APPARATUS FOR MANUFACTURING COMPOSITE AIRFOILS

Abstract
The present disclosure is directed to an apparatus for manufacturing a composite component. The apparatus includes a mold onto which the composite component is formed. The mold is disposed within a grid defined by a first axis and a second axis. The apparatus further includes a first frame assembly disposed above the mold, and a plurality of printheads coupled to the first frame assembly within the grid in an adjacent arrangement along the first axis. At least one of the mold or the plurality of printheads is moveable along the first axis, the second axis, or both. At least one of the printheads of the plurality of printheads is moveable independently of one another along a third axis.
Description
FIELD

The present disclosure relates in general to methods and apparatuses of manufacturing composite structures. The present disclosure relates more specifically to methods and apparatuses for manufacturing composite airfoils.


BACKGROUND

Wind power is considered one of the cleanest, most environmentally friendly energy sources presently available, and wind turbines have gained increased attention in this regard. A modern wind turbine typically includes a tower, a generator, a gearbox, a nacelle, and one or more rotor blades. The rotor blades capture kinetic energy of wind using known foil principles. The rotor blades transmit the kinetic energy in the form of rotational energy so as to turn a shaft coupling the rotor blades to a gearbox, or if a gearbox is not used, directly to the generator. The generator then converts the mechanical energy to electrical energy that may be deployed to a utility grid.


The rotor blades generally include a suction side shell and a pressure side shell typically formed using molding processes that are bonded together at bond lines along the leading and trailing edges of the blade. Further, the pressure and suction shells are relatively lightweight and have structural properties (e.g., stiffness, buckling resistance and strength) which are not configured to withstand the bending moments and other loads exerted on the rotor blade during operation. Thus, to increase the stiffness, buckling resistance and strength of the rotor blade, the body shell is typically reinforced using one or more structural components (e.g., opposing spar caps with a shear web configured therebetween) that engage the inner pressure and suction side surfaces of the shell halves.


The spar caps are typically constructed of various materials, including but not limited to glass fiber laminate composites and/or carbon fiber laminate composites. The shell of the rotor blade is generally built around the spar caps of the blade by stacking layers of fiber fabrics in a shell mold. The layers are then typically infused together, e.g., with a thermoset resin. Accordingly, conventional rotor blades generally have a sandwich panel configuration. As such, conventional blade manufacturing of large rotor blades involves high labor costs, slow through put, and low utilization of expensive mold tooling. Further, the blade molds can be expensive to customize.


Thus, methods for manufacturing rotor blades may include forming the rotor blades in segments. The blade segments may then be assembled to form the rotor blade. For example, some modern rotor blades, such as those blades described in U.S. patent application Ser. No. 14/753,137 filed Jun. 29, 2015 and entitled “Modular Wind Turbine Rotor Blades and Methods of Assembling Same,” which is incorporated herein by reference in its entirety, have a modular panel configuration. Thus, the various blade components of the modular blade can be constructed of varying materials based on the function and/or location of the blade component.


In view of the foregoing, the art is continually seeking improved methods for manufacturing wind turbine rotor blade panels having printed grid structures.


BRIEF DESCRIPTION

Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.


The present disclosure is directed to an apparatus for manufacturing a composite component. The apparatus includes a mold onto which the composite component is formed, wherein the mold is disposed within a grid defined by a first axis and a second axis. The apparatus also includes a first frame assembly disposed above the mold and a first group of printheads coupled to the first frame assembly within the grid in an adjacent arrangement along the first axis, each of the printheads defining an extruder. The first group of printheads is moveable together along at least one of the first axis and the second axis. The apparatus also includes a mechanism configured to articulate the first group of printheads about the mold and a control unit configured to control the mechanism. The control unit includes at least one processor configured to implement a plurality operations, including but not limited to instructing the first group of printheads to deposit a first volume of fluid composite in a predesigned pattern at a first zone on the mold via the extruders to form a first plurality of printed rows, pausing depositing of the fluid composite, aligning the first group of printheads to a second zone on the mold, and instructing the first group of printheads to deposit a second volume of the fluid composite in the predesigned pattern at the second zone to form a second plurality of printed rows, the first and second plurality of printed rows forming a grid structure, wherein adjacent printed rows in each of the first and second plurality of printed rows comprise side walls that partially overlap each other to define overlapping portions, and wherein the first and second plurality of printed rows of the first and second zones are separated by a gap.


In another aspect, the present disclosure is directed to a composite component. The composite component includes a three-dimensional stabilizing structure and a substantially two-dimensional monolithic panel at least partially enveloping and securing the stabilizing structure. The stabilizing structure includes a patterned architecture formed of a first plurality of printed rows and a second plurality of printed rows secured onto the monolithic panel. Further, adjacent printed rows in each of the first and second plurality of printed rows include side walls that partially overlap each other to define overlapping portions, and wherein the first and second plurality of printed rows of the first and second zones are separated by a gap.


These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.





BRIEF DESCRIPTION OF THE DRAWINGS

A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures, in which:



FIG. 1 illustrates a perspective view of one embodiment of a wind turbine according to an aspect of the present disclosure;



FIG. 2 illustrates a perspective view of one embodiment of a composite component according to an aspect of the present disclosure;



FIG. 3 illustrates an exploded view of the composite component of FIG. 2;



FIG. 4 illustrates a cross-sectional view of one embodiment of a leading edge segment of a composite component according to an aspect of the present disclosure;



FIG. 5 illustrates a cross-sectional view of one embodiment of a trailing edge segment of a composite component according to an aspect of the present disclosure;



FIG. 6 illustrates a cross-sectional view of the composite component of FIG. 2 according to an aspect of the present disclosure along line 6-6;



FIG. 7 illustrates a cross-sectional view of the composite component of FIG. 2 according to an aspect of the present disclosure along line 7-7;



FIG. 8A illustrates a perspective view of one embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 8B illustrates a perspective view of one embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 8C illustrates a perspective view of one embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 8D illustrates a perspective view of the embodiment generally provided in FIG. 8C in an open position of the apparatus for manufacturing a composite component;



FIG. 8E illustrates a side view of a portion of an embodiment of the apparatus generally provided in regard to FIGS. 8A-8F;



FIG. 8F illustrates a perspective view of the embodiments of the apparatus generally provided in FIGS. 8C and 8D further depicting additional embodiments of the apparatus;



FIG. 9A illustrates a perspective view of another embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 9B illustrates a perspective view of another embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7



FIG. 10 illustrates a cross-sectional view of one embodiment of a mold of a composite component, particularly illustrating an outer skin placed in the mold with a plurality of grid structures printed thereto;



FIG. 11 illustrates a perspective view of one embodiment of a grid structure according to an aspect of the present disclosure;



FIG. 12 illustrates a perspective view of one embodiment of a mold of a composite component with an apparatus for manufacturing the composite component positioned above the mold so as to print a grid structure thereto according to an aspect of the present disclosure;



FIG. 13 illustrates a perspective view of one embodiment of a mold of a composite component with an apparatus for manufacturing a composite component positioned above the mold and printing an outline of a grid structure thereto according to an aspect of the present disclosure;



FIG. 14 illustrates a perspective view of one embodiment of a mold of a composite component with an apparatus for manufacturing a composite component positioned above the mold and printing an outline of a grid structure thereto according to an aspect of the present disclosure;



FIG. 15 illustrates a cross-sectional view of one embodiment of a first rib member of a grid structure according to an aspect of the present disclosure;



FIG. 16 illustrates a cross-sectional view of another embodiment of a first rib member of a grid structure according to an aspect of the present disclosure;



FIG. 17 illustrates a top view of one embodiment of a grid structure according to an aspect of the present disclosure;



FIG. 18 illustrates a cross-sectional view of one embodiment of a first rib member and intersecting second rib members of a grid structure according to an aspect of the present disclosure;



FIG. 19 illustrates a cross-sectional view of one embodiment of a second rib member of a grid structure according to an aspect of the present disclosure;



FIG. 20 illustrates a top view of one embodiment of a grid structure according to an aspect of the present disclosure, particularly illustrating rib members of the grid structure arranged in a random pattern;



FIG. 21 illustrates a perspective view of another embodiment of a grid structure according to an aspect of the present disclosure, particularly illustrating rib members of the grid structure arranged in a random pattern;



FIG. 22 illustrates a graph of one embodiment of buckling load factor (y-axis) versus weight ratio (x-axis) of a grid structure according to an aspect of the present disclosure;



FIG. 23 illustrates a partial, top view of one embodiment of a printed grid structure according to an aspect of the present disclosure, particularly illustrating a node of the grid structure;



FIG. 24 illustrates a partial, top view of one embodiment of a printed grid structure according to an aspect of the present disclosure, particularly illustrating a start printing location and an end printing location of the grid structure;



FIG. 25 illustrates an elevation view of one embodiment of a printed rib member of a grid structure according to an aspect of the present disclosure, particularly illustrating a base section of one of the rib members of the grid structure having a wider and thinner cross-section than the remainder of the rib member so as to improve bonding of the grid structure to the outer skins of the composite component;



FIG. 26 illustrates a top view of another embodiment of a grid structure according to an aspect of the present disclosure, particularly illustrating additional features printed to the grid structure;



FIG. 27 illustrates a cross-sectional view of one embodiment of a composite component having a printed grid structure arranged therein according to an aspect of the present disclosure, particularly illustrating alignment features printed to the grid structure for receiving the spar caps and shear web;



FIG. 28 illustrates a partial, cross-sectional view of the composite component of FIG. 25, particularly illustrating additional features printed to the grid structure for controlling adhesive squeeze out;



FIG. 29 illustrates a cross-sectional view of one embodiment of a composite component having printed grid structures arranged therein according to an aspect of the present disclosure, particularly illustrating male and female panel alignment features printed to the grid structure;



FIG. 30 illustrates a top view of yet another embodiment of a grid structure according to an aspect of the present disclosure, particularly illustrating auxiliary features printed to the grid structure;



FIG. 31 illustrates a cross-sectional view of one embodiment of a composite component according to an aspect of the present disclosure, particularly illustrating a plurality of grid structures printed to inner surfaces of the rotor blade panel;



FIG. 32 illustrates a partial, cross-sectional view of the leading edge of the composite component of FIG. 29, particularly illustrating a plurality of adhesive gaps;



FIG. 33A illustrates a perspective view of another embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 33B illustrates a perspective view of still another embodiment of an apparatus for manufacturing a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIG. 34 illustrates various steps in which the apparatus of FIG. 34 is used to additively manufacture a composite component, such as the composite component generally illustrated in FIGS. 2-7;



FIGS. 35-38 illustrate various tops view of multiple embodiments of a grid structure design as printed by an apparatus for manufacturing a composite component according to the present disclosure;



FIG. 39 illustrates a partial, perspective view of one embodiment of a composite component according to the present disclosure;



FIG. 40 illustrates a top view of another embodiment of a grid structure design as printed by an apparatus for manufacturing a composite component according to the present disclosure, particularly illustrating the height, overlap, thickness, width, and length of the grid structure;



FIG. 41 illustrates a perspective view of one embodiment of a blade tip forming using the manufacturing methods described herein according to the present disclosure, particularly illustrating a grid structure formed of a plurality of grid structure segments each separated by a spanwise gap;



FIG. 42 illustrates a top view of one embodiment of a grid structure design according to the present disclosure, particularly illustrating a grid design having both spanwise and chordwise gaps;



FIGS. 43A and 43B illustrate top views of one embodiment of an apparatus for manufacturing a composite component according to the present disclosure, particularly illustrating an apparatus having a plurality of groups of separated printheads configured to print different zones of a grid structure;



FIGS. 44A, 44B, and 44C illustrates various views of one embodiment of a structural member provided on an inner surface of the outer skin(s) according to the present disclosure;



FIGS. 45-48 illustrate various tops view of still additional embodiments of a grid structure design as printed by an apparatus for manufacturing a composite component according to the present disclosure;



FIGS. 49A and 49B illustrate various tops view of multiple embodiments of a stacked-cup design of a grid structure as printed by an apparatus for manufacturing a composite component according to the present disclosure;



FIG. 50 illustrates a top view of a grid structure design as printed by an apparatus for manufacturing a composite component according to the present disclosure;



FIG. 51 illustrates a cross-sectional view of a composite component according to the present disclosure, particularly illustrating a scarf joint at an angle between two printed zones of a grid structure;



FIG. 52 illustrates a top view of the composite component of FIG. 49, particularly illustrating structural plates arranged at the scarf joint for reinforcement; and



FIG. 53 illustrates a side view of a printhead printing a composite component according to the present disclosure, particularly illustrating a scarf joint at a 45-degree angle between two printed zones of a grid structure.





DETAILED DESCRIPTION

Reference now will be made in detail to embodiments of the present disclosure, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.


Generally, the present disclosure is directed to an apparatus and method for manufacturing a composite component, including structures thereof, using automated deposition of materials via technologies such as 3-D Printing, additive manufacturing, automated fiber deposition or tape deposition, as well as other techniques that utilize CNC control and multiple degrees of freedom to deposit material. The apparatus generally includes a mold onto which the composite component is formed. The mold is disposed within a grid defined by a first axis and a second axis generally perpendicular to the first axis. A plurality of printheads is disposed within the grid in adjacent arrangement along the first axis. The plurality of printheads is coupled to a first frame assembly. The mold, the plurality of printheads, or both, is moveable along the first axis and the second axis. Each machine head of the plurality of printheads is moveable independently of one another along a third axis.


The embodiments of the apparatus and method shown and described herein may improve manufacturing cycle time efficiency, such as by enabling a relatively simple zig-zag, sinusoidal, or orthogonal motion to deposit composite component structures, such as onto a rotor blade panel formed onto a mold. Thus, the methods described herein provide many advantages not present in the prior art. For example, the methods of the present disclosure may provide the ability to easily customize composite component structures having various curvatures, aerodynamic characteristics, strengths, stiffness, etc. For example, the printed or formed structures of the present disclosure can be designed to match the stiffness and/or buckling resistance of existing sandwich panels for composite components. More specifically, composite components defining the exemplary rotor blades and components thereof generally provided in the present disclosure can be more easily customized based on the local buckling resistance needed. Still further advantages include the ability to locally and temporarily buckle to reduce loads and/or tune the resonant frequency of the rotor blades to avoid problem frequencies. Moreover, the structures described herein enable bend-twist coupling of the composite component, such as defining a rotor blade. Furthermore, improved methods of manufacturing, and improve manufacturing cycle time associated therewith, for the improved customized composite component structures may thereby enable cost-efficient production and availability of composite components, including, but not limited to, rotor blades described herein, such as through a higher level of automation, faster throughput, and reduced tooling costs and/or higher tooling utilization. Further, the composite components of the present disclosure may not require adhesives, especially those produced with thermoplastic materials, thereby eliminating cost, quality issues, and extra weight associated with bond paste.


Referring now to the drawings, FIG. 1 illustrates one embodiment of a wind turbine 10 according to the present disclosure. As shown, the wind turbine 10 includes a tower 12 with a nacelle 14 mounted thereon. A plurality of rotor blades 16 are mounted to a rotor hub 18, which is in turn connected to a main flange that turns a main rotor shaft. The wind turbine power generation and control components are housed within the nacelle 14. The view of FIG. 1 is provided for illustrative purposes only to place the present invention in an exemplary field of use. It should be appreciated that the invention is not limited to wind turbines or any particular type of wind turbine configuration. In addition, the present invention is not limited to use with wind turbines, but may be utilized in producing any composite component, such as any application having rotor blades. Further, the methods described herein may also apply to manufacturing any composite component that benefits from printing or laying a structure to a mold. Still further, the methods described herein may further apply to manufacturing any composite component that benefits from printing or laying a structure onto a skin placed onto a mold, which may include, but is not limited to, before the skins have cooled so as to take advantage of the heat from the skins to provide adequate bonding between the printed structure and the skins. As such, the need for additional adhesive or additional curing is eliminated.


Referring now to FIGS. 2 and 3, various views of an exemplary composite component that may be produced by the structures, apparatuses, and methods generally provided herein according to the present disclosure are illustrated. More specifically, an exemplary embodiment of a composite component defining a rotor blade 16 is generally provided. As shown, the illustrated rotor blade 16 has a segmented or modular configuration. It should also be understood that the rotor blade 16 may include any other suitable configuration now known or later developed in the art. As shown, the modular rotor blade 16 includes a main blade structure 15 constructed, at least in part, from a thermoset and/or a thermoplastic material and at least one blade segment 21 configured with the main blade structure 15. More specifically, as shown, the rotor blade 16 includes a plurality of blade segments 21. The blade segment(s) 21 may also be constructed, at least in part, from a thermoset and/or a thermoplastic material.


The thermoplastic rotor blade components and/or materials as described herein generally encompass a plastic material or polymer that is reversible in nature. For example, thermoplastic materials typically become pliable or moldable when heated to a certain temperature and returns to a more rigid state upon cooling. Further, thermoplastic materials may include amorphous thermoplastic materials and/or semi-crystalline thermoplastic materials. For example, some amorphous thermoplastic materials may generally include, but are not limited to, styrenes, vinyls, cellulosics, polyesters, acrylics, polysulphones, and/or imides. More specifically, exemplary amorphous thermoplastic materials may include polystyrene, acrylonitrile butadiene styrene (ABS), polymethyl methacrylate (PMMA), glycolised polyethylene terephthalate (PETG), polycarbonate, polyvinyl acetate, amorphous polyamide, polyvinyl chlorides (PVC), polyvinylidene chloride, polyurethane, or any other suitable amorphous thermoplastic material. In addition, exemplