A method is provided for handling wind turbine blades aboard a vessel, the method including providing on the vessel a blade rack assembly configured to accommodate more than one blade, the rack assembly having at least a root rack and a tip rack, and the root rack and tip rack defining between them a blade support plane. The method also includes providing a jack acting between the vessel and one of the root or tip rack; and raising or lowering one of the root or tip rack aboard the vessel by the jack to thereby move the blade support plane through an elevation angle θ. A jack assembly on a wind turbine installation vessel and an offshore wind turbine installation vessel are also provided, each capable of raising or lowering a rack of wind turbine blade root or tip support frame elements.
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1. A method for handling wind turbine blades aboard a vessel, said method comprising:
providing on said vessel a blade rack arrangement configured to accommodate more than one blade, said rack arrangement comprising at least a root rack and a tip rack, wherein said root rack and said tip rack between them define a blade support plane;
providing a jack including a drive device acting between said vessel and at least one of a lifting platform or a rotatable rack spacer associated with one of said root rack or tip rack; and
raising or lowering one of said root rack or tip rack aboard said vessel by means of said jack to thereby move said blade support plane through an elevation angle.
15. A method for handling wind turbine blades aboard a vessel, said method comprising:
providing on said vessel a blade rack arrangement configured to accommodate more than one blade, said rack arrangement comprising at least a root rack and a tip rack, wherein said root rack and said tip rack between them define a blade support plane;
providing a jack acting between said vessel and one of said root rack or tip rack, wherein said jack comprises a linear drive operatively coupled to said vessel proximate a first end of said linear drive and pivotably coupled to at least one of a lifting platform or a rotatable rack spacer proximate a second end of said linear drive; and
raising or lowering one of said root rack or tip rack aboard said vessel by means of said jack to thereby move said blade support plane through an elevation angle.
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9. A jack on a wind turbine installation vessel capable of raising or lowering a rack of wind turbine blade root support frame elements or tip support frame elements of the blade rack arrangement, according to the method of
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14. An offshore wind turbine installation vessel comprising a loading deck, a crane and the jack according to
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The present invention relates to the handling of wind turbine blades aboard a vessel, in particular an installation vessel for wind turbines, especially offshore wind turbines.
Long-distance shipping of wind turbine blades typically involves arranging the blades longitudinally inside the hull or transport compartment of a ship. For the purposes of installing wind turbines, especially offshore wind turbines, the main wind turbine elements such as tower, nacelle and blades or rotors are typically loaded aboard an installation vessel equipped with ancillary equipment for turbine erection. Installation vessels typically resemble a floating work platform more than a traditional transport ship. These vessels are generally loaded with turbine elements at a coastal location local to the planned turbine erection site.
Wind turbine blades may be transported aboard vessels such as installation vessels by placing them in racks on a loading surface such as a deck. The blades are typically loaded onto and unloaded from such vessels in a horizontal orientation of the blades. This is because lifting equipment for loading or unloading is typically configured for horizontal handling of the blades. The dimensions of installation vessels are typically such that the blades may extend to some extent beyond side of such vessels. This creates a hazard in the form of a risk of blade dipping in agitated waters or in case the vessel would encounter swell.
One previously suggested rack arrangement for blade stowage aboard a vessel has a capacity for carrying eighteen blades and comprises a fixed root rack and a facing fixed tip rack. Each tip and root rack comprises a set of fixed blade frame portions such that each blade rests substantially horizontally between a pair of blade frame portions effectively comprising a root frame and a corresponding tip frame. Each root or tip rack comprises six side-by-side columns of three blade frames per column. Rows of six frames are arranged in a vertical arrangement with an offset in the longitudinal blade direction at the root rack such that each root frame saddle is vertically clear of the one beneath it. Each tip frame strop can be disengaged from its tip frame to allow loading or unloading of a blade in a lower frame pair. This arrangement allows successive blades to be loaded into in a respective root frame saddle and a corresponding tip frame strop. The blades may thus be placed successively into the fixed frame pairs which make up the rack arrangement. In order to prevent damage arising as a consequence of blades dipping in the water during occasional rolling of an installation vessel, each root and tip rack includes a lower spacer frame fixed to a vessel deck and carrying the respective root or tip rack. This spacer frame ensures a minimum clearance between the stowed blades and the vessel deck, and hence, a minimum clearance between the blades and the water along that portion of the blades which overhangs the side of the transport vessel. This spacer frame arrangement reduces the blade dipping hazard in connection with vessel roll during agitated or rough conditions. A similar rack arrangement including nine pairs of fixed blade frames has also been proposed.
