method and system for transporting and storing at least two wind turbine blades of the wind turbines

专利摘要:
METHOD AND SYSTEM FOR THE TRANSPORT AND STORAGE OF AT LEAST TWO WIND TURBINES OF WIND TURBINES A transport and storage system for at least two wind turbine blades and which comprises a first wind turbine and a second wind turbine blade. wind turbine wind turbine blade is described. The wind turbine blades, each having a root end and a tip end, said system comprising a packaging system that is adapted to place the first wind turbine blade, so that the tip end of the first points of wind turbine wind turbine blade in a first direction, and placing the second wind turbine blade, so that the tip end of the second points of wind turbine wind turbine in a second direction, which is substantially opposite to first direction. The tip end of the second wind turbine blade extends beyond the root end of the first wind turbine blade, and the tip end of the first wind turbine blade extends beyond the root end of the second wind turbine blade ( ...).
公开号:BR112015008854B1
申请号:R112015008854-6
申请日:2013-10-25
公开日:2021-03-02
发明作者:Jacobus Van Der Zee；Anders Nielsen；Kenth SKIPPER-MORTENSEN
申请人:Lm Wp Patent Holding A/S；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[0001] The present invention relates to a method of transporting or storing the wind turbine blades, as well as a storage and transport system for transporting at least two wind turbine blades, including a wind turbine blade. first wind turbine and a second wind turbine blade. BACKGROUND OF THE INVENTION
[0002] Wind turbine wind turbine blades used for horizontal axis wind turbines to generate electricity from the wind can be quite large and today they can be over 70 meters long and 4 meters wide. Wind turbine blades are usually made of a fiber-reinforced polymer material and comprise an upwardly flowing shell piece and a downwind casing part. Due to the size and fragility of these large rotor blades, wind turbine blades can be damaged during transport as well as during loading and unloading. Such damage can seriously impair the performance of wind turbine blades. Therefore, wind turbine blades need to be carefully packed in order to ensure that they are not damaged.
[0003] However, due to the increasing length of modern wind turbine blades, it gradually becomes more complicated and expensive to transport the wind turbine blades. It is not uncommon for transportation costs to be equal to 20 percent of the total costs of manufacturing, transporting and assembling the wind turbine blade over the rotor of a wind turbine blade. In addition, some wind turbine blades are transported to the assembly site through different modes of transport, such as by truck, train and ship. Some of these modes of transport may have restrictions for large loads, maximum heights, maximum widths, maximum distances between transport structures or supports, for example, dictated by local regulations. Therefore, there is a logistical problem of providing transport solutions that are suitable for various types of transport.
[0004] In general, there is a demand for making transport solutions simpler, safer and cheaper. The prior art provides several solutions for transporting more than one rotor wind turbine blade through a single container or other packaging system, which is an obvious way to reduce transportation costs. However, the aforementioned restrictions and limitations can increase the difficulty of transporting a plurality of wind turbine blades that use the same packaging system.
[0005] EP1387802 discloses a method and system for transporting two straight wind turbine blades, in which the root end of a first wind turbine blade is arranged in a first packaging structure, and the tip end of a second , next to the wind turbine blade is disposed of a second packaging structure which is provided next to and connected to the first packaging structure with the effect that the wind turbine blades are compactly stored together with the other in an " end-to-root ". However, in this root end transport structure system they support the wind turbine blades at the tip of the blades, where they are mechanically more fragile. In addition, the package structures are arranged on the face of the root end and the tip of the wind turbine blade. Therefore, the distance between the package structures is approximately equal to the length of the wind turbine blades. For very long wind turbine blades of 45 meters or more, this may not be possible due to local regulations and transport restrictions.
[0006] It is therefore an objective of the invention to obtain a new method and system for storing and transporting a plurality of wind turbine blades, which overcome or ameliorate at least one of the disadvantages of the prior art or which can provide an alternative useful. SUMMARY OF THE INVENTION
[0007] Therefore, a transport system for a wind turbine blade with a root end transport structure and a tip end transport structure is provided, the structures are stackable in which the structures are arranged in such a way that a root end transport structure and at least a portion of a successive tip end transport structure will overlap with the root end diameter of a wind turbine blade supported by said end transport structure of the end root, and where the tip end transport structure is arranged in such a way that a tip end of a pre-supported folded or swept wind turbine blade will be spaced from the ground.
[0008] According to one aspect of the invention, a method is provided for the transport or storage of at least two wind turbine blades and which comprises a first wind turbine wind turbine blade and a second wind turbine blade. wind turbine, the blades of the wind turbine, each having a root end and a tip end, in which the method comprises the steps of: a) placing the first wind turbine blade, so that the tip end of the first wind turbine blade blades in a first direction, b) placing the second wind turbine blade in an adjacent wind turbine and in the immediate vicinity of the first wind turbine wind turbine blade, so that the tip end of the second wind turbine blade points of wind turbine in a second direction, which is substantially opposite to the first direction. According to a first aspect, the second wind turbine blade is in step b) arranged so that the tip end of the second wind turbine blade extends beyond the root end of the first wind turbine. The tip end of the wind turbine blade can also extend beyond the root end of the second wind turbine wind turbine blade. This will inevitably be the case, if the first wind turbine blade and the second wind turbine wind turbine blade are of the same length.
[0009] Thus, it is evident that the two blades of wind turbines are arranged substantially parallel to each other and oriented in opposite directions. Since the thickness of the wind turbine blades is typically decreasing from the root end to the tip end, the wind turbine blades can like the new "end-to-root" scheme being arranged on top of each other through images that have a relatively small combined cross section. In addition, the new configuration ensures that a tip end section of the second wind turbine blade can be supported farther from the tip end than with a common support structure assembly for the root of the first wind turbine blade and a end section of the second wind turbine blade. In this way, the tip end section can be supported in a position where the wind turbine blade is mechanically stronger than at the right at the tip end.
[0010] In addition, the new transport layout ensures that the sets of structures can be arranged longitudinally closer to each other, thus being able to comply with local regulations that may place restrictions on the maximum distance between the support structures for transportation.
[0011] According to an advantageous embodiment, the first wind turbine wind turbine blade and the second wind turbine wind turbine blade in steps a) and b) are stacked on top of each other, that is, in a way that the second wind turbine blade is arranged over the first wind turbine blade. Advantageously, the first wind turbine wind turbine blade and the second wind turbine wind turbine blade are arranged so that the rope planes of the respective ends of the ends are arranged substantially horizontally. By "substantially horizontal" is meant that the chord plane can vary up to +/- 25 degrees from the horizontal.
[0012] In a preferred embodiment, the wind turbine blades are arranged so that an upwind side (pressure or side) of the wind turbine blade is substantially downwards.
[0013] According to an alternative embodiment, the first wind turbine wind turbine blade and the second wind turbine wind turbine blade in steps a) and b) are stacked side by side. In such an embodiment, the first wind turbine wind turbine blade and the second wind turbine wind turbine blade can advantageously be arranged so that the rope planes of the respective ends of the ends are arranged substantially vertically. Thus, the blades can, for example, be arranged so that they are supported on their leading edges (which are mechanically stronger than the trailing edges) through an upwardly facing receptacle.
[0014] In a stacking system to store more than two wind turbine blades, it is also possible to stack the wind turbine blades both horizontally and vertically, that is, in a stacked set.
[0015] The method advantageously refers to the transport and storage of wind turbine blades, having a wind turbine blade length of at least 40 meters, or at least 45 meters, or even at least 50 meters. The blades of wind turbines can be so that, when mounted on a horizontal wind turbine against the wind configured in an unloaded state, they will curve forward of the rotor plane, so that the tip of the tower the clearance is increased.
[0016] The first and second wind turbine blades can be pre-folded Such pre-folds of wind turbine blades can be arranged on the tip end structures and root end structures so that they are straightened slightly or completely during transport, for example, as shown in WO05005286 by the present applicant. However, wind turbine blades do not necessarily have to be stretched. Since the wind turbine blades are supported close to the ends and the wind turbine blades are arranged with the side facing downwind, the very weight of the wind turbine blade can straighten the wind turbine blades due to gravitational forces that act on the middle part of the wind turbine blade.
[0017] According to a preferred embodiment, the root end of the first wind turbine blade is arranged in a first root end structure, the second root end of the wind turbine blade is disposed of a second wind structure. root end, the tip end of the first wind turbine blade wind turbine is arranged in a first tip end structure, and the final end of the second wind turbine wind turbine blade is arranged in a second end of the structure tip. This end of the frame tip preferably comprises a receptacle for supporting a tip end section. Thus, the first tip-end structure comprises a first tip-end receptacle, and the second tip-end structure comprises a second tip-end container. Depending on the particular solution, the container can, for example, either the side withstand the pressure of the wind turbine blade or, alternatively, the leading edge of the wind turbine blade. However, in principle, the receptacle can also support the suction side of the wind turbine blade or even the trailing edge of the blade. The structures themselves can be used as lifting tools so that two or more wind turbine blades can be lifted at once and without imposing stress on the wind turbine blades.
[0018] In a particularly advantageous embodiment, the second tip end structure is attached, optionally detachably attached, to the first root end structure, and the first tip end structure is attached, optionally detachably attached, to the second end of root structure. So, it is clear that the images can be constructed as an integral solution, comprising either a base end structure and a tip end structure (or container), or as separate structures for the root and the tip. This last solution has the advantage that the second wind turbine blade can be more easily disengaged from the first wind turbine blade, simply by detaching the tip end structures from the root end structures.
