PROCESS FOR MANEUVERING A WINDBREAD BLADE

专利摘要:
To maneuver a wind turbine blade between the ground and an electric generator rotor installed on a nacelle (15) at the top of a tower (10), the blade (25) is held in a support (40) mounted on a trolley (30) disposed against the tower. The carriage is moved and guided along the tower using at least one inclined cable (32, 33) so as to exert on the carriage a force having a horizontal component in the direction of the tower.
公开号:FR3052816A1
申请号:FR1655613
申请日:2016-06-16
公开日:2017-12-22
发明作者:Nicolas Fabry；Benoit Melen；Jean-Daniel Lebon
申请人:Soletanche Freyssinet SA；
IPC主号:

专利说明:

PROCESS FOR MANEUVERING A WINDMILL BLADE
The present invention relates to the installation of pale wind turbines, as well as their removal.
BACKGROUND
To install or uninstall the blades of wind, it is most often used cranes with high capacity, able to lift heavy loads to the top of the tower, for example the same cranes used to equip the nacelle. The availability of these cranes to assemble the wind turbines is however problematic because their location is very expensive while the weather conditions to intervene on the blades are not insured.
If the wind turbine blades are bulky, with a length of more than 50 m for large wind turbines, their weight is not so important, for example 10 to 15 tons. The use of large cranes is not necessary, even if it is the most commonly used.
[0004] Alternatively, it has been proposed in US Pat. No. 7,785,073 to assemble or dismount a wind turbine blade by using at least one cable stretched between the ground and a part mounted on the nacelle, for example. example the rotor hub of the generator, and moving the blade along this cable. However, the blade remains quite sensitive to wind or other disturbances as it moves along the cable, although the response is usually in favorable weather conditions. In case of unexpected wind, the safety requires a reorientation of the nacelle before intervening on the second or third blade, but the cable system complicates operations. In addition, this solution does not facilitate the docking of the blade on the hub, which remains a delicate operation.
An object of the present invention is to provide a more convenient technique for raising or lowering wind turbine blades without resorting to high-rise cranes.
ABSTRACT
It is proposed a method for maneuvering a wind turbine blade between the ground and an electric generator rotor installed on a nacelle at the top of a tower. The method comprises: holding the blade in a blade holder mounted on a carriage disposed against the tower; and moving and guiding the carriage along the tower, using at least one inclined cable so as to exert on the carriage a force having a horizontal component in the direction of the tower.
The carriage supporting the blade is supported on the tower during its ascent (or descent) to (or since) the upper position for connecting (or disconnect) the blade to the rotor.
This support, which stabilizes the blade during its movement, is secured by the horizontal component of the force exerted on the carriage by at least one cable which (i) ensures its guidance and / or (ii) exerts traction for hoist or stop the descent.
Once reached high position, the carriage is still held firmly against the tower by the cable or cables, which facilitates the connection of the blade to the rotor of the generator. It is possible to rotate the platform and / or rotate the rotor and / or adjust the height of the carriage and / or move the blade support relative to the carriage to present the blade connection interface in good conditions to ensure assembly.
The installation or removal of the wind turbine blades, which do not necessarily require a high-rise crane, are greatly simplified. The time of the intervention as well as its cost are therefore minimized.
In one embodiment, the guidance of the carriage along the tower is operated independently of the nacelle which is mounted sufficiently high at the top of the tower so as to pivot about a vertical axis.
To ensure the guidance of the carriage, two cables may be arranged symmetrically on either side of a vertical plane. Each of these guide cables may be connected to a point located at the foot of the tower and at a point located in the upper part of the tower and be deflected on an angular return element provided on the carriage. The connection points of the two guide cables are advantageously arranged so that the guide cables exert on the angular return elements of the carriage a force having a horizontal component in the direction of the tower. The connection points of the two guide cables in the upper part of the tower can in particular be arranged under the nacelle. An adjustment of their voltage and possibly used to make the carriage guidance function even more reliable.
