FR3011991A1 - DIRECT DRIVING WIND GENERATOR, WIND TURBINE COMPRISING THE GENERATOR AND METHOD OF MOUNTING WIND TURBINE - Google Patents

Abstract

The subject of the present invention is a generator for a direct drive wind turbine. The stator (4) of the wind turbine comprises a plurality of stator magnetic elements (10) (4) fixed on a first support assembly of the magnetic elements ( 10) and a first structure formed of spokes, the first structure being able to fix the first set to the fixed frame (1) of the wind turbine. The rotor (5) comprises: a plurality of rotor magnetic elements (10) (5) fixed on a second support assembly of the magnetic elements (10), the second assembly having a generally circular shape and a second radiation-formed structure the second structure being adapted to fix the first assembly to the hub, the first structure comprising a plurality of oblique spoke pairs (6), each pair of oblique spokes (6) having the shape of a capital lambda, the first set being attached to the top of each uppermost lambda at a fixing point (8) located closest to a magnetic element, the end of the oblique spokes (6) opposite the vertex being adapted to be fixed to the fixed frame (1) of the 'wind turbine. The invention also relates to the wind turbine comprising the generator and a method of mounting the wind turbine.

Description

FIELD OF THE INVENTION The present invention relates to the field of wind turbines and more particularly to direct drive wind turbines. BACKGROUND OF THE INVENTION A wind turbine is composed, inter alia, of blades fixed to a hub to form a propeller, of a generator producing electric current when the blades rotate under the driving force of the wind and a mast at the top of which are placed the propeller and the generator. Electric generators used in wind turbines may be indirect drive or direct drive. The Indirect Generator operates with a speed multiplier that is installed between the turbine propeller shaft and the electric generator shaft that drives a rotor. Thus, the engine torque produced by the wind turbine propeller indirectly transmits its rotation caused by the wind to the generator via the multiplier. The direct drive generator operates without a multiplier. The rotor of the generator is thus driven directly to the same speed of rotation as the propeller of the wind turbine. Thanks to the direct drive, this type of generator is appreciated by the fact that they do not need a gear multiplier gear that is deemed complex and fragile. On the other hand, the rotation speeds are low. To overcome these low speeds of rotation, these generators have large diameters. For example, the diameter of a generator can reach 7 m for a power output of 6 MW. The structure that carries the electromagnetic components of the generator must be made accurately to ensure that the operating spacing between the stator, which is the fixed part of the generator, and the rotor, which is the rotating part of the generator, be sufficiently constant. This spacing may be of the order of 6 mm. In addition, the structure must withstand, without deforming or breaking, internal forces such as radial and tangential electromagnetic force and external forces such as inclination, acceleration of gravity, inertial forces generated by the movements of the wind turbine. Direct drive generators are heavy, difficult to machine and transport in size and therefore expensive. For example, the stator of a currently marketed 6 MW generator contains a set of fixed electromagnets whose total mass is of the order of 30 t.

Some generators use for the rotor a set of electromagnets whose total mass is also 30 t. Other generators use magnets for the rotor fixed on a magnetizable metal support whose total mass is of the order of 10 t. Most often, the rotor is located inside the stator. The mass of the generator structure is often between 1.5 and 3 times the mass of the electromagnetic components. The structure is generally made of welded steel sheets. Some generators currently marketed have a stator divisible into sectors to facilitate their manufacture and transport. Some others contain a bearing that positions the rotor relative to the stator. WO 02/099950 A1 teaches an electric generator including a rotor having a light and rigid structure. The rotor includes a central hub and a concentric ring. Rays extend between the hub and the ring while being held in tension to hold the ring in compression like a bicycle wheel. A plurality of magnetic elements is arranged regularly on the ring. The spokes may be arranged radially or obliquely in the plane of rotation or may form an angle with the plane of rotation. The rotor ring may be formed of assembled arc sections. The stator of the generator may have the same structure including a ring and radial or oblique rays which can hold the ring cantilevered. The structure taught by this document, where the spokes are held in tension, allows the generator to resist external forces but is not adapted to the internal forces caused by the electromagnetic forces produced by the magnetic elements. GENERAL DESCRIPTION OF THE INVENTION The subject of the present invention is a light wind turbine generator which makes it possible to resist external forces, such as gusts, and internal forces, such as electromagnetic forces. To this end, the invention relates to a generator of a direct drive wind turbine, the wind turbine comprising a fixed frame and a rotating part relative to the frame and driven by the wind energy comprising a hub and blades, the generator comprising at least one stator and a rotor, the generator being characterized in that the stator comprises: - a plurality of magnetic stator elements fixed on a first support assembly of the magnetic elements, the first assembly having a generally circular shape, a first structure formed of spokes, the first structure being able to fix the first assembly to the fixed frame of the wind turbine, the rotor comprising: a plurality of magnetic rotor elements fixed on a second support assembly of the magnetic elements , the second set having a generally circular shape, - a second structure formed of spokes, the second structure being ap to attach the first set to the hub, the first structure comprising a plurality of oblique spoke pairs, each pair of oblique rays having the shape of a uppercase lambda, the first set being attached to the top of each uppercase lambda at a point fastening located closest to a magnetic element, the end of the oblique rays opposite the apex being adapted to be fixed to the fixed frame of the wind turbine.