[0019] In another embodiment, the connecting parts of the root end structures and the tip end structures that connect to or attach the wind turbine blade to the structure can be articulated in relation to the structure itself. This can, for example, be achieved by the root by connecting a plate to the root of the wind turbine blade which is hingedly connected to the structure. In the same way, this can be achieved by allowing a tip end of the receptacle to be pivotally connected to the tip end structure. Such embodiments have the advantage of reducing loads, which would otherwise be introduced to both structures, or wind turbine blades, due to deviations from the wind turbine blade or the like during transport.
[0020] In another advantageous embodiment, the first root end structure and / or the second root end structure is a root end support adapted to be attached to a root end face of a shovel. wind turbine. This wind turbine provides a particularly simple solution, where the support or structure can be connected to, for example, a root end plate of the wind turbine blade and without having to support the outside of the wind turbine blade. Thus, external damage to the external surface of the wind turbine blades can be more easily avoided. The tip end structures (with containers) can be attached to the supports, so that the tip end extends beyond the support, when the wind turbine blade is inserted into the tip end of the structure (and container).
[0021] In yet another advantageous embodiment, the first root end structure and the second end of the structure tip are connected in one or T-shaped configuration, so that an L-base or L-shaped configuration. T is attached to the L-shaped root end of the wind turbine wind turbine blade first, and a part that transversely extends the L- structure (or end) or T-shaped configuration that supports a longitudinal section the tip end of the second wind turbine blade. The same also applies to the second root end structure and the first tip end structure. Advantageously, the L or T-shaped configuration is formed so that the base is a root end face support connected to the root end face of the first wind turbine blade, and the cross-extending part of the structure supports a tip end section of the second wind turbine blade.
[0022] The union of the structure is arranged so that the base of the T-L- or configuration is arranged vertically. The cross-sectional part of the structure can be arranged so that it extends from the top or the bottom of the base. In this configuration, the second wind turbine blade is arranged on top of the first wind turbine blade. The transversely extending end or part of the structure can thus support a part of the suction side or the pressure side of the wind turbine blade of an upwardly facing receptacle. Alternatively, the end may extend from the side of the base. In such a configuration, the wind turbine blades are arranged side by side, and the transversely extending end or part of the structure can support a part of the leading edge or the trailing edge of the wind turbine blade of a container that remains for up.
[0023] Whether the wind turbine blades are arranged so that both wind turbine blades are facing the main end downwards (in the side-by-side arrangement) or with the upwardly flowing shell parts facing downwards (in the vertically stacked arrangement), it is evident that the structure that extends transversely part of the two sets of structures that must be arranged inversely in relation to the base structure. Thus, the two sets of structures have slightly different configurations.
[0024] The assembly of L- or T-shaped structure has the advantage that the structure extends transversely supporting a larger part of the tip sections, thus, better relieving loads and possibly also minimizing the necessary protrusion of the part of the tip that extends beyond the root end frame.
[0025] In one embodiment, the longitudinal extent of the part of the structure that extends transversely is at least 1 meter, advantageously at least 1.5 meters, more advantageously, at least 2 meters. The longitudinal section of the tip end of the wind turbine blade can be supported along the entire section, or it can be supported in a plurality of discrete sections within the end of the L- or T-shaped frame assembly.
[0026] As an alternative for the assembly of L or T-shaped structure, the root end structure and the tip end structure can be arranged in substantially the same plane.
[0027] Advantageously, a plurality of first and second blades of wind turbine wind turbines are placed in a matrix, and in which the blades of the wind turbine comprise each defining a shoulder, maximum blade of the blade, and in which the blades of wind turbines are arranged, so that the forms of chord maxima an angle of between 20 and 75 degrees from a horizontal plane, with advantage between 22 and 73 degrees. Even more advantageously, the maximum rope forms an angle of between 15 and 35 degrees from a horizontal plane, with an advantage of between 20 and 30 degrees. It is evident that this stacking method can be advantageous for any wind turbine blade stacking configuration side by side with the root end and tip end arranged in the same direction. In a preferred embodiment, it is the root end of the wind turbine blade that is connected between 15 and 35 degrees from a horizontal plane, advantageously between 20 and 30 degrees. The angle can, for example, be defined by connecting lines between a part of the hull against the wind and a part of the hull downwind at the end of the root of the wind turbine blade. In this configuration, the wind turbine blades in a stacked set can be arranged so that they overlap slightly with the shoulder of a wind turbine blade that partially extends over an adjacent wind turbine blade, so that the side to be windward side of a wind turbine blade near the ledge faces downwards towards the side near the stern tip of an adjacent wind turbine blade. In this way, it is possible to stack the blades of wind turbines in images that have a width that corresponds to the diameter of the root, or only slightly larger, although the length of the shoulder rope exceeds that diameter.
[0028] In another embodiment, the intermediate protection members are arranged between the first wind turbine blade and the second wind turbine blade. The protective intermediate members are preferably placed in a longitudinal position between the first root end structure and the second root end structure. Advantageously, the intermediate protection members are arranged close to the tip end structures in order to provide additional support for a tip end section of the wind turbine blade. Protection means preventing the wind turbine blades from being damaged due to bending or the wind turbine blades impacting each other. The protection members are particularly advantageous intermediates when the wind turbine blades are stacked on top of each other. In such a configuration, the intermediate protection members can be used as support to support an additional tip end section of a wind turbine blade and can transfer loads from the tip end of the wind turbine blade higher than the root region mechanically stronger of the lower wind turbine blade. The additional protection members can be arranged under the lower wind turbine blade in a stacked assembly and a support or ground platform. The additional protective element is advantageously arranged to support an additional tip end section of the lower wind turbine blade, for example, close to the final tip structure of the lower wind turbine blade.
[0029] The protective intermediate members can be made of a foamed polymer.
[0030] In another embodiment, a root end face of the first wind turbine blade is arranged within 45 meters from a root end face of the second wind turbine blade, advantageously within 42 meters. In this way, root end supports or structures must also be arranged a maximum of 45 meters or 42 meters from each other.
[0031] In accordance with the first aspect, the invention also provides a transport and storage system for at least two wind turbine blades and which comprises a first wind turbine wind turbine blade and a second turbine blade wind power. The blades for wind turbines each have an end of the root and an end of the tip. The system comprises a packaging system that is adapted to place the first wind turbine blade, so that the tip end of the first wind turbine blade points in a first direction, and placing the second wind turbine blade, so that the tip end of the second wind turbine The wind turbine blade points in a second direction, which is substantially opposite to the first direction. The tip end of the second wind turbine blade extends beyond the root end of the first wind turbine blade, and the tip end of the first wind turbine blade extends beyond the root end of the second wind turbine blade. , when the first and the second wind turbine blades are arranged in the packaging system. Thus, once again, it is clear that the system is adapted for the first and the second blades of wind turbine wind turbines substantially parallel to each other and pointing towards the tip root, but with a protrusion.
[0032] According to a first embodiment, the packaging system comprises: a first root end structure for attachment to the root end of the first wind turbine blade, a first tip end structure to support a portion of tip end of the first wind turbine blade, a second root end structure for attachment to the root end of the second wind turbine wind turbine blade, and a second tip end structure to support an end portion of the wind turbine tip. second wind turbine wind turbine blade. The second tip end structure can be connected, optionally detachable, with the first root end structure, and the first tip end structure can be, optionally detachable, connected with the second root end structure. Thus, it is evident that the structures can be constructed as an integral solution, comprising either a root end structure and a tip end structure (or container), or as separate structures for the root and the tip. This latter solution has the advantage that the second wind turbine blade can more easily be disengaged from the first wind turbine blade, simply by detaching the tip end structures from the root end structures.
[0033] In an advantageous embodiment, the first root end structure and / or the second root end structure are end supports adapted to be attached to a root end face of the first wind turbine blade and the second wind turbine wind turbine blade, respectively. This provides a particularly simple solution, where the structure or support can be attached to, for example, a root end plate of the wind turbine blade and without having to support the outside of the wind turbine blade. Thus, external damage to the outer surface can be more easily avoided. The tip end structures (with containers) can be attached to the supports, so that the tip end extends beyond the support, when the wind turbine blade is inserted into the tip end of the structure (and container).
[0034] At the tip end of the first wind turbine blade, when arranged in the first tip end structure, a first longitudinal extension extends beyond the first tip end structure, and the tip end of the second turbine blade wind, when disposed on the second tip end structure, a second longitudinal extension extends beyond the first tip end structure. In other words, the first tip end structure is adapted to pack the tip end of the first wind turbine blade at a first distance from the tip, and the second tip end structure is adapted to pack the tip end of the second end blade of wind turbine tip wind turbine at a first distance from the tip. The first longitudinal extension and the second longitudinal extension can be at least 2 meters, advantageously at least 3.5 meters, and more advantageously, at least 5 meters. The tip of the wind turbine blade can even extend at least 6, 7, or 8 m beyond the end of the structure tip.
[0035] In a particularly advantageous embodiment, the storage system is adapted to stack the first and second wind turbine blades on top of each other. The second end structure can, for example, be a tip connected to an upper part of the first root end structure, and the first tip end structure is connected to a lower part of the second root end structure. In this configuration the wind turbine blades are arranged so that the rope planes of the ends of the wind turbine blades are substantially horizontal. The installation can be adapted to organize the wind turbine blades with a part of the shield against the wind substantially downwards.
[0036] In an alternative embodiment, the tip end structures are attached to the sides of the root end structures. In such a configuration the end rope planes of the tip of the paddles are arranged substantially vertically, with advantage, with a tip facing downwards.