In one embodiment, at least one traction cable is connected to the carriage for driving the carriage during its ascent along the tower, or for retaining the carriage during its descent along the tower, the traction cable. being inclined so that the traction it exerts on the carriage has a horizontal component in the direction of the tower. The carriage may include at least one deflection pulley for hauling the towing cable, thereby limiting the pulling force required to move the carriage and the blade. The traction cable can be deflected by at least one pulley located in the upper part of the tower and connected to a winch or brake located at the foot of the tower.
In one embodiment, the blade support is pivotally mounted on the carriage, about a substantially horizontal axis. To orient the blade naturally during its movement, the support should hold the blade in a region situated between its proximal end, that is to say the end to be connected to the electric generator rotor, and its center of gravity. to facilitate the maneuver, it is preferable that the region where the blade support holds the blade is closer to the center of gravity than its proximal end.
In one implementation of the method, the blade is brought to the foot of the tower in a horizontal position where it is gripped in the blade holder mounted on the carriage. The carriage is then moved upwardly by supporting a distal portion of the blade until the carriage has reached a height where the blade extends vertically with its distal end downward, and then the displacement is continued to the top of the carriage until the proximal end of the blade reaches the electric generator rotor.
The blade support may comprise a clamp having a shaped gasket adapted to the outer profile of the blade.
To assemble the blade to the electric generator rotor, the latter is positioned to have a hub location facing the proximal end of the blade. In one embodiment of the method, the carriage that has reached the top of its path along the tower is controlled to adjust the position of the proximal end of the blade relative to the hub location. Advantageously, the carriage is arranged to provide an adjustment of the position of the proximal end of the blade according to at least one degree of freedom among: translation in a radial direction relative to the tower, rotation about a horizontal axis perpendicular to a radial plane relative to the tower, rotation about a longitudinal axis of the blade.
To enhance safety during maneuvering of the blade, it is possible to add to the truck a blocking system thereof relative to the tower, activatable by an operator. This locking system comprises for example a strap or the like, connected to the carriage and forming a loop around the tower, the carriage being equipped with an actuator for tensioning the strap in response to a command provided by the operator.
BRIEF DESCRIPTION OF THE DRAWINGS
Other features and advantages of the present invention will appear in the following description of a nonlimiting exemplary embodiment, with reference to the accompanying drawings, in which: - Figure 1 is a diagram in side view of a wind turbine with a blade moving along the tower in direction II shown in Figure 2; - Figure 2 is a diagram in front view of the wind turbine, in the direction II-II shown in Figure 1; FIG. 3A is a diagram in section, along a horizontal plane (A-A in FIG. 3B), of a carriage holding a blade to accompany its movement along the tower of a wind turbine; - Figure 3B is a sectional diagram of the same carriage, in a radial plane (B-B in Figure 3 A); FIG. 3C shows a detail of the carriage, in the direction C indicated in FIG. 3A; and FIGS. 4A-C are simplified diagrams of a wind turbine, illustrating an example of loading operation of the blade on the carriage and the beginning of its ascent along the tower.
DESCRIPTION OF EMBODIMENTS
Figures 1 and 2 show schematically a wind turbine having a tower 10 surmounted by a nacelle 15. To facilitate reading of these two figures, the horizontal dimensions of the wind turbine tower are exaggerated in relation to its vertical dimension . In practice, the vertical dimension of the tower, for example of the order of 150 m, is more than 10 times greater than its horizontal dimensions.
The tower 10 stands from a foundation 11 built in the ground. Typically, the tower 10 is made by assembling prefabricated concrete elements, over all or part of its height. The concrete elements are prestressed by vertical cables (not shown) to ensure a good resistance of the tower 10 to the bending forces that the wind will cause it.
The top of the tower 10 is equipped to accommodate the nacelle 15 which has a mount for pivoting around the vertical axis Z of the tower. The nacelle 15 is provided to receive the electric generator 20 of the wind turbine, whose rotor has a hub 21 for receiving three blades 25 oriented at 120 ° with respect to X axis of the rotor. Only one blade is shown in the drawings. Each blade 25 at a proximal end 26, having a connection interface to the hub 21 of the rotor, and a distal end 27.