According to another feature, the points of attachment of the peaks of circumflex accents of the first structure are included in a first plane perpendicular to the axis of rotation of the rotating part. According to another feature, the two oblique rays of the uppercase lambda extend symmetrically from the apex, each forming an angle with respect to the first plane so that the oblique rays of a capital lambda can intersect with the oblique rays of at least one other capital lambda of the first structure. According to another feature, the first structure further comprises a plurality of stiffeners having two ends, a first end of the stiffener fixing the first set to the point of attachment of each lambda top capital, the second end of the stiffener being adapted to be fixed to frame of the wind turbine so that the segment between the first end and the second end forms an angle with the first plane to form a triangulated structure between the set of stiffeners and the set of oblique rays of the first structure. According to another feature, the second structure comprises a plurality of pairs of oblique rays, each pair of oblique rays having the shape of a capital lambda, the second set being fixed at the top of each uppercase lambda at a point of attachment located at most near a magnetic element, the end of the oblique rays opposite the top being adapted to be fixed to the hub. According to another feature, the points of attachment of the vertices of the circumflex accents of the second structure are included in a second plane perpendicular to the axis of rotation of the rotating part, the second plane being distinct from the first plane. According to another feature, the two oblique rays of the uppermost lambda extend symmetrically from the apex, each forming an angle with respect to the second plane so that the oblique rays (6) of a capital lambda can intersect one another. with the oblique rays of at least one other capital lambda of the second structure. According to another feature, the second structure further comprises a plurality of stiffeners having two ends, a first end of the stiffener fixing the second set to the point of attachment of each top of the uppercase lambda, the second end of the stiffener being adapted to be fixed to the hub of the wind turbine so that the segment between the first end and the second end forms an angle with the second plane to form a triangulated structure between the set of stiffeners of the second structure and all the spokes obliques of the second structure. According to another feature, the angle formed by each pair of radius forming a capital lambda has a value between 25 ° and 70 °. In another feature, the first assembly is cantilevered to the first structure, the first assembly concentrically surrounding the second assembly. According to another feature, the second set is fixed cantilever on the second structure, the second set concentrically surrounding the first set. According to another particularity, the first set and the second set are each a set of bars parallel to the axis of rotation of the rotating part on which is fixed at least one magnetic element, a bar being fixed to a top of each lambda uppercase perpendicular to the oblique rays. According to another particularity, the first set and the second set are each a set of sectors fixed together to form a ring on which the regularly spaced magnetic elements are fixed. In another feature, the stator ring and / or the rotor ring is an annular conduit.

