbine more quickly.

The braking device comprises:a braking actuator91, connected (not shown) to the bottom linking member41,a brake disc92rotationally linked to the rotor pulley64, andtwo brake linings93arranged respectively between the brake actuator91and the brake disc92.

With reference toFIG. 6, the rotation shaft element45of the turbine crosses the thickness of the bottom linking member41and emerges from a lower side, facing the ground, opposite the upper side on which the rotor pulley64is arranged. The brake disc92is secured to the rotation shaft element45under the bottom linking member41.

The brake actuator91is arranged and configured to act, during braking, by adherence on the brake disc92via the brake linings93.