To maneuver the blade between the ground and its docking position on the hub 21, the method implements a carriage 30 which moves along the tower 10 and a guide and traction system using one or more cables. In the examples shown in FIGS. 1 and 2, this system comprises two guide cables 32 and a traction cable 33.
The carriage 30 moves on the wall 12 of the tower 10 in a vertical plane P parallel to the view of Figure 1. The vertical plane P is radial, that is to say it contains the Z axis of the tower 10. The carriage 30 has a frame provided with wheels 35 which are four in the example shown to ensure the rolling of the carriage in its path along the tower 10. The wheelbase 35 is typically a few meters, for example 5 to 6 m.
A blade support 40 adapted to hold the blade 25 during its displacement is mounted on the chassis of the carriage 30. The blade support 40 to a degree of freedom in rotation relative to the carriage 30, about an axis horizontal X 'substantially perpendicular to the rolling plane of the carriage 30 defined by its wheels 35.
The wheels 35 provide some guidance of the carriage 30 in its vertical path along the tower 10. However, the guide function and especially provided by the cables 32 which, in the example shown, have a symmetrical arrangement around from the radial plane P.
The guidance of the carriage 10 is operated independently of the nacelle 15, by elements located under this nacelle.
In the example in question, each of the guide cables 32 has a first anchoring point 50 in the lower part of the tower 10, close to the foundation 11, and a second anchoring point 51 at the top of the the tower 10, near the nacelle 15 but beneath it (so that the nacelle can rotate without obstacle around its axis Z). The carriage 30 comprises an angular return element 52, such as a saddle or a pulley, for each of the guide cables 32. The angular return elements 52 are mounted on both sides of the carriage 30 so that each of them cooperates with one of the guide cables 32. Each cable 32 thus extends between its two anchor points 50, 51 forming a bend at the level of the angular deflection element 52. The altitude of the elbow changes at the as the carriage 30 moves along the tower 10.
If the elasticity of the guide cables 32 is not sufficient to allow the slight variation in their length when the carriage 30 moves, it is possible to provide a tensioning mechanism to the guide cables 32. This mechanism of tensioning (not shown) comprises for example a jack that stretches each of the cables 32 by absorbing the variation in length related to the displacement of the angular return element 52. The jack is for example located in the lower part of the tower. It may be common to the two guide cables 32. Alternatively, there is a jack for each cable 32. The tension adjustment may be useful for balancing the forces exerted by the two guide cables 32 on the carriage 30 so that the guidance is more efficient.
As shown in Figure 1, the positioning of the low and high anchor points 50, 51 of a guide cable 32 is such that the wall 12 of the tower 10 on which the carriage 30 rolls is located between the angular deflection element 52 and the anchoring points 50, 51. As a result, the tension of the guide cables 32 results in a force exerted on the angular deflection element 52 and the carriage 30 which has a horizontal component in the direction of the tower 10. This horizontal component of the force contributes to keep the carriage 30 against the wall 12 of the tower 10.
On the other hand, the symmetrical arrangement of the guide cables 32 and the angular return elements 52 on either side of the radial plane P (Figure 2) ensures that the carriage 30 remains well on its predefined vertical path.
The traction cable 33 is used to hoist the carriage 30 when it comes to mount the blade 25 on the hub 21, or to curb the descent of the carriage 30 when it comes to disassemble the blade 25.
In the example shown in Figure 1, the traction cable 33 extends between an attachment point 55 on the carriage 30, a return pulley 56 located in the upper part of the tower 10 and a winch 57. located at the base of the tower 10. Alternatively, it is possible to mount the winch 57 at the top of the tower. When it comes to lowering a blade 25, the winch 57 is replaced by a brake, unless the winch 57 has a braking function.
Between the point of attachment 55 and the top of the tower (pulley 56), the traction cable 33 follows an inclined trajectory, so that the traction Ti that it exerts on the carriage 30 has a horizontal component which tends to hold the trolley 30 against the tower 10.
In Figure 1, the attachment point 55 is shown in front of the carriage 30, so that the drawing is easier to read. In practice, the point of attachment 55 can be located between the axles of the wheels 35 so that the carriage 30 is better held against the wall 12 of the tower 10.