[0037] In another embodiment, at least one first intermediate protection element is disposed between the first wind turbine blade and the second wind turbine blade. The first intermediate protective element can advantageously be provided near the tip end of an upper wind turbine blade disposed of the first wind turbine blade and the second wind turbine blade. In addition, a second intermediate protection element can be arranged below the lower of the two blades of the wind turbine. In a stacked set, this wind turbine blade will then also be an intermediate protection element disposed between two wind turbine blades. In addition, an intermediate protection element can be arranged under the lowest wind turbine blade in the stacked assembly. The intermediate protection elements can be made of a foamed polymer.
[0038] It is clear that some of the solution provided can also be used for other transport and storage configurations of wind turbine blades, for example, without the excess tip.
[0039] Thus, according to a second aspect, the invention provides a method for transporting or storing at least two wind turbine blades and which comprises a first wind turbine wind turbine blade and a second wind turbine blade. wind turbine wind turbine, the wind turbine blades, each having a root end and a tip end, in which the method comprises the steps of: a) placing the root end of the first wind turbine blade of a first root end structure, b) placing a tip end section of the first wind turbine wind turbine blade in a first tip end structure, c) placing the root end of the second blade wind turbine in a second root end structure, so that the second root end structure is arranged near the tip end of the first structure with the first substantially tip end structure above the second root end structure, d) placing a tip end section of the second wind turbine blade to a second tip end structure, so that the second tip end structure is installed close to the first root end structure with the second tip end structure substantially below the first root end structure, wherein the method comprises the additional step of arranging means for intermediate protection and between the first wind turbine blade and the second blade of wind turbine.
[0040] According to another aspect, the invention also provides a transport and storage system for at least two wind turbine blades and which comprises a first wind turbine wind turbine blade and a second turbine blade wind turbine wind, the blades of the wind turbine, each having a root end and a tip end, said system comprising a packaging system that is adapted for placement in the first wind turbine blade, so that the tip end of the first wind turbine blade blades points in a first direction, and placing the second wind turbine blade, so that the tip end of the second wind turbine blades points in a second direction, which is substantially opposed to the first direction, in which the transport and storage system includes a packaging system comprising: - a first root end structure for attachment to the root end of the first a wind turbine wind turbine blade, - a first tip end structure to support a tip end portion of the first wind turbine blade in one place, - a second root end structure for attachment to the root end of the second wind turbine wind turbine blade, and - a second tip end structure for supporting a tip end portion of the second wind turbine blade, wherein the packaging system further comprises an intermediate protection element disposed between the first wind turbine blade and the second wind turbine blade.
[0041] In another aspect, the invention provides a method for transporting or storing at least two wind turbine blades and comprising a first wind turbine wind turbine blade and a second wind turbine blade. wind turbine, the wind turbine blades each having a root end and a tip end, the method comprising the steps of: a) placing the root end of the first wind turbine blade of a first winding structure root end, b) placing a tip end section of the first wind turbine wind turbine blade in a first tip end structure, c) placing the root end of the second wind turbine blade at a second root end structure, d) placing a tip end section of the second wind turbine blade to a second tip end structure, in which e) the first root end structure and the second end tip end structure, as well as the first tip end structure and the second root end structure are connected as sets of T-shaped or L-shaped structures, so that the bases of the structure sets are connected at the root the ends of the first and second wind turbine blades, and the ends of the base assemblies to support a longitudinal section of the ends of the tips of the first and second wind turbine blades of wind turbines.
[0042] The invention also provides a transport and storage system for at least two wind turbine blades and which comprises a first wind turbine blade and a second wind turbine wind turbine blade, the wind turbine blades. wind each having a base end and a tip end, said system comprises a packaging system which is adapted to place the first wind turbine blade, so that the tip end of the first points of the first wind turbine blade in a first direction, and placing the second wind turbine blade, so that the tip end of the second points of the second wind turbine wind turbine blade are in a second direction, which is substantially opposite the first direction, in which the transport and storage system includes a packaging system comprising: f) a first root end structure for attachment to the root end of the first turbine blade and wind turbine unit, g) a first tip end structure to support a tip end portion of the first wind turbine blade in a first place, h) a second root end structure for attachment to the root end of the second wind turbine wind turbine blade, i) a second tip end structure for supporting a tip end portion of the second wind turbine blade, wherein j) the first root end structure and the second end structure of the tip, as well as the first tip end structure and the second root end structure are connected as sets of T-shaped or L-shaped structures, so that the bases of the sets of structures are connected to the root as ends of the first and second blades of wind turbine wind turbines, and the ends of the base assemblies to support a longitudinal section of the ends of the tips of the first and second second blades of wind turbines of wind turbines.
[0043] In addition, the invention provides a frame assembly for use in transporting and storing wind turbine blades, wherein the final frame assembly comprises a part root structure for attachment to a root end of a first part wind turbine blade and a frame tip to support a section end of the tip end of a second wind turbine blade, in which the root end structure part and the tip part end structure are connected in one configuration or T-shaped L-shaped.
[0044] In another aspect, the invention provides a transport and storage system for at least two wind turbine blades and which comprises a first wind turbine wind turbine blade and a second wind turbine blade wind turbine blades, the blades of the wind turbine each having a root end and a tip end, as well as a shoulder defining a maximum blade string, in which the method comprises the steps of: a) placing the end of the root of the first wind turbine blade of a first root end structure, b) the placement of a tip end section of the first wind turbine wind turbine blade in a first tip end structure, c) a placing the root end section of the second wind turbine blade on a second root end structure, d) placing the tip end section of the second wind turbine wind turbine blade on a second pole end structure e) arrange the first and second blades of wind turbines parallel to each other so that the first root end structure is placed adjacent to the second root end structure, and the first tip end structure is disposed adjacent to the second tip end structure, in which the first wind turbine wind turbine blade and the second wind turbine wind turbine blade are arranged so that the maximum string of the wind turbine blades form angles between 15 and 35 degrees with a horizontal plane, advantageously, between 20 and 30 degrees, more advantageously about 25 degrees.
[0045] It is clear that all the embodiments described in relation to a first aspect of the invention are equally applicable to any other aspect of the invention.
[0046] In particular, a transport system is provided for a wind turbine blade having a pointed end and a root end, the wind turbine blade still having a circle with diameter D of the screw at said root end, in that the transport system comprises: a root end transport structure for supporting a root end of a wind turbine wind turbine blade; a tip end transport structure for supporting a portion of a wind turbine blade for the tip end of said wind turbine blade, said tip end transport structure comprising a base structure and a support bracket, provided at the top of said base structure to receive a part of a wind turbine wind turbine blade; wherein said end-to-end transport structure is stackable on top of said root-end transport structure, from m that the conveyor system is operable to stack successive wind turbine blades of the wind turbines at one end of the root alternating the final disposition tip; wherein said root end transport structure has a height H; tip end transport structure comprises a frame base, with a height h; in which (H + h) is approximately equal to D; such that a transport structure and the root end of the base structure of one end of the tip overlap the transport structure stacked successively with one end of the root of a shovel. wind turbine supported by said root end transport structure.
[0047] Providing the end of the support tip with a base height of h means that when an individual wind turbine blade is supported on a surface, using the transport system, the tip end of such a wind turbine blade it is spaced from the underlying surface, by means of said height of the base. In addition, when in a stacked configuration, such as the construction of the root end structure, it allows the end structure of the tip to overlap with the root end of a wind turbine blade stacked under the tip end structure, the height of a stacked set of wind turbine blades using the aforementioned transport system will be reduced.
[0048] By overlapping, it should be understood that by providing the tip end structure, with a base height h, on which the support element is located, this allows the base structure to be stacked on top of a front root end structure, such that the vertical height of the root end structure and the base structure of the tip end structure is substantially equal to the root end diameter of the supporting wind turbine blade.
[0049] Preferably (0.5 D) <H <(0.9 D).
[0050] A root end transport structure is also provided for a wind turbine blade, the wind turbine blade having a tip end and a root end, the transport structure having a height, a width and a depth, wherein the height of the transport structure is less than the diameter of the circle of a root end screw of a wind turbine blade to be supported by said transport structure.
[0051] A low height transport structure allows for relatively easier handling of the transport structure, and reduces the transport and handling costs of the structure when not in use to support a wind turbine wind turbine blade.
[0052] Preferably, the width of said transport structure is equal to or greater than the diameter of the screw circle of a wind turbine blade to be supported by said transport structure.
[0053] Preferably, the depth of said transport structure is equal to or greater than a quarter of the width of the transport structure.
[0054] Providing a transport structure with such dimensions the result is a stable structure with a low center of mass, and which is capable of supporting a wind turbine blade.
[0055] Preferably, the root end transport structure comprises: a structure body; a root end plate coupled to said structure body, said root end plate arranged to couple with an end of the root of a wind turbine blade, wherein said root end plate is arranged to engage with less than 2/3 of the screw circle of a root end of a wind turbine blade to support said wind turbine blade wind turbine in said transport structure.