According to another feature, the stator ring and / or the rotor ring comprises a system providing a forced air flow in the conduit of the ring or rings. According to another feature, the oblique rays and / or the stiffeners 5 of each set are offset at the opposite to form an acute angle between them. According to another feature, the oblique rays and / or the stiffeners of each set are made of cast iron. The invention also relates to a wind turbine characterized in that it comprises at least one mast at the top of which is fixed at least one fixed frame and a rotating part on which are fixed blades, the fixed frame being fixed to the stator of the generator according to the invention, the rotating part being fixed to the rotor of the generator according to the invention. The invention also relates to a method of mounting a wind turbine 15 according to the invention comprising a generator according to the invention, with a first structure formed of spokes, the first structure being able to fix the first assembly to the fixed frame of the wind turbine and a second structure formed of spokes, the second structure being able to fix the first assembly to the hub, characterized in that it comprises the following steps: fixing the first structure to the stator and to the fixed frame of the wind turbine - fixing the second structure to the rotor and the hub of the rotating part of the wind turbine, - fixing the blades of the wind turbine to the rotating part of the wind turbine 25 - raising the mast to the place of use of the wind turbine 'wind turbine. According to another feature, the fixing of the first structure to the stator and to the fixed frame of the wind turbine and the attachment of the second structure to the rotor and to the hub of the rotating part of the wind turbine, the mounting of the rotor ring are preceded by the assembly of sectors forming the rotor ring and the stator ring. According to another feature, the fixing of the first structure to the stator and to the fixed frame of the wind turbine and the attachment of the second structure to the rotor and to the hub of the rotating part of the wind turbine, the mounting of the rotor ring are preceded by a step of assembling each rotor sector to a stator sector so that their gap surfaces coincide and a step of insertion of spacers in the air gap, the fixing steps of the first and second structures being followed by a step of subtracting the spacers. The invention, with its features and advantages, will emerge more clearly on reading the description given with reference to the accompanying drawings, in which: FIG. 1 represents a cross-section of a wind turbine generator according to the second embodiment. Figure 2 shows the second structure according to the second embodiment. Figure 3 shows the first structure according to the second embodiment.

Figure 4 shows a cross section of a wind turbine generator according to the first embodiment. FIG. 5 shows a perspective view of a detail of the first structure or the second attachment structure of the oblique rays and a stiffener according to one embodiment.

Figure 6 shows an exploded perspective view of the first structure according to the first embodiment. Fig. 7 shows an exploded perspective view of the second structure according to the first embodiment.

Figure 8 shows a detail of the cross section of Figure 4. DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION The following description will refer to the figures cited above.

The invention relates to a generator for a direct drive wind turbine. The wind turbine may comprise a fixed frame (1) and a rotating part (3) with respect to the frame (1) and driven by the wind energy comprising a hub and blades (4).

Figure 1 shows the upper part of the wind turbine according to one embodiment. This figure 1 shows the base of a blade (2) of the propeller, the generator, the fixed frame (1) which connects the mast of the wind turbine to the part of the wind turbine comprising the generator and the generator. 'propeller. The generator comprises at least one stator (4) and one rotor (5). The stator (4) comprises a plurality of stator magnetic elements (10) (4) fixed to a first support assembly of the magnetic elements (10). The magnetic elements (10) are regularly distributed over the first support assembly. The stator (4) also comprises a first structure formed of spokes. This first structure is able to fix the first set to the fixed frame (1) of the wind turbine. The rotor (5) also comprises a plurality of rotor magnetic elements (5) (5) fixed to a second support assembly of the magnetic elements (10). The magnetic elements (10) are regularly distributed over the second set. The rotor (5) comprises a second structure formed of oblique rays (6). This structure is suitable for fixing the first assembly to the hub of the wind turbine.

For the stator (4) and / or the rotor (5), the magnetic elements (10) may be, for example, electromagnets, permanent magnets or any other magnetic element adapted to the operation of the generator. These magnetic elements (10) can be fixed by a fixing means which may be glue, at least one screw or any other suitable fastening means. The first structure comprises a plurality of oblique ray pairs (6). Each pair of oblique spokes (6) has the shape of a capital lambda of angle a.

The top of the uppercase lambda formed by each pair of oblique rays (6) makes it possible to fix the first set. The top of each uppermost lambda is attached to a point (8) of attachment to the first set so that the distance between the point (8) of fixing the top of the uppercase lambda and the place where an element is fixed ( 10) magnetic is the smallest.

The points of attachment of the peaks of the circumflex accents of the first structure are included in a first plane (13) perpendicular to the axis of rotation of the rotating part (3) of the wind turbine. The two free ends of each pair of oblique spokes (6), opposite to the top, are adapted to be fixed to the fixed frame (1) of the wind turbine.