In addition, as shown in Figure 2, the connection of the traction cable 33 on the carriage 30 does not necessarily consist of an attachment point. In the example shown in FIG. 2, the cable 33 has a halyard at the level of the carriage 30, which makes it possible to reduce the force coming from the winch 57. In the example, the carriage 30 is equipped with two return pulleys 58 located on both sides, and the pulling cable 33 passes under these two pulleys 58 to be returned to an anchor point 59 located at the top of the tower 10. Due to this arrangement, each pulley 58 receives traction cable 33 a force Ti / 2 from the winch 57, which results in a total force Ti on the carriage. This force Ti has a vertical component that raises the truck (or slows down its descent) and a horizontal component that slams the truck against the wall 12 of the tower 10.
The guiding and traction system may comprise a frame for positioning the anchoring points 51, the pulley 56 and / or the anchoring point 59 at the top of the tower 10. The frame consists of example in a pair of beams 60 fixed to the tower 10 in its upper part, under the nacelle 15. The concrete elements forming the tower 10 may, in the upper part thereof, be prefabricated so as to incorporate the beams 60 or to present an interface allowing easy their assembly and disassembly. The beams 60 are pre-equipped so that the positions of the anchor points 51, 59 and the pulley 56 are well defined to provide the guiding and pulling forces as described above.
The beams 60, as well as the cables 32, 33, the carriage 30 and the winch 57, constitute an apparatus that can be moved from one wind turbine to another when there are needs to assemble or dismount blades. 25.
It is possible to leave all or part of the equipment of the beams 60 to facilitate any maintenance operations during the life of the wind turbine.
The cables 32, 33 for guiding and pulling the carriage 30 must remain relatively close to the wall of the tower 10 so as not to hinder the rotation of the rotor provided with all or part of its blades 25.
Figure 1 illustrates, in dashed lines, an option that can be added to the carriage 30 to improve safety during maneuvers of the blade 25. According to this option, a system 80-84 blocking the carriage 30 relative to the turn 10 is provided to be put into service selectively by the operator, especially in case of deterioration of weather conditions while the blade is transported by the carriage 30.
For example, the locking system comprises one or more straps 80 arranged in a loop around the tower 10, with both ends attached to the carriage 30. The strap 80 is put in place, without being stretched, before that the carriage 30 begins its vertical movement along the tower 10, then it moves along with the carriage along the tower. To ensure that the strap 80 accompanies the vertical movements of the carriage 30 without hindering them, it can be passed or held in a guide 82 such as a hook located on the side of the tower 10 diametrically opposite the carriage 10, which guide 82 is suspended from a beam 60 at the top of the tower via a rope 83. On the beam 60, the length of the rope 83 is adjusted by a reel 84 so that the guide 82 moves vertically with a speed adapted to that of the trolley 30.
The carriage 30 is provided with an actuator 81 connected to one or both ends of the strap 80, and activatable remotely by the operator. In response to a command from the operator, the actuator 81 extends the strap 80 to encircle the tower 10 and lock the carriage 30 and the blade 25 in position.
Figures 3A and 3B show in more detail a possible arrangement of the carriage 30 shown in Figure 1. The frame 36 of the carriage 30 is equipped with wheels 35 mounted on two axles in this example. At the front of the chassis 36 is the attachment point 55 of the traction cable 33 (or one or more return pulleys if there is a hauling of the cable 33).
The blade support 40 may be in the form of a clamp having two shells provided with a profile inner lining adapted to the outer profile of the blade 25 in the region where it is held. The profile of the interior lining of the support 40 is oriented, with respect to the longitudinal axis of the blade 25, so that it is opposite its location on the hub 21 of the generator, with a suitable angular position at the connection of the blade on the hub. The lining may be flexible to better ensure that the composite material of the blade 25 is not damaged. The two shells are gathered around the blade 25 when it is gripped by the clamp 40, and held against each other, with the blade between them, by means of threaded rods 65 or other suitable assembly means .
As shown in Figures 1, 2 and 3B, the blade 25 is held in the support 40 in a region between its proximal end 26 and its center of gravity G. Thus, the distal end 27 of the blade is naturally directed downward as the carriage 30 progresses along the tower 10.