Developments in wind turbine technology have led to ever increasing blade lengths. In order to mitigate for the hazard of blade dipping, the height and overall size of spacer frames has had to increase in order to maintain an appropriate clearance between blade tips and water surface in case of vessel roll. This is very costly in terms of construction material and it wastes already limited space on board the vessel.
The present invention aims to improve blade handling aboard a vessel. In particular, the present invention seeks to improve blade handling and stowage aboard a transport or installation vessel.
An improved method for blade handling aboard a vessel is provided. The method may in particular be carried out aboard an installation vessel. In particular, the method of the invention may comprise providing on a vessel, a blade rack arrangement configured to accommodate more than one blade, the rack arrangement comprising at least a root rack and a tip rack, wherein the root rack and tip rack between them define a blade support plane; and providing a jack acting between the vessel and one of the root or tip rack; and raising or lowering one of the root or tip rack aboard the vessel by means of the jack to thereby move the blade support plane through an elevation angle. The jack may comprise any suitable drive for raising or lowering a heavy bulky load such as a tip or root rack loaded with blades. The jack may preferably be powered. A suitable drive element for a jack may be a hydraulic drive. By raising or lowering a root or tip rack aboard a vessel by means of a jack, to thereby move a blade support plane through an elevation angle, a substantial improvement in the transportation configuration can be achieved using simple means. Increased safety and reduced costs can thereby result, while at the same time preserving the advantages of existing blade loading and unloading arrangements into or out of a blade rack arrangement. The method of the invention may give rise to numerous potential advantages. For example, it ensures that blades may be stowed on board in a different angular orientation than the orientation in which they are loaded or unloaded. It also ensures that a stowage angle of the blades can be selected, according to criteria such as vessel type or expected water, sea or weather conditions. In other words, it can ensure blade stowage optimisation independently of certain blade loading and unloading considerations. The method also enables a maximisation of the use of limited space aboard a vessel, even allowing for transportation of more blades on a given deck space or height. The invention further allows the provision of lower, smaller spacer frame arrangements thereby saving expense.
In an optional, preferred aspect of the invention, the other one of the root or tip rack is substantially not raised or lowered. Accordingly, the invention may encompass raising or lowering a tip rack while maintaining the root rack substantially unmoved in relation to the loading deck. Conversely, the root rack may be raised or lowered while the tip rack is maintained substantially unmoved in relation to the loading deck. In a further optional aspect, the root or tip rack which is maintained unmoved, may preferably be positioned atop a static base frame, supported at a height above a loading deck of said vessel. Accordingly, one effect of raising a moveable one of a tip or root rack in relation to a static base frame at an opposite, facing rack is to cause the tip of any blade supported in the relevant rack arrangement to be raised to a level higher than the height of the static base frame above the loading deck. More particularly, the clearance height between the water surface outboard said vessel and the tip of a blade in a blade rack arrangement aboard said vessel will be greater or significantly greater than the base frame height above the vessel deck. Moreover, since the blade support plane is thereby inclined, the clearance between a blade and the water surface outboard the vessel progressively increases along the blade length to its tip. Advantageously therefore, the present invention may lend itself to the safe handling and transportation of longer blades. Inclination of the blades makes blade length independent from required spacer frame height.
In a further optional aspect, each tip or root rack may be comprised of one or more columns of root or tip frame elements, wherein each such column of may comprise one or more frame element. In particular, each frame element is preferably configured to support a respective root or tip portion of a single blade. Preferably, a root or tip rack comprises multiple stacked frame elements in a column. Still further optionally, each root or tip frame element may be separably connectable to one or more adjacent frame elements in said root or tip column. In embodiments, the frames may be configured to allow secure, separable lateral connection between columns of frame elements. The frame elements are preferably stackable in a modular configuration to create stacked columns of different frame heights depending on the number of blades to be loaded in any rack arrangement. One or more columns of stacked root or tip frames may be described as a root or tip rack. A root or tip rack may thus comprise one or more columns of stacked frames, arranged side by side. A rack arrangement may in particular comprise a tip rack and a facing root rack.
In a further optional aspect, the method may include separably connecting adjacent frame elements by means of fasteners. These may be of any suitable form such as e.g. bolts.
In a further optional aspect, the method may additionally comprise providing a pivot under the other one of said root or tip rack. The provision of this pivot allows a certain rotational movement of the relevant rack during raising or lowering of an opposite, i.e. a facing root or tip rack. This tends to prevent a shift in the angular position of a supported blade portion relative to a frame element in a rack or to any fixtures in which it is supported while a relevant rack is being raised or lowered. Moreover, the relative mutual position of opposing root or tip racks may thereby remain substantially unchanged during raising or lowering of a rack. Preferably, a pivot located at the foot end of a rack may be provided in the form of a tiltable platform on which the root or tipack is supported or fixed. Such a pivot may perform the function of an element more generally known as a skid.
According to a further optional embodiment, the jack may comprise a drive element and a rotatable rack spacer capable of rotating between a lowered support position and a raised support position. A lowered support position of the rotatable rack spacer may in particular correspond to a lowered position of a root or tip rack supported on said spacer. A raised support position of the rotatable rack spacer may in particular correspond to a raised position of a root or tip rack supported on said spacer. A suitable rotatable rack spacer may be directly or indirectly connected both to a linear drive of a jack and directly or indirectly to a root or tip rack. Actuation of a linear drive of a jack may preferably urge the rotatable rack spacer in rotation, thereby changing its orientation in a vertical plane such that a separation between a root or tip rack and a vessel loading deck is thereby correspondingly or proportionally changed. The rotatable spacer may exhibit a locked, lowered support position and/or a locked raised support position. In this context, the term “locked . . . position” may denote a position of the rotatable spacer in which the root or tip rack rests in either a lowered or raised position without additional external assistance. In embodiments, during a raising or lowering action of a root or tip rack, the drive element of a jack may move a driving end thereof though a greater linear distance than the height change of the relevant rack. Preferably, in embodiments the rotatable spacer is positioned between the loading deck of the vessel and a relevant rack.
In embodiments, the elevation angle through which the blade support plane may be moved by the action of the jack is between zero and of at least three degrees, preferably between zero and at least four degrees, still preferably between zero and at least five degrees, still preferably between zero and at least seven degrees, still preferably between zero and at least ten degrees. Preferably, according to aspects of the invention, there may be provided a connecting boom between the root rack and the tip rack. In embodiments, there may optionally be provided more than one boom between a relevant tip and root rack. This option may be preferred where there are multiple columns of root or tip frames arranged side-by-side. The boom may counteract any tendency for the root and tip racks to move together or apart during a raising or lowering action of the jack or following such a raising or lowering action. Preferably such a boom may rotationally connect the jack with a pivotable skid supporting the other one of said root or tip rack, i.e. the relevant rack not being raised or lowered by the action of the jack. Still further, the boom may be configured to cause rotation of the skid or tiltable support platform as a result of an extending or retracting action of the jack beneath an opposite i.e. facing rack.
The invention also encompasses a jack on a wind turbine installation vessel capable of raising or lowering a rack of wind turbine blade root or tip support frame elements according to the defined method, wherein the jack comprises an assembly including a lifting platform driven by a drive device and being positionable at a root or tip rack to be raised or lowered. The jack, or jack assembly is thereby capable of putting into effect the method of the invention, in particular: by raising or lowering a tip or root rack of a blade stowage rack arrangement, the blade support plane may be moved through an elevation angle. A blade stowage rack arrangement and any blades supported therein may thereby in particular be tilted between a blade loading/unloading position and a blade transport position. Blades being transported on an installation vessel comprising a jack arrangement of the invention may thereby be exposed to a reduced risk of dipping.
Optionally, the jack may further comprise a skid positionable beneath a rack which is opposite to i.e. facing the relevant rack on a lifting platform. Such a skid may in particular be a pivot and may be in the form of a tiltable platform. A jack may optionally comprise a pivotable skid in the form of a tiltable platform, rotatably coupled to the lifting platform by a coupling linkage such as a boom. The coupling may in particular help to preserve the relative position of opposing racks during raising or lowering of a jack.
The drive device of a jack may in particular be a linear drive and may be hydraulic such as a hydraulic piston. Alternatively, other linear drive types may be used such as a worm shaft and collar or a pneumatic drive. The drive may be coupled to a rotatable rack spacer or lifting platform. A rack spacer may for example be rotatably coupled to a pivot joint at a root or tip rack and may additionally be rotatably coupled to a linear drive of the jack.
In embodiments, a rotatable rack spacer may be configured to exhibit a raised rack support position and a lowered rack support position. The jack assembly may be configured to rotate the rotatable rack spacer between a raised and a lowered position by means of its linear drive. Optionally, the raising or lowering action of a root or tip rack may be effected by driving a portion of the rotatable rack spacer along a support surface, such as a loading deck of a vessel while another portion of the rotatable rack spacer may be caused to pivot about a pivot joint at a root or tip rack.
It may be beneficial to provide a boom between at least one element of a root rack and at least one element of a tip rack or between platform elements on which they are supported and preferably fixed. This may prevent the tip or root rack being pushed along the blade by a pushing action of the linear drive device during raising of the relevant rack. The boom may also act to generally relieve stresses on the blades during raising or lowering of a relevant rack.
The invention may furthermore comprise an offshore wind turbine installation vessel.
The invention as well as particular aspects thereof is furthermore explained with reference to non-limiting examples shown by way of illustration in the appended drawings.
The term “rack arrangement” is a collective term intended to denote a blade storage construction providing a support structure for wind turbine blades with support elements at or towards the blades' root ends and at or towards their tip ends in the form of a respective, facing root and tip rack. So-called “tip end” support may in particular be provided by means of a tip frame or tip rack at or near a mid-portion of a blade, towards the blade tip. So-called “root end” support may in particular be provided by means of a root frame or root rack at or near a root end of a blade. Preferably, a root end support frame or root rack is provided at the blade root end. A root or tip rack may be unitary or modular although the modular type may be preferred. Each blade may preferably be stored in a frame pair. A root or tip rack may be established by providing one or more frames in a fixed arrangement on a working platform such as on a loading deck of a vessel. The rack arrangement may be progressively loaded with blades by loading blades into successive frame pairs of the rack arrangement. Alternatively, a rack arrangement may be created by successive addition of frame modules to one another aboard a vessel. In such a case, the blades will typically be pre-loaded each in a tip and root pair of single frame elements or several blades in multiple pairs of frame elements. Here the term: “vessel” designates a floating vessel for transportation over water, especially a maritime vessel.
In
The term “loading” may herein include bringing a blade on board optionally with or without a root or a tip frame element. It may optionally further include securing a blade in a respective root or tip frame in a rack arrangement on board. It may further include complementing a root or tip rack on board by addition of one or more frame elements. The term “unloading” may herein include removing a blade from on board optionally including unloading a blade from respective frames on board or optionally by unloading a blade complete with a root or tip frame. The term “blade handling” may include any or all these operations and may additionally include stowing of blades. An installation vessel may refer to a vessel specially adapted for providing a working platform for offshore wind turbine erection and optionally, ancillary equipment therefor such as lifting equipment, e.g. one or more cranes. A loading deck of an installation vessel may refer to any support surface aboard capable of, or suitable for, receiving all or part of a blade rack arrangement, preferably permitting loading or unloading of blades to and from said rack arrangement.
In the present application, the term “blade” is intended to denote that part of a wind turbine rotor which extends from its hub. A reference herein to a blade is not intended to be a reference to a rotor as a whole.
A blade support plane denotes a plane in which the main longitudinal axis of a relevant blade extends and in which the blade is supported in a respective root and tip frame element of a rack in a blade rack. Previously, that plane was a fixed transportation plane. In the present invention, that plane is tiltable.
Also shown in
The exemplary linkage 36 shown in
The linear drive 32 and each displaceable element of the linkage 36, is shown in two positions in
In embodiments, also shown in
In aspects of the invention, the pivot 50 may be rotatably coupled to the jack assembly 30, in particular, to the lifting platform 34. This may be achieved in any suitable manner. In preferred aspects of the invention, the lifting platform 34 may be rotatably coupled to the pivot 50 via a boom 47. In alternative embodiments, a pivot 50 may be associated with a drive mechanism configured to synchronise the tilt angle of the pivot 50 with the movement or position of the lifting platform 34. In preferred embodiments, the rotatable coupling between the lifting platform 34 and the pivot 50 may be capable of driving the rotation of the pivot platform 49 of pivot 50. In embodiments, rotatable coupling between the lifting platform 34 and the pivot 50 may be by means transmission of movement through rotor blades 10 in the respective root or tip racks 2, 3 although this is not preferred.
In the embodiment of
As shown in
The linear drive 32 may be any suitable linear drive device such as a hydraulic piston or worm shaft and collar. Preferably, the linear drive 32 is controlled by a control device (not shown) and may be actuated remotely or automatically or both. Preferably the degree of inclination applied to the blade support plane is infinitely variable. A single column of frames 4, 5 is shown in each root or tip rack 2, 3. In embodiments (not shown) there may be more than one column of frames 4, 5 in each root or tip rack 2, 3. In embodiments, a jack arrangement 32 may be provided for each column of frames or there may be more than one column of frames supported on a single lifting platform 34. In other words, each root or tip rack 2, or 3 may be associated with one or more jacks 30. Similarly, in embodiments, a pivot 50 may be provided for each column of frames in a rack or there may be more than one column of frames supported on a single pivot 50.
A further example of aspects of the invention is illustrated in
According to aspects of the method of the invention, the rack arrangement 1 may thereby be moved between a transport position of the blades 10 and a loading/unloading position of the blades by changing the inclination angle of the blade support plane 18. In preferred embodiments, the angle θ may be infinitely variable and may be adjusted between zero and five degrees. Still preferably, the angle θ may be adjusted between zero and ten degrees. Still further preferably, the angle θ may be adjusted between zero and twenty degrees. In embodiments, the angle θ may be adjustable by between zero and more than 20 degrees.
In
In the illustration
It can be seen from all the
During use, the blades 10 may be loaded onto the vessel 100 for example from a quayside and preferably by means of a crane 120. Generally, when loading or unloading blades 10, these are suspended from a crane 120 with the blade main axis lying in a horizontal plane. The blades 10 may be placed into frames 4, 5 of an existing blade rack arrangement 1 on board a vessel 100 with a root or tip rack 2, 3 of the blade rack arrangement 1 being associated with a jack 30 on the vessel 100. Alternatively, the blades 10 may be transported from a quayside in single or multiple transport frame elements 4, 5 which, when placed on a loading deck 11 of a vessel equipped with a jack 30, make up a respective root and tip rack 2, 3 and thereby constitute a rack arrangement 1. In all cases, at least one rack 2, 3 of a rack arrangement 1 is positioned in relation to a jack 30 such that it may be raised or lowered by the action of the jack 30. The blades 10 are transported by crane 120 and placed in the rack arrangement 1 in a horizontal orientation. Thus, immediately after loading into the rack arrangement 1, each blade initially lies with its main axis in a horizontal support plane defined by the relative arrangement of facing frame elements 4, 5 within each rack arrangement 1. As mentioned previously, a jack 30 may be configured to lift or lower a single column of frames 4, 5 or multiple columns of frames 4, 5 standing side-by-side. Once a relevant blade or relevant group of blades for a shipment is loaded aboard, the jack 30 may be actuated (raised or lowered) to thereby raise or lower a relevant rack 2, 3, moving the blade support plane 18 through an elevation angle θ such that the blade tips are raised. The blade shipment may be transported to an erection site, which may in particular be an offshore site. Alternatively, the blade shipment may be transported by vessel 100 to any desired unloading site. Upon reaching the relevant unloading site, the jack 30 may once again be actuated to move the blade support plane 18 through an elevation angle θ thereby to lower the blade tip clearance height and bring the blade support plane back to the horizontal before commencing unloading the blades 10 from the rack arrangement 1, preferably by means of the crane 120.
The illustrated embodiments constitute examples of aspects of the invention. They are not to scale. The invention is not limited by the illustrated examples.
Botwright, Adrian, Ursell-Smith, Mark, Maroti, Stefan
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