[0056] As the root end plate is designed to support a wind turbine blade by coupling with only a portion of the root end of the wind turbine blade it can be reduced according to the height of the end plate of the wind turbine. root, in relation to the diameter of the screw circle of the root end of the wind turbine wind turbine blade, resulting in a reduction in the total height of the root end transport structure.
[0057] Preferably, said root end plate comprises a substantially C-shaped body arranged to engage with a part of the circle of a screw at the end of the root of a wind turbine blade.
[0058] A root end transport structure for a wind turbine blade is also provided, the wind turbine blade having a tip end and a root end, the transport structure comprises: a frame body; a root end plate for coupling with the root end of a wind turbine blade, wherein said root end plate is hingedly coupled to said frame body.
[0059] When providing a hinged root plate, any bending moments due to the deflection or bending wind turbine blade are prevented from being transferred to the body of the structure. Therefore, the frame body may be of relatively light construction, since it does not need to withstand such relatively large forces.
[0060] Preferably, said root plate is hingedly coupled to said frame body along the horizontal axis.
[0061] As the angle to the vertical made by the root end of a wind turbine blade can depend on factors such as the center of gravity of the wind turbine blade and the bending properties of the wind turbine blade, According to the capacity for the hinge root structure along the horizontal axis it allows different angles for the root of the wind turbine blade to be accommodated with the transport structure.
[0062] Additionally or alternatively, said root plate is articulated coupled to said body of structure along the vertical axis.
[0063] The articulation of the root plate around the vertical axes prevents damage to the transport structure due to misalignment or handling problems.
[0064] Preferably, said root end plate is mounted on at least one support arm, said at least one arm coupled to said transport structure through an articulated joint.
[0065] Preferably, said at least one support arm comprises an articulated support.
[0066] The use of an articulated support allows greater degrees of freedom of manipulation of the root plate, to receive and accommodate the root end of a wind turbine blade on the transport structure more easily.
[0067] Preferably, said transport structure comprises at least a first and a second support arm, wherein said first and second support arms are positioned on opposite sides of a nominal central longitudinal axis of a shovel. wind turbine to be mounted on said root end plate.
[0068] When positioning the support arms on both sides of the central point of the root end of the wind turbine blade, the adoption of forces from the root end of the blade is balanced in the transport structure.
[0069] A transport structure is also provided for a tip end of the wind turbine wind turbine blade, the wind turbine blade having a tip end and a root end, the transport structure comprises: a body of a tip end support bracket for supporting a portion of a wind turbine blade towards the tip end of said wind turbine blade, wherein a first end of said tip end support bracket is hingedly coupled to said transport structure along the horizontal axis; and in that an edge support bracket flap is provided on said support, carrying said edge support flap arranged to receive a portion of the main edge of a wind turbine blade supported by said support bracket, such that the wind turbine blade can be rotationally moved over said articulated coupling in relation to said transport structure to that supported on said support.
[0070] By providing an articulated coupling for the support bracket, a wind turbine blade can be adjusted in relation to the body of the structure, to allow the correct positioning of the wind turbine in the transport structure. The support flap provided on the support allows partial support of the wind turbine wind turbine blade, preventing unwanted movement of the wind turbine wind turbine blade during any subsequent turn or transport.
[0071] Preferably, a second end of said support element can be removably attached to said body, when said support structure is received in said structure body.
[0072] Preferably, said tip end support element comprises a flexible strap having a support surface provided on said flexible strap.
[0073] The use of a flexible belt as part of the support allows adjustments or movements of a supported wind turbine blade to be absorbed by twisting or twisting the appropriate strap, without being transferred to the relatively rigid structural body. Therefore, the frame body may have a lighter construction compared to prior art systems.
[0074] Preferably, the tip end transport structure further comprises a safety strap to be mounted around a wind turbine blade received in said transport structure.
[0075] Preferably, the tip end transport structure is arranged to be positioned in a location for the tip end of a wind turbine blade to be supported by the transport system, such that a sweep or curvature of the wind turbine blade from the location of said tip end of the transport structure to the tip end of the supported wind turbine blade is less than the height h of the base structure of the tip end transport structure.
[0076] The transport system is preferably used for the transport of wind turbine blades having a Δy pre-fold, and / or wind turbine blades. Therefore, the location of the support member of the tip end structure above the horizontal surface by a height h allows such a wind turbine blade to bend to be supported on the ground, without the tip end of the wind turbine blade from reaching the ground.
[0077] Preferably, the tip end transport structure is arranged to be positioned spaced from the tip end of the wind turbine blade.
[0078] Preferably, a wind turbine blade to be supported by the transport system has a longitudinal length L, in which the tip end transport structure is arranged to be positioned at a distance F from the root end of said blade. wind turbine, where (0.5 L) <F <(0.95L), preferably (0.6 L) <F <(0.85L).
[0079] Supporting the tip portion of the wind turbine blade at such a location on the outer portion of the wind turbine blade, spaced from the tip end, provides a balance between the effectiveness of the supporting structural wind turbine blade, at the same time reduces the minimum wheelbase or effective surface required to support the transport system.
[0080] A method of transporting at least two wind turbine blades with a tip end and a root end is also provided, the method comprising the steps of: supporting a first wind turbine wind turbine blade, wherein a first root end transport structure is arranged to support the root end of said first wind turbine wind turbine blade and a first tip end transport structure is arranged to support a portion of said first wind turbine blade for the tip end of said first wind turbine blade, said first wind turbine wind turbine blade with a diameter D of screw circle at said root end; supporting a second wind turbine blade, in that a second root end transport structure is arranged to support the root end of said second wind turbine blade and a second structure tip end transport means is arranged to support a portion of said second wind turbine wind turbine blade to the tip end of said second wind turbine blade, and to lift said second root end transport structure on top of the said first tip tip end transport structure, and stacking of said second tip end transport structure of said first root end transport structure, wherein said second wind turbine wind turbine blade is stacked in a root end alternating the final tip of the arrangement above said first wind turbine wind turbine blade to form a transport unit, wherein at least said first root transport structure end is arranged to have a height H, in which said first transport structure and second tip end are arranged to suppose remove the respective first and second wind turbine blades from wind turbines at a height h above the base of the first and second tip-end transport structures, and where (H + h) is approximately equal to D, so that said first root end transport structure and at least a portion of said second overlap end end transport structure with the root end of said first wind turbine wind turbine blade.
[0081] It should be understood that any of the characteristics described above can be combined in any embodiment of the transport system, as described. Furthermore, it is to be understood that said tip end transport structure can be provided separately with said root end transport structure, and vice versa. DETAILED DESCRIPTION OF THE INVENTION
[0082] The invention is explained in detail below with reference to embodiments shown in the drawings, in which
[0083] Fig. 1 shows a wind turbine,
[0084] Fig. 2 shows a schematic view of a wind turbine blade according to the invention,
[0085] Fig. 3 shows a schematic view of an airfoil profile,
[0086] Fig. 4 shows a schematic view of the wind turbine blade according to an embodiment of the invention, seen from above and from the side,
[0087] Fig. 5 shows a schematic side view of a first wind turbine blade and a second wind turbine blade stored in a packaging system according to an embodiment of the invention,
[0088] Fig. 6 illustrates how the blades are oriented in the packaging system according to an embodiment of the invention,
[0089] Fig. 7 shows a schematic view of the wind turbine blade end stored in a stacked set of packaging systems according to an embodiment of the invention,
[0090] Fig. 8 shows a top view of the mutual arrangement of the wind turbine blades when stacked in a matrix,
[0091] Fig. 9 shows a schematic side view of a series of wind turbine blades first and second wind turbine blades of wind turbines stored in a packaging system according to an embodiment of the invention with intermediate protection means arranged between the wind turbine blades,
[0092] Fig. 10 shows a perspective view of a wind turbine blade stored in a stacked set of packaging systems in an alternative embodiment of the present invention,
[0093] Fig. 11 shows an embodiment of a root end transport structure according to an embodiment of the invention,
[0094] Fig. 12 shows an embodiment of a tip end transport structure according to an embodiment of the invention, and
[0095] Fig. 13 shows a side view of an arrangement of pre-folded wind turbine blades supported by transport systems according to embodiments of the invention.
[0096] The present invention relates to the transport and storage of wind turbine blades of horizontal axis wind turbines (HAWTs).
[0097] Fig. 1 illustrates a modern conventional wind turbine according to the so-called "Danish concept" with a tower 4, a motor spindle 6 and a rotor with an essentially horizontal rotor shaft. The rotor includes an axis 8 and three wind turbine blades 10 that extend radially from axis 8, each having a root wind turbine blade 16 closer to the axis and a tip of the wind turbine blade 14 further away from the shaft. axis 8. The rotor has an indicated radius R.
[0098] Fig. 2 shows a schematic view of a first embodiment of a wind turbine blade 10. The wind turbine blade 10 is shaped like a conventional wind turbine blade and comprises a root region 30, closer to the axis, a profile or an airfoil region 34, further away from the axis and a transition region 32 between the root region 30 and the airfoil region 34. The wind turbine blade 10 comprises a leading edge 18 facing the direction of rotation of the wind turbine blade 10, when the wind turbine blade is mounted on the shaft, and a trailing edge 20 facing away from the leading edge 18.
[0099] The airfoil region 34 (also called the profiled region) has an ideal or almost ideal wind turbine blade shape with respect to elevator generation, whereas the root region 30, due to structural considerations, it has a substantially circular or elliptical cross-section, for example, which makes it easier and safer to mount the wind turbine blade 10 with the shaft. The diameter (or chord) of the root region 30 can be constant across the entire root area 30. The transition region 32 has a transition profile gradually changing in a circular or elliptical shape from the root region 30 of the airfoil of the airfoil region 34. The chord length of the transition region 32 normally increases with increasing distance from the center. The airfoil region 34 has an airfoil profile with a rope that extends between the leading edge 18 and the trailing edge 20 of the wind turbine blade 10. The width of the rope decreases with increasing distance r from the center.
[0100] A shoulder 40 of the wind turbine blade 10 is defined as the position, where the wind turbine blade 10 has its longest rope length. The shoulder 40 is typically provided at the boundary between the transition region 32 and the airfoil region 34.
[0101] It should be noted that the strings from different sections of the wind turbine blade do not normally meet in a common plane, since the wind turbine blade may be twisted and / or curved (that is, pre-folded) , thus providing the plane of the rope with a correspondingly twisted and / or curved path, this is the most frequent case, in order to compensate the local speed of the wind turbine blade as being dependent on the radius from the center.
[0102] The wind turbine blade 10 comprises a shell made of fiber-reinforced polymer and is normally made as a pressure side or part of the windshield 24 and a suction side or part of the downwind shell 26 which they are glued along the connecting lines 28 and extend along the trailing edge 20 and the leading edge 18 of the wind turbine blade 10.
[0103] Figs. 3 and 4 illustrate the parameters, which are used to explain the geometry of the wind turbine blades to be stored and transported according to the invention.
[0104] Fig. 3 shows a schematic view of an airfoil profile 50 of a wind turbine blade typical of a wind turbine represented with the various parameters, which are typically used to define the geometric shape of an aerodynamic profile. The airfoil profile 50 has a pressure side 52 and a suction side 54, which during use - that is, during the rotation of the rotor - normally facing windward (or against the wind) and the leeward side ( or downwind), respectively. Airfoil 50 has a rope 60, with a length of rope c that extends between a leading edge 56 and a trailing edge 58 of the wind turbine blade. The airfoil 50 has a thickness t, which is defined as the distance between the pressure side 52 and the suction side 54. The thickness t of the airfoil varies along the string 60. The deviation from a symmetrical profile is given by a line curvature 62, which is a median line along the profile 50. The aerodynamic profile of the median line can be found by selecting inscribed circles from the leading edge 56 to the trailing edge 58. The median line follows the centers of said inscribed circles and the deviation or distance from the string 60 is called curvature f. Asymmetry can also be defined by using parameters called the upper curvature (or suction side of curvature) and lower curvature (or the curvature of the pressure side), which are defined as the distances from the rope 60 and the side suction 54 and pressure side 52, respectively.
[0105] Airfoil profiles are often characterized by the following parameters: co length of the rope, f maximum curvature, df the position of the maximum curvature f, t the maximum thickness of the airfoil, which is the largest diameter of the circles inscribed along the curvature line mean 62, dt the maximum position of thickness t, and a nose radius (not shown). These parameters are usually defined as reasons for the length of the string c. Thus, a relative thickness of the local wind turbine blade t / c is given as the ratio between the maximum local thickness t and the length of the local rope, c. In addition, the position of the maximum curvature on the pressure side can be used as a design parameter, and also, of course, the position of the maximum curvature on the suction side.
[0106] Fig. 4 shows other geometric parameters of the wind turbine blade. The wind turbine blade has a total length of the wind turbine blade L. As shown in Fig. 3, the root end is located at position r = 0, and the tip end located at r = L. The shoulder 40 The wind turbine blade is located at a position r = Lw, and has a shoulder width W, which is equal to the length of the rope in the shoulder 40. The root diameter is defined as X. In addition, the turbine blade wind power has a pre - bend which is defined as Δy, which corresponds to the deflection out of the plane from a field axis 22 of the wind turbine blade.
[0107] Wind turbine blades over time become longer and longer and can now be over a length of 70 meters. The length of the wind turbine blades, as well as the shape of the wind turbine blades in relation to the shoulder, twist and pre-arching makes it increasingly difficult to transport the wind turbine blades, in particular, if a plurality of wind turbine blades must be transported and stored together. The shape and size of the wind turbine blades also place limitations on the close shape of the wind turbine blades that can be stored in a stacked set.
[0108] Fig. 5 shows a schematic view of the first embodiment of a transport and storage system according to the invention for the transport and storage of a first wind turbine blade and a second wind turbine blade. wind 10. The transport and storage system includes a packaging system comprising a first frame assembly 70. The first frame assembly 70 consists of a root end structure 71 in the form of a root end support for connection to a root end face 17 of the first wind turbine blade, and a tip end structure 72 to support a tip end section 15 of the second wind turbine blade. The first frame assembly has an L-shaped configuration, where the root end support 71 forms the base of the L-shaped assembly, and the tip end of the frame 72 forms a cross-extending part of the frame ( or ends) extending from the root top of the end support 71. The second set of frame 80 is also comprised of a root end structure 81, in the form of a root end support for attachment to a face of the root end 17 of the second wind turbine blade, and a tip end structure 82 for supporting a tip end section 15 of the first wind turbine blade. The first frame assembly has an L-shaped configuration, where the root end support 81 forms the base of the L-shaped assembly, and the tip end of the frame 82 forms a part of the structure that extends transversely ( or ends) extending from the bottom of the root end structure 81.
[0109] In terms of the following claims, it is clear that the first frame assembly comprises the first root end structure and the second tip end structure, while the second structure assembly comprises the second root end structure and the first tip end structure.
[0110] Some local regulations have limitations on the maximum distance between the supports for transporting items, for example, a maximum of 42 meters. The packaging system accommodates these regulations by being designed so that the first tip end of the wind turbine wind turbine blade ends and the second wind turbine wind turbine blade extends beyond the root end structures 70, 80 so that the longitudinal measure or protrusion of the tip ends extends beyond the root end structures 70, 80, thus being able to transport wind turbine blades of lengths greater than lf, the maximum distance between the supports . In addition, this new configuration has the advantage that the tip end sections are supported at a distance from the respective tip ends, where the wind turbine blades are mechanically stronger than the right end. Thus, the likelihood that wind turbine blade frames will be harmful is significantly reduced. In addition, the L-shaped configuration of the structure sets 70, 80 is adapted to support the tip end over a longitudinal extension of, for example, at least 1 meter, thus ensuring an even better support for the wind turbine blades. .
[0111] The tip end structures 72, 82 can advantageously comprise one or more containers having a support face facing upwards, to support a part of the windward side of the wind turbine blade. In addition, the tip end structures 72, 82 can advantageously be removably connected with the root end structures 71, 81.
[0112] In the configuration shown, the wind turbine blades are arranged with the pressure side (or windward side) substantially downwards. In this way, the wind turbine blades are also arranged so that the middle part of the wind turbine blade is further away from the floor support surface or due to the pre - arching of the wind turbine blades. However, the wind turbine blades are, as shown in Fig. 6, turned so that the boundary lines 28, as well as the shoulder rope 40, form an α angle of about 25 degrees with a horizontal line 29. This has an additional advantage, when the wind turbine blades are stacked in arrays comprising first and second frame assemblies 70, 80 and, consequently, comprising an array of wind turbine blades stored from the first and second wind turbines, once that wind turbine blades can be stacked more compactly than conventional systems for transporting and storing such wind turbine blades. This is best illustrated in Figs. 7 and 8, showing wind turbine blades stacked in a matrix, in which Fig. 7 shows an end view of the transport and storage system with the wind turbine blades stored in the system, and Fig. 8 shows a view top of the wind turbine blades of the matrix, with the storage system removed from the figure, in order to better illustrate the mutual arrangement of the wind turbine blades.
[0113] From the end view, shown in Fig. 7, it appears that the first wind turbine blades that have their root end faces connected to the root end supports 71 are arranged so that the shoulders of the wind turbine blades 40 of points slightly upwards and to the right, while the second wind turbine blades which have their tip-end structure sections supported on the tip-end structures 72 and are arranged so that the bumps 40 of the point from above and to the left of the figure. In this way, the wind turbine blades can be stacked side by side in structures that are only slightly wider than the diameter of the root D of the wind turbine blades.
[0114] In the top view, shown in Fig. 8, it can be seen that the wind turbine blades are arranged so that they overlap slightly with the shoulder 40 of a wind turbine blade that partially extends over a blade of wind turbine. adjacent wind turbine so that the windward side of a wind turbine blade near the ledge faces downward to the leeward side near the leading edge of an adjacent wind turbine blade.
[0115] In some situations it may be advantageous to provide additional support components for accessing loads from the wind turbine blades, for example, through intermediate protection members 90 between the first and second wind turbine blades of wind turbines . The intermediate protection members 90 can advantageously be arranged near the tip end of the upper wind turbine blade, so that the loads can be transferred from an end section of the upper wind turbine blade to a root section of a lower wind turbine blade. An additional protection member 92 can be arranged between the lower wind turbine blade in the matrix and a support or ground platform. Protective members 90, 92 can, for example, be made of a foamed polymer.
[0116] With reference to fig. 11, an embodiment of a root end transport structure, according to an aspect of the invention, is generally indicated at 100. The root end transport structure 100 comprises a body 102 and a plate end of the root 104, coupled to the body of the structure 102. FIG. 11 (a) illustrates a front perspective view of the transport structure 100, fig. 11 (b) illustrates a plan view of a root end plate 104 of the transport structure, Fig. 11 (c) illustrates a rear perspective view of the transport structure 100, and fig. 11 (d) illustrates a rear perspective view of the end plate of the root structure of Fig. 11 (c).
[0117] The transport structure 100 is arranged to couple with less than the entire circumference of a screw circle of a wind turbine blade to be supported by the transport structure, since it offers several advantages in terms of stability, and transportation and handling issues.
[0118] The transport structure 100 is designed to have a height H less than the diameter of the screw circle of the root end of a wind turbine blade to be supported by the transport structure, and preferably to have a width W, equal to or greater than the said diameter of the screw circle. The depth Df of the structure 100 is designed to adequately support the structure 100, preferably being at least a quarter of the diameter distance from the screw circle. Such a construction provides a relatively low center of mass of the transport structure 100, and reduces the possibility of the structure 100 of being easily nullified, either when supporting a root end of a wind turbine blade or when not supporting a wind turbine blade. .
[0119] The root end plate 104 is hingedly coupled to the structural body 102, through a pair of arms protruding from the support 106. In the embodiment of fig. 11, the support arms 106 are articulated with the body of the structure 102, around the horizontal axis, but will be understood to be any suitable articulated joint, which can be provided, and / or articulated supports can be provided. The use of an articulated connection between the root end plate 104 and the body of the structure 102 means that the plate 104 can be supplied at any suitable angle with respect to the vertical, to accommodate any bending or deformation of the root end of the blade. wind turbine, without transferring such bending moments to the body of the structure 102. As a result, the structural body 102 can be of a relatively light construction, since it does not have to withstand such relatively large bending moments from the end of the wind turbine blade root.
[0120] Preferably, at least two support arms 106 are provided, with arms 106 prepared to be spaced around the center point of the root end of a wind turbine blade, supported by said transport structure 100 , in such a way that the forces associated with said wind turbine blade are uniformly transferred to the body supporting structure 102.
[0121] The root end plate 104 is preferably arranged to couple with a subsection of the screw circle of one end of the wind turbine blade root, which results in a reduced height of the entire structure of the wind turbine structure. transport 100. The embodiment of fig. 11 shows end plate 104, which has a substantially C-shaped structure, where plate 104 is operable to couple about 2/3 the circumference of a wind turbine blade root end screw. The engagement shape and root end plate 104 is selected to adequately support a root end of a wind turbine blade, while keeping the height of the transport frame 100 structure to a minimum.
[0122] It should be understood that any other suitable shape of the root end plate 104 can be used, which is arranged to be coupled with a part of a circle of a wind turbine blade screw, for example, a plate U-shaped, a substantially square plate, etc.
[0123] It is to be understood that the root end plate 104 can be provided with a plurality of coupling openings arranged along separate fictional screw circles on the root end plate 104, to accommodate the end plate coupling of root root 104 of different ends of the wind turbine blade, of wind turbine, having different circle diameters. This allows the root end transport structure 100 to be used interchangeably with blades for wind turbines of different sizes. It should also be understood that the coupling openings can be shaped to be wider and / or more than the openings corresponding to the screw circle of a wind turbine blade, to allow for the coupling adjustment between the root end plate 104 and the root end of the wind turbine blade, for example, in the case of misalignment, the ovalization of the root end, etc.
[0124] With reference to fig. 12 (a), an embodiment of a tip end transport structure according to an aspect of the invention, is generally indicated by 108. Transport structure 108 comprises a base structure 110 and a support portion 112, provided at the top of the base structure 110. The support part 112 comprises at least one end support support tip 114, which is pivotally coupled with the transport structure 108. Support support 114 receives a portion of a wind turbine blade (indicated by section 116) to be supported by the tip end transport structure 108, wherein the portion of the wind turbine blade is spaced from the tip end of the wind turbine blade.
[0125] With reference to fig. 12 (b), an enlarged view is shown of an example of a support bracket end of the tip 114. The support bracket 114 comprises a first and a second end 118a, 118b arranged to couple with the support part 112 of the support structure. tip end transport 108. The support bracket 114 further comprises a padding or padding material 120 arranged to support the surface of a wind turbine blade. A front edge support flap 122 is provided on support support 114, preferably projecting from the padding or padding material 120. The front edge support flap 122 is arranged to receive the leading edge of a wind turbine blade supported on the support bracket 114, to prevent movement of the wind turbine blade when on the support bracket 114.
[0126] In use, a first end 118a of the support bracket 114 can be connected to the support portion 112, with the second end 118b protruding freely from the structure. A portion 116 of a wind turbine blade can be placed on the support bracket 114 with the main edge of the wind turbine blade, mounted adjacent to said flap 122. The support can then be pivoted in relation to the body of the transport structure , to position the wind turbine blade within the transport frame 108, at which point the second end 118b of the support bracket 114 can be attached to the structure 108. A secondary support strip 124 can then be positioned along the surface of the support structure. blade section 116 opposite the supporting support element 114, and fixed with the support part 112, to securely hold the wind turbine wind turbine blade within the transport structure 108.
[0127] It is to be understood that the support arm 114 can be formed from a relatively flexible strap having a padding or padding material 120 and a support front edge flap 122 molded with the strap.
[0128] The base structure 110 of the tip end transport structure 108 has a height h. This ensures that portion 116 of the wind turbine blade is supported at a distance h from the ground or the underlying surface. With reference to fig. 13, this configuration of a transport system for a wind turbine blade provides additional advantages when used for the transport or storage of pre-folded wind turbine blades, in which the wind turbine blades are manufactured to have a curve or curvature in a substantially upwind direction, as described in European Patent No. EP1019631.
[0129] Fig. 13 (a) illustrates a root-to-tip arrangement of blade stacking for pre-folded wind turbines 128, using a conveyor system, as shown in the figures. 5 and 9, provided on a surface of S. In this case, the pre-curvature of the blades of the wind turbine 128 will result in the end of the tip 128a of the lower wind turbine blade that protrudes below the level of the surface S for the stack of the wind turbine. transport system. Therefore, the transport system stack must be provided on a platform raised in some way from ground level, to ensure that the tip end 128a of the bottom wind turbine blade is not damaged when disposed on the stack. Such an arrangement can lead to additional complications when handling and transporting the battery.
[0130] In contrast, fig. 13 (B) illustrates an arrangement from root to blade stacking tip for pre-folded wind turbines 128 using a conveyor system comprising the final root structure 100 and the tip end structure 108 of the Figures. 11 and 12, provided on a surface S. In this embodiment, as the tip end transport structure 108 supports the wind turbine blade section 116 at the top of the base structure 110, at a distance h from the level of the surface S, therefore, the tip of the end 128 of the bottom wind turbine blade is kept above the level of the surface S, eliminating the need for any further increase of the transport stack above the surface S.
[0131] The tip end transport structure is arranged to be positioned in a direction towards, but spaced from, the tip end of a wind turbine blade. Preferably, the tip end transport structure is arranged to be positioned at a distance F from the tip of the blade root, where (0.5 L) <F <(0.95L), preferably (0, 6 L) <F <(0.85L). Supporting the tip portion of the wind turbine blade at such a location, on the outer portion of the wind turbine blade, spaced from the tip end, providing a balance between the effectiveness of the wind turbine blade support structure, while reducing the minimum support wheelbase or effective surface required to support the transport system.
[0132] Furthermore, due to the reduced height of the root tip transport structure 100, the base structure 110 of the subsequent tip end transport structure 108, which are stacked at the front end of the root transport structures 100, effectively overlap with the root end of the wind turbine blade supported on the front of root end transport structures 100. This arrangement acts to reduce the total height of the transport stack, while accommodating the adjusted dimensions of the end transport structures of the end. tip 108, which provides for easy handling and minimized space requirements for transportation.
[0133] Preferably, the combined height H of the root end transport structure 100 and height h of the base structure 110 of the tip end transport structure 108 is approximately equal to the distance of the diameter of the blade circle of a shovel wind turbine to be supported by the transport structure 100,108.
[0134] The invention has been described with reference to preferred embodiments. However, the scope of the invention is not limited to the illustrated embodiments, and changes and modifications can be made without departing from the scope of the invention, which is defined by the following claims. The packaging system, for example, has been described in relation to an L-shaped frame assembly. However, in another advantageous embodiment, the structure assembly may be T-shaped, so that the support root end is fixed with the tip end structure in an intermediate part of it. In addition, the wind turbine blades can be stacked in a packaging system, in which the root end structures and tip end structures are arranged in the same plane, as shown in Fig. 10. The transport and delivery systems storage have also been described in a configuration, in which the second wind turbine blade is arranged over the first wind turbine blade. However, it is clear that the system can also be arranged in a configuration, in which the first and second blades of wind turbines are arranged side by side. In such a configuration, the wind turbine blades, instead, are arranged so that the glue lines and wake up the shoulder to form an angle of approximately 25 degrees in relation to the vertical. In addition, the containers of the tip end structures could instead be adapted to supported on the leading edge of a tip end section, instead.
[0135] The invention is not limited to the embodiments described herein, and can be modified or adapted, without departing from the scope of the present invention.
[0136] List of numerical references 2 Wind turbine 4 Tower 6 Motor spindle 8 Axis 10 Wind turbine blades 14 End of the wind turbine blade 15 Final section of the tip 16 Root wind turbine blades 17 Root end face 18 Main edge 20 Vanishing edge 22 Tilt axis 24 Part of the pressure side bark / part of the cascade against the wind 26 Part of the suction side bark / part of the windproof shell 28 Connecting lines 29 Horizontal 30 Root region 32 Region of transition 34 Airfoil region 50 Airfoil profile 52 Pressure side / downwind side 54 Suction side / downwind side 56 Main edge 58 Vanishing edge 60 Rope 62 Curve line / midline 70 First frame assembly 71 Root end frame / root end bracket (from first frame assembly) 72 Tip end frame / frame part that extends transversely (from first frame assembly) 80 First frame assembly structure 81 Root end structure / root end support (from the first mounting frame) 82 Point end structure / part of the structure extending transversely (from the first mounting frame) 90 Intermediate protection member 92 Member of additional protection 100 Root end transport frame 102 Frame body 104 End root plate 106 Support arms 108 Tip end transport frame 110 Base frame 112 Support part 114 Support bracket 116 Turbine blade part wind turbine 118 Support end support 120 Padded support material 122 Main edge support flap 124 Retaining strap c length of the maximum thickness position df maximum curvature position dp maximum pressure position on the curvature side f curvature lf distance between longitudinal end structures and longitudinal extension of the tip protrusion of the turbine blade wind L Length wind turbine blade r local radius, radial distance from the root of the wind turbine blade t thickness D diameter of the root of the wind turbine blade Δy pre-bend H height root end of the transport structure W Structure width root tip transport structure Df Depth of the root end transport structure h height of the tip end transport structure.

权利要求:
Claims (19)
[0001]
1. Transport system for a wind turbine blade characterized by having a tip end and a root end, the wind turbine blade additionally having a diameter of the screw circle Dat said root end, in which the transport system comprises : at least the root end transport structure to support one end of the root of a wind turbine wind turbine blade; at least one end end transport structure to support a portion of a wind turbine blade to the end of the wind turbine tip of said wind turbine blade, said tip end transport structure comprising a base structure and a support support provided at the top of said base structure for receiving a portion of a wind turbine blade; the tip end transport structure is stackable on top of the root end transport structure, so the conveyor is operable to stack successive wind turbine blades of the wind turbines at one end of the root alternating the end arrangement tip; wherein said root end transport structure has a height H; wherein the tip end transport structure comprises a frame base, with a height h; and in that (H + h) is approximately equal to D, such that a root end transport structure base end tip overlapping transport structure stacked successively with a root end of a turbine blade wind turbine supported by said root end transport structure.
[0002]
Transport system according to claim 1, characterized in that (0.5 D) <H <(0.9 D), preferably (0.5 D) <H <(0.75D).
[0003]
Transport system according to claim 1 or claim 2, characterized in that the root end transport structure has a height, width and depth, wherein the width of said root end transport structure is equal to or greater than the diameter of the circle of a wind turbine blade screw to be supported by said root end transport structure.
[0004]
Transport system according to any of claims 1 to 3, characterized in that the root end transport structure has a height, width and depth, wherein the depth of the root end transport structure is equal to or greater than a quarter of the width of the root end transport structure.
[0005]
Transport system according to any one of the preceding claims, characterized in that the transport structure of the root end comprises: a frame body; In a root end plate coupled to said frame body, said root end plate arranged to engage with a root end of a wind turbine blade, wherein said root end plate is arranged to engage with less than 2/3 of the screw circle at one end of the root of a wind turbine blade to support said wind turbine blade in said root end transport structure.
[0006]
Transport system according to claim 5, characterized in that said root end plate comprises a substantially C-shaped body arranged to engage with a part of the circle of a screw at the end of the root of a turbine blade wind power.
[0007]
Transport system according to any one of the preceding claims, characterized in that the root end transport structure comprises: a frame body; a root end plate for coupling with the root end of a wind turbine blade, wherein said root end plate is hingedly coupled to said frame body.
[0008]
Transport system according to claim 7, characterized in that said root end plate is pivotally coupled to the structural body of said transport structure along the root end of the horizontal axis.
[0009]
Transport system according to claim 7 or claim 8, characterized in that said root end plate is hingedly coupled to the structural body of said transport structure along the root end of the vertical axis.
[0010]
Transport system according to any one of claims 7 to 9, characterized in that said root end plate is mounted on at least one support arm, said at least one arm coupled to said end root transport structure through of an articulated joint.
[0011]
Transport system according to claim 10, characterized in that said at least one support arm comprises an articulated support.
[0012]
Transport system according to claim 10 or claim 11, characterized in that said root end transport structure comprises at least a first and a second support arm, wherein said first and second support arms are positioned on opposite sides of a theoretical central longitudinal axis of a wind turbine wind turbine blade to be mounted on said root end plate.
[0013]
Transport system according to any preceding claim, characterized in that said final transport frame tip comprises: a frame body, at least one tip end support element for supporting a portion of a wind turbine blade for the tip end of said wind turbine blade, wherein a first end of said tip end support element is pivotally coupled to said tip tip transport structure along the horizontal axis; and in that a leading edge of a wind turbine blade is provided on said support, carrying said edge wind turbine blade arranged to receive a portion of the leading edge of a wind turbine blade supported by said support element, such that the wind turbine wind turbine blade can be rotatably moved over said articulated coupling with respect to said tip end transport structure while supported on said support.
[0014]
Transport system according to claim 13, characterized in that a second end of said support element can be removably attached to the body of the transport structure of said tip end structure when said support element is received in said body of structure.
[0015]
Transport system according to claim 13 or claim 14, characterized in that said tip end support element comprises a flexible band having a support surface provided in said flexible band.
[0016]
Transport system according to any one of claims 13 to 15, characterized in that the tip end transport structure further comprises a safety belt to be mounted around a wind turbine blade received in said end transport structure the tip.
[0017]
17. Transport system according to any one of the preceding claims, characterized in that said tip-end transport structure is arranged to be positioned in a location for the tip end of a wind turbine blade to be supported by the transport system, such that a sweep or wind curve of the wind turbine blade from the location of said tip end transport structure to the tip end of the supported wind turbine blade is less than the height h of the structure base of the tip end transport structure.
[0018]
Transport system according to any one of the preceding claims, characterized in that a wind turbine blade is supported by the transport system having a longitudinal length L, and in which the end of the tip end transport structure is arranged to be positioned at a distance F from the root end of said wind turbine blade, where (0.5 L) <F <(0.95L), preferably (0.6 L) <F <(0.85L).
[0019]
19. Method of transport of at least two blades of wind turbines having a tip end and a root end, the method characterized by comprising the steps of: supporting a first wind turbine blade of wind turbine, in which a first structure of root end transport is arranged so as to support the root end of said first wind turbine wind turbine blade and a first tip end transport structure is arranged to support a portion of said first wind turbine blade for the tip end of said first wind turbine blade, said first wind turbine blade with a diameter D circle of screws at said root end; supporting a second wind turbine blade, wherein a second end transport structure of the root is arranged to support the root end of said second wind turbine blade and a transport structure for the second the tip end is arranged to support a portion of said second wind turbine blade to the tip end of said second wind turbine blade, piling said second root end transport structure on top of said first wind structure tip end transport, and stacking of said second tip end transport structure of said root end transport structure, wherein said second wind turbine wind turbine blade is stacked on one end of the root alternating the tip end of the above arrangement said wind turbine blade of first wind turbine to form a transport unit, wherein at least said first root end transport structure is arranged to have a height H, wherein said transport structure of the first and second tip end are arranged to support the respective first and second turbine blades wind turbine wind turbines at a height h above the base of the first and second tip-end transport structures, and (H + h) is approximately equal to D, such that said first end-transport structure of the root and at least a portion of said second end-carrying structure of the overlapping tip with the root end of said first wind turbine wind turbine blade.

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同族专利:

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公开号 | 公开日

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US9874235B2|2018-01-23|

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US20150300314A1|2015-10-22|

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US10781834B2|2020-09-22|

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EP3098435A1|2016-11-30|

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US20160369768A1|2016-12-22|

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CN104755753A|2015-07-01|

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WO2014064247A1|2014-05-01|

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ES2621508T3|2017-07-04|

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DK2917566T3|2017-04-24|

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EP2917566B1|2017-01-04|

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BR112015008854A2|2017-07-04|

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PL2917566T3|2017-07-31|

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CN104755753B|2018-01-02|

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EP2917566A1|2015-09-16|

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法律状态:
2018-11-21| B06F| Objections, documents and/or translations needed after an examination request according art. 34 industrial property law|

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2020-03-24| B06U| Preliminary requirement: requests with searches performed by other patent offices: suspension of the patent application procedure|

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2021-01-19| B09A| Decision: intention to grant|

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2021-03-02| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 25/10/2013, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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GB1219279.5|2012-10-26|

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GBGB1219279.5A|GB201219279D0|2012-10-26|2012-10-26|Method and system for transporting and storing at least two wind turbine blades|

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GB1220100.0|2012-11-08|

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GB201220100A|GB201220100D0|2012-11-08|2012-11-08|Method and system for transporting and storing at least two wind turbine blades|

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PCT/EP2013/072386|WO2014064247A1|2012-10-26|2013-10-25|Method and system for transporting and storing at least two wind turbine blades|

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