Preferably, the region where the blade 25 is held in the support 40 is much closer to the center of gravity G than to the proximal end 26. This limits the need to compensate for the angular momentum of the blade 25 around the X 'axis when the blade is lifted from the ground.
The carriage 30 shown in Figures 3A-B comprises a plate 62 mounted on the frame 36 by means of telescopic supports 63 which can be remotely controlled to adjust the orientation and the position of the plate 62 relative to the 36. In the non-limiting example shown in Figures 3A-B, there are four telescopic supports 63 near the four corners of the frame 36 which is generally rectangular. Each support 63 comprises an actuator, for example a jack, associated with a power source (not shown) on board the truck and can be controlled by means of a remote controlled by an operator controlling the maneuver from the nacelle 15.
The carriage 30 shown in Figures 3A-B further comprises a pivot bearing 64 interposed between the plate 62 and the blade holder 40 to allow the pivoting of the blade support about the axis X 'supra. The bearing 64 may optionally be motorized so that the operator can also adjust the angular position of the support 40 and the blade 25 around the axis X 'when the proximal end 26 is close to its location on the hub 21.
Figures 3A and 3C show a way of mounting on the carriage 30 the angular return elements 52 for the guide cables 32. In this example, each angular return element has the shape of a saddle 52 on which the guide cable 32 is deflected. The saddle 52 has a curved track on which the cable 32 bears. This curved track is sandwiched between two plates that let the guide cable 32 while maintaining its position in position on the track. These two plates form a unit which is articulated on the frame 36 of the carriage 30 around an axis Y parallel to the direction of movement of the carriage 30 along the tower 10. This arrangement, provided symmetrically on both sides another of the chassis 36, allows the guide cables 32 to perform their function regardless of the height of the carriage 30 along the tower 10.
When installing a blade 25, the operator can adjust the position of the proximal end 26 of the blade once the carriage 30 reached the top of its path along the tower. The position of the proximal end 26 is adjusted relative to the location provided for the blade on the hub 21 of the rotor.
For this, the operator, placed at a control station arranged on the nacelle 15 and using a suitable control interface, has the following degrees of freedom: rotation of the generator 20 around the Z axis with respect to tower 10; rotation of the hub 21 around the X axis; vertical translation of the carriage 30, upwards or downwards, by means of the winch / brake 57; rotation of the blade 25 on the carriage 30 about the axis X ', for example by means of the motorized ring gear 64; translation in the radial direction relative to the tower 10, for example by synchronized control of the telescopic supports 63; rotation about a horizontal axis perpendicular to the radial plane P, for example by differential control of the telescopic supports 63 located at the front of the carriage 30 and the telescopic supports 63 located at the rear of the carriage 30; rotation about the longitudinal axis of the blade, for example by differential control telescopic supports 63 located on the left side of the carriage 30 and telescopic supports 63 located on the right side of the carriage 30.
These adjustment operations can be performed while the blade 25 is firmly held relative to the tower 10 by the effect of the guide and traction cables 32, 33. In addition, as the blade 25 is oriented vertically Tower 10 gives him some protection from the wind.
FIGS. 4A-C are an illustration of a loading procedure for the blade 25 to be mounted along the wind turbine tower 10. Initially (FIG. 4A), the blade 25 is brought into a horizontal position at the foot of the tower 10 with the aid of one or more vehicles 70, 71. At this moment, the carriage 30 is in the low position, and the support 40 is placed on the blade 25 in the appropriate region between its center of gravity G and its proximal end 26. Once the blade 25 is gripped in the support 40, the winch 57 is actuated to initiate the ascent of the carriage 30 (FIG. 4B). In this phase, a small crane 72 can be used to support the distal portion 27 of the blade. There is no need for a very powerful crane since the blade 25 is held by the support 40 in a region close to its center of gravity.
Once the carriage 30 has reached a height or the blade 25 is oriented vertically (Figure 4C), the activation of the winch 57 and maintained for the carriage 30 to continue its ascent to the docking position of the blade on the rotor. At this point, the adjustment of the maneuver can be completed by the operator as indicated above.
The embodiments described above are a simple illustration of the present invention. Various modifications can be made without departing from the scope of the invention which emerges from the appended claims.

权利要求:
Claims (18)
[1" id="c-fr-0001]
A method of operating a wind turbine blade (25) between the ground and an electric generator rotor (20) installed on a nacelle at the top of a tower (10), the method comprising: holding the blade in a mounting bracket; blade (40) mounted on a carriage (30) disposed against the tower; and moving and guiding the carriage along the tower, using at least one cable (32, 33) inclined to exert on the carriage a force having a horizontal component in the direction of the tower.
[2" id="c-fr-0002]
2. Method according to claim 1, wherein the guide of the carriage (30) along the tower (10) is operated independently of the nacelle (15) which is mounted at the top of the tower so as to be pivotable around a vertical axis (Z).
[3" id="c-fr-0003]
3. Method according to any one of the preceding claims, wherein two guide cables (32) are arranged symmetrically on either side of a vertical plane, each guide cable being connected to a point (50) located at foot of the tower (10) and at a point (51) located in the upper part of the tower and being deflected on an angular return element (52) provided on the carriage (30).
[4" id="c-fr-0004]
4. The method of claim 3, wherein the connection points (50, 51) of the two guide cables (32) are arranged so that the guide cables exert on the angular return elements (52) of the carriage (30). ) a force having a horizontal component in the direction of the tower (10).
[5" id="c-fr-0005]
5. Method according to any one of claims 3-4, wherein the connection points (51) of the two guide cables (32) in the upper part of the tower (10) are arranged on the tower below the nacelle ( 15).
[6" id="c-fr-0006]
6. Method according to any one of claims 3-5, wherein the guide cables (32) have an adjustable voltage (T2).
[7" id="c-fr-0007]
A method according to any one of the preceding claims, wherein at least one pulling cable (33) is connected to the carriage (30) for driving the carriage as it ascends along the tower (10), or for retaining the carriage as it descends along the tower, the traction cable being inclined so that the traction (Ti) that it exerts on the carriage has a horizontal component in the direction of the tower.
[8" id="c-fr-0008]
8. The method of claim 7, wherein the carriage (30) comprises at least one return pulley (58) for performing a hauling of the traction cable (33).
[9" id="c-fr-0009]
9. A method according to any one of claims 7-8, wherein the traction cable (33) is deflected by at least one pulley (56) located in the upper part of the tower (10) and connected to a winch (57). ) or a brake located at the base of the tower.
[10" id="c-fr-0010]
10. Method according to any one of the preceding claims, wherein the blade holder (40) is pivotally mounted on the carriage, about a substantially horizontal axis (X ').
[11" id="c-fr-0011]
The method of claim 10, wherein the blade (25) has a proximal end (26) for connection to the electric generator rotor and a distal end (27) opposite the proximal end, and the support blade (40) holds the blade in a region between the proximal end and the center of gravity (G) of the blade.
[12" id="c-fr-0012]
The method of claim 11, wherein the region where the blade holder (40) holds the blade (25) is closer to the center of gravity (G) than the proximal end (26).
[13" id="c-fr-0013]
A method as claimed in any one of the preceding claims, comprising: bringing the blade (25) to the foot of the tower (10) in a horizontal position; gripping the blade in the blade holder (40) mounted on the carriage (40); starting an upward movement of the carriage by supporting a distal portion (27) of the blade until the carriage has reached a height where the blade extends vertically with its distal end downward; and continuing the upward movement of the carriage until a proximal end (26) of the blade reaches the electric generator rotor.
[14" id="c-fr-0014]
14. A method according to any one of the preceding claims, wherein the blade support (40) comprises a clamp having a shaped gasket adapted to an outer profile of the blade (25).
[15" id="c-fr-0015]
The method of any one of the preceding claims, wherein the electric generator rotor is positioned to have a hub location (21) facing a proximal end (26) of the blade (25), and wherein the carriage (30) reaching the top of its path along the tower (10) is controlled to adjust the position of the proximal end of the blade relative to the hub location.
[16" id="c-fr-0016]
The method of claim 15, wherein the carriage (30) is arranged to provide adjustment of the position of the proximal end (26) of the blade (25) in at least one degree of freedom among a translation in a radial direction relative to the tower (10), a rotation about a horizontal axis perpendicular to a radial plane with respect to the tower, and a rotation about a longitudinal axis of the blade.
[17" id="c-fr-0017]
17. A method according to any one of the preceding claims, wherein a locking system of the carriage (30) relative to the tower (10) is activatable by an operator.
[18" id="c-fr-0018]
18. The method of claim 17, wherein the locking system comprises a strap (80) connected to the carriage (30) and forming a loop around the tower (10), the carriage being equipped with an actuator (81) for tensioning the strap in response to a command provided by the operator.

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ES2364732B1|2010-02-25|2012-09-17|Gamesa Innovation & Technology, S.L.|USEFUL FOR THE HANDLING OF SHOVELS.|

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GB201121760D0|2011-12-19|2012-02-01|Lm Wind Power As|A blade cart for a wind turbine blade|

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KR101422497B1|2012-06-21|2014-07-25|삼성중공업 주식회사|Blade maintenance platform for wind turbine|

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JP2015075037A|2013-10-09|2015-04-20|三菱重工業株式会社|Wind turbine blade attaching/detaching method and device|

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US10502189B2|2015-07-16|2019-12-10|Vesta Wind Systems A/S|Methods for erecting or dismantling a multirotor wind turbine|WO2017162249A1|2016-03-22|2017-09-28|Vestas Wind Systems A/S|Wind turbine descent system|

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BR112019005389A2|2016-09-30|2019-06-11|Gurit Tooling Taicang Co Ltd|locking device and system, and, movement side of a wind turbine blade mold.|

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CN110671276B|2019-11-20|2021-01-08|江西省斯云新能源智能科技有限公司|Device for mounting a wind turbine blade|

法律状态:
2017-06-28| PLFP| Fee payment|Year of fee payment: 2 |

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2017-12-22| PLSC| Search report ready|Effective date: 20171222 |

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2018-06-22| PLFP| Fee payment|Year of fee payment: 3 |

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2019-05-22| PLFP| Fee payment|Year of fee payment: 4 |

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2020-05-20| PLFP| Fee payment|Year of fee payment: 5 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1655613A|FR3052816B1|2016-06-16|2016-06-16|PROCESS FOR MANEUVERING A WINDBREAD BLADE|

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FR1655613|2016-06-16|FR1655613A| FR3052816B1|2016-06-16|2016-06-16|PROCESS FOR MANEUVERING A WINDBREAD BLADE|

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CN201680088027.8A| CN109642547A|2016-06-16|2016-12-09|The method for handling wind turbine blade|

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US16/310,153| US20190257292A1|2016-06-16|2016-12-09|Method for handling a wind turbine blade|

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PCT/FR2016/053319| WO2017216430A1|2016-06-16|2016-12-09|Method for handling a wind turbine blade|

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BR112018076060A| BR112018076060A2|2016-06-16|2016-12-09|method for installing a wind turbine blade|

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CA3027930A| CA3027930A1|2016-06-16|2016-12-09|Method for handling a wind turbine blade|

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EP16825474.6A| EP3472457A1|2016-06-16|2016-12-09|Method for handling a wind turbine blade|

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AU2016412179A| AU2016412179A1|2016-06-16|2016-12-09|Method for handling a wind turbine blade|