Each pair of oblique rays (6) may be attached to the first set such that the two oblique rays (6) of the uppermost lambda extend symmetrically from the apex each at an angle to an axis of symmetry which on the one hand, extends a diameter of the first set of generally circular shape and, on the other hand, passes through the point (8) for fixing the top of the uppercase lambda. The two oblique radii (6) of the uppermost lambda of the first structure may also extend symmetrically from the vertex, each forming an angle b with respect to the first plane (13) so that the oblique rays (6) of a capital lambda can cross without touching with the oblique rays (6) of at least one other capital lambda of the first structure. Without limitation, the angle b can have a value between 0 ° and 10 °, preferably 5 °. The first structure may further comprise a plurality of stiffeners (7) having two ends. A first end of the stiffener (7) is attached to the first assembly at the point (8) for fixing a top of the uppercase lambda. The second end of the stiffener (7) is adapted to be fixed to the fixed frame (1) of the wind turbine so that the segment between the first end and the second end forms an angle p with the first plane (13). The stiffener (7) thus fixed makes it possible to form a triangulated structure between the set of stiffeners (7) and the set of oblique rays (6) of the first structure. In the same way, the second structure may comprise a plurality of oblique ray pairs (6). Each pair of oblique spokes (6) has the shape of a capital lambda of angle a '. The top of the uppermost lambda formed by each pair of oblique rays (6) makes it possible to fix the second set. The top of each uppercase lambda is attached to a point (8) of attachment to the second set so that the distance between the point (8) of fixing the top of the uppercase lambda and the place where a magnetic element is fixed. the smallest. The attachment points of the circumflex accents of the second structure are included in a second plane (14) perpendicular to the axis of rotation of the rotating part (3) of the wind turbine.

The two free ends of each pair of oblique spokes (6), opposite the top, are adapted to be fixed to the hub of the wind turbine. Each pair of oblique rays (6) can be attached to the second set so that the two oblique rays (6) of the uppermost lambda extend symmetrically with respect to an axis of symmetry 30 which, on the one hand, extends a diameter of the second set of generally circular shape and, secondly, passes through the point (8) for fixing the top of the lambda uppercase. The two oblique radii (6) of the upper lambda of the second structure may also extend symmetrically from the vertex, each forming an angle θ 'with respect to the second plane (14) so that the oblique rays (6) a capital lambda can intersect with the oblique rays (6) of at least one other capital lambda of the second structure. Without limitation, the angle δ 'can have a value between 0 ° and 10 °, preferably 5 °.

The second structure may further comprise a plurality of stiffeners (7) having two ends. A first end of the stiffener (7) is attached to the second set at the point (8) for attaching a capital lambda top. The second end of the stiffener (7) is adapted to be fixed to the hub of the wind turbine so that the segment between the first end and the second end forms an angle 3 'with the second plane (14). The stiffener (7) thus fixed makes it possible to form a triangulated structure between all the stiffeners (7) and all the oblique rays (6) of the second structure. In a nonlimiting manner, the angle α or α 'formed by each pair of spokes forming a capital lambda has a value of between 25 ° and 70 °, preferably a value of 40 °. Without limitation, the angle p formed between a stiffener (7) and the first plane (13) or the second plane (14) has a value between 15 ° and 30 °, preferably a value of 25 °. The oblique spokes (6) and / or the stiffeners (7) of each structure are offset at the opposite end to form an acute angle between them. The oblique rays (6) and / or the stiffeners (7) of each structure are, for example, cast iron. The oblique character of the stator spokes (4) and the position of the fastener 30 on the fixed frame (1) of the wind turbine are chosen so that the stator (4) keeps its circular shape despite the elastic deformations generated by gravity. The oblique character of the stator spokes (4) and the position of the fastening also make it possible to effectively withstand the resisting torque of the electromagnetic forces.

The stiffeners (7) of the stator (4) counteract the tilting moment caused by the mass of electromagnets acting on the distance between them oblique rays (6). These stiffeners (7) also resist the axial forces generated by the inclination of the axis of rotation and the axial accelerations.

All the components of the first structure are arranged so that, under the effect of internal and external forces, the bending stresses are minimized. In particular, the oblique spokes (6) and the stiffeners (7) are formed of bars stressed in tension and in compression. The advantages described above concerning the oblique character of the spokes as well as about the stiffeners (7) can be taken over for the rotor (5). According to a first embodiment of the generator shown in Figure 4, the first assembly is fixed cantilever on the first structure. In this embodiment, the first set concentrically surrounds the second set. In a second embodiment of the generator shown in Figure 1, the second assembly is fixed cantilevered on the second structure. In this embodiment, the second set concentrically surrounds the first set. The first set and the second set may have several configurations. The first set and the second set have a generally circular shape.

According to a first configuration, the first set and the second set are each a set of arc sectors fixed together to form each a ring on which are fixed the magnetic elements (10) regularly spaced.

The stator ring (4) and / or the rotor ring (5) may have, for example, an annular hollow shape such as an annular duct of rectangular section. The arc sectors may be made of welded steel to form a portion of the annular conduit. The arc sectors can be interconnected by bolted connections.

Since the ring or rings are hollow, they may advantageously be used as conduit (s) for a forced air flow that may be necessary for the cooling of the magnetic elements (10) such as the electromagnets. A system providing forced airflow into the duct of the ring (s). Arc sectors can be bolted together. Stagger plates may be interposed between two arc sectors to compensate for geometrical deviations in manufacture. The usual geometrical differences observed in the manufacture of the components of the generator make it possible to assemble on the fixed frame (1) an assembly comprising, for example, an arc sector on which four oblique rays (6) and two stiffeners have been fixed. (7). This assembly can be made by bolting. The geometric differences are compensated by the elasticity of the generator components. It is possible to insert a wedging plate between the oblique spokes (6) and the fixed frame (1) or the sector.

Figures 1 and 4 each represent a section of the generatrix of the wind turbine according to the second embodiment and the first embodiment, respectively. These cuts show the structure of the generator with its main components including a bearing bearing two bearings fixed on the fixed frame (1) and rotating guide the propeller and the rotor (5) of the generator. In a different but no less advantageous manner, the propeller can be carried by a single rolling bearing. FIG. 6 represents a perspective view of a portion of the stator (4) exploded of the wind turbine of an example according to the first configuration and according to the first embodiment. The oblique spokes (6) fix the cantilever ring at the points of attachment to the vertices of the circumflex accents. The attachment points (8) are fastening means which can be fixed integrally to the ring. The attachment points (8) are fastening means which can be integral with each section of the ring. Each attachment point (8) comprises at least three fastener surfaces (12a, 12b, 12c). Two first fixing surfaces (12a, 12b) make it possible to fix each oblique radius (6) at one end of the oblique radius (6). The first surfaces (12a, 12b) are arranged so that the two oblique rays (6) form a capital lambda at an angle a. The third surface (12c) of attachment makes it possible to fix a stiffener (7). The third surface (12c) is arranged so that the stiffener (7) forms an angle 13 with the first plane (13). Fixing points (9) on the fixed frame (1) of the wind turbine make it possible to fix the oblique spokes (6) of the first structure on the fixed frame (1).

These points (9) for attachment to the fixed frame (1) may comprise two surfaces arranged to allow to receive and fix the ends of the oblique rays (6) opposite the vertices of the circumflex accents. FIG. 7 represents a perspective view of a part of the rotor (5) exploded of the wind turbine of an example according to the first configuration and according to the first embodiment. The oblique rays (6) fix the ring at the points (8) for attachment to the vertices of the circumflex accents. The attachment points (8) are fastening means which can be fixed integrally to the ring. The attachment points (8) are fastening means which can be integral with each section of the ring. Each attachment point (8) comprises at least three fastener surfaces (12a, 12b, 12c). Two first fixing surfaces (12a, 12b) make it possible to fix each oblique radius (6) at one end of the oblique radius (6). The first surfaces (12a, 12b) are arranged so that the two oblique rays (6) form a capital lambda at an angle a '. The third fixing surface makes it possible to fix a stiffener (7). The third surface (12c) is arranged so that the stiffener (7) forms an angle 3 'with the second plane (14). Fixing points on the hub are used to fix the oblique spokes (6) of the second structure on the hub. These fixing points on the hub may comprise two surfaces arranged to allow to receive and fix the ends of the oblique rays (6) opposite the vertices of the circumflex accents. The oblique rays (6) are, for example, bars which comprise a fixing head (6a, 6b) at each end. The first fixing head (6a) is fixed on one of the two first fixing surfaces (12a, 12b) of the fixing point (8). The second fixing head (6b) is fixed on a fastening surface on the hub or an attachment surface (9) on the fixed frame (1) for, respectively, the rotor (5) or the stator (4).

The stiffeners (7) are bars which comprise a fixing head (7a, 7b) at each end. The first fixing head (7a) is fixed on the third fixing surface (12c) of the fixing point (8). The second fixing head (7b) is fixed on a mounting surface on the hub or a surface (11) for fixing on the fixed frame (1) for, respectively, the rotor (5) or the stator (4). The oblique spokes (6) and / or the stiffeners (7) are bolted to the fastening surfaces at their fastening heads.

According to a second configuration not shown, the first set and the second set are each a set of bars parallel to the axis of rotation of the rotating part (3) on which is fixed at least one magnetic element. Each bar is attached to a top of each uppercase lambda perpendicular to the oblique rays (6). The invention also relates to a wind turbine. The wind turbine comprises at least one mast at the top of which are fixed at least one fixed frame (1) and a rotating part (3) on which are fixed blades. The fixed frame (1) is fixed to the stator (4) of the generator. The rotating part (3) is fixed to the rotor (5) of the generator. The invention also relates to a method of mounting a wind turbine comprising a generator. The method comprises the following steps: - fixing the first structure to the stator (4) and to the fixed frame (1) of the wind turbine, - fixing the second structure to the rotor (5) and to the hub of the rotating part (3 ) of the wind turbine, - attachment of the blades of the wind turbine to the rotating part (3) of the wind turbine - elevation of the mast at the place of use of the wind turbine.

According to the first configuration, the fixing of the first structure to the stator (4) and to the fixed frame (1) of the wind turbine and the attachment of the second structure to the rotor (5) and to the hub of the rotating part (3) of the wind turbine mounting of the rotor ring (5) is preceded by the assembly of the arc sectors forming the rotor ring (5) and the stator ring (4).

For example, in the case where a part of the magnetic elements are magnets, the rotor and the stator which can be divided into sectors of the same angular extent, a rotor sector is assembled on a stator sector by forming a pair of so that their gap surfaces coincide. The magnetic force of the magnets strongly draws the sectors toward each other. To prevent them from coming into contact, for example, spacers of a few millimeters are placed in the air gap. Each sector pair is then mounted on the first structure and then on the second structure or vice versa. The spacers are then removed before the blade attachment step.

It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration, but may be modified within the scope defined by the scope of the appended claims, and the invention should not be limited to the details given above.

Claims (21)

REVENDICATIONS1. Generator of a direct drive wind turbine, the wind turbine comprising a fixed frame (1) and a rotating part (3) with respect to the fixed frame (1) and driven by the wind energy comprising a hub and blades, the generator comprising at least one stator (4) and a rotor (5), the generator being characterized in that the stator (4) comprises: - a plurality of magnetic elements (10) of stator (4) fixed on a first set for supporting the magnetic elements (10), the first assembly having a generally circular shape, - a first structure formed of spokes, the first structure being able to fix the first assembly to the fixed frame (1) of the wind turbine, the rotor ( 5) comprising: - a plurality of magnetic rotor elements (10) (5) fixed on a second support assembly of the magnetic elements (10), the second assembly having a generally circular shape, - a second structure formed of spokes, the second structure being adapted to fix the second assembly to the hub, the first structure comprising a plurality of pairs of oblique spokes (6), each pair of oblique spokes (6) having the shape of a capital lambda, the first set being fixed at the top from each uppermost lambda to a fixing point 2s (8) located closest to a magnetic element, the end of the oblique spokes (6) opposite the vertex being adapted to be fixed to the fixed frame (1) of the wind turbine . 2. Generator according to claim 1, characterized in that the points (8) for fixing the vertices of the lambdas uppercase of the first structure 301-1991 19 are included in a first plane (13) perpendicular to the axis of rotation of the rotating part (3). 3. Generator according to claims 1 and 2, characterized in that the two oblique rays (6) of the uppermost lambda extend symmetrically from the vertex each forming an angle δ relative to the first plane (13) so that that the oblique rays (6) of a capital lambda can intersect with the oblique rays (6) of at least one other capital lambda of the first structure. 4. Generator according to at least one of claims 1 to 3, characterized in that the first structure further comprises a plurality of stiffeners (7) having two ends, a first end of the stiffener (7) securing the first set to the fixing point of each capital lambda top, the second end of the stiffener (7) being adapted to be fixed to the frame of the wind turbine so that the segment between the first end and the second end forms an angle with the foreground (13) to form a triangulated structure between the set of stiffeners (7) and the set of oblique rays (6) of the first structure. 5. Generator according to claim 1, characterized in that the second structure comprises a plurality of pairs of oblique spokes (6), each pair of oblique spokes (6) having the shape of a capital lambda, the second set being fixed at the top of each uppermost lambda at an attachment point located closest to a magnetic element, the end of the oblique spokes (6) opposite the vertex being adapted to be fixed to the hub. 6. Generator according to claim 5, characterized in that the attachment points of the uppermost lambdas of the second structure are included in a second plane (14) perpendicular to the axis of rotation of the rotating part (3), the second plane (14) being distinct from the first plane (13). 7. Generator according to claims 5 and 6, characterized in that the two oblique rays (6) of the uppermost lambda extend symmetrically from the top, each forming an angle relative to the second plane (14) so that the oblique rays (6) of a capital lambda can intersect with the oblique rays (6) of at least one other capital lambda of the second structure. 8. Generator according to at least one of claims 5 to 7, characterized in that the second structure further comprises a plurality of stiffeners (7) having two ends, a first end of the stiffener (7) fixing the second set to the point fixing each lambda top cap, the second end of the stiffener (7) being adapted to be fixed to the hub of the wind turbine so that the segment between the first end and the second end forms an angle with the second plane (14) for forming a triangulated structure between all the stiffeners (7) of the second structure and the set of oblique rays (6) of the second structure. 15 9. Generator according to at least one of claims 1 or 5, characterized in that the angle formed by each pair of radius forming a capital lambda has a value between 25 ° and 70 °. 10. Generator according to claim 1, characterized in that the first set is fixed cantilever on the first structure, the first set concentrically surrounding the second set. 11. Generator according to claim 1, characterized in that the second set is fixed cantilever on the second structure, the second set concentrically surrounding the first set. 12. Generator according to at least one of claims 1 or 5, characterized in that the first set and the second set are each a set of bars parallel to the axis of rotation of the rotating part (3) on which is fixed at least one magnetic element, a bar being fixed to a top of each uppermost lambda perpendicular to the oblique rays (6). 13. Generator according to claim 1, characterized in that the first set and the second set are each a set of sectors fixed together to form a ring on which are fixed the magnetic elements (10) regularly spaced. s Generator according to Claim 13, characterized in that the stator ring (4) and / or the rotor ring (5) is an annular duct. Generator according to at least one of claims 13 and 14, characterized in that the stator ring (4) and / or the rotor ring (5) comprises a system providing a forced air flow in the leads the ring (s). 16. Generator according to at least one of claims 1 to 9, characterized in that the oblique rays and / or the stiffeners of each structure are offset to the opposite to form an acute angle between them. 17. Generator according to at least one of claims 1 to 9, characterized in that the oblique rays (6) and / or the stiffeners (7) of each structure are made of cast iron. 18. A wind turbine characterized in that it comprises at least one mast at the top of which is fixed at least one fixed frame (1) and a rotating part (3) on which are fixed blades, the fixed frame (1) being fixed to stator (4) of the generator according to claim 1, the rotating part (3) being fixed to the rotor (5) of the generator according to claim 1. 19. A method of mounting a wind turbine according to claim 18 comprising a generator with a first structure formed of spokes, the first structure being able to fix a first set to the fixed frame of the wind turbine and a second structure formed of spokes, the second structure being able to fix a second assembly to the hub, characterized in that it comprises the following steps: - fixing of the first structure to the stator (4) and to the fixed frame (1) of the wind turbine, - fixing of the second rotor structure (5) and the hub of the rotating part (3) of the wind turbine, - fixing the blades of the wind turbine to the rotating part (3) of the wind turbine - elevation of the mast at the location of the wind turbine use of the wind turbine. 20. The method of claim 19, characterized in that the fixing of the first structure to the stator (4) and to the fixed frame (1) of the wind turbine and the attachment of the second structure to the rotor (5) and the hub of the rotating part (3) of the wind turbine assembly of the rotor ring (5) is preceded by the assembly of sectors forming the rotor ring (5) and the stator ring (4). 21. Method according to at least one of claims 19 and 20, characterized in that the fixing of the first structure to the stator (4) and the fixed frame (1) of the wind turbine and the attachment of the second structure to the rotor (5). ) and at the hub of the rotating part (3) of the wind turbine the assembly of the rotor ring (5) is preceded by a step of assembling each rotor sector to a stator sector so that their gap surfaces coincide and a step of insertion of spacers in the air gap, the fixing steps of the first and the second structure being followed by a step of subtracting the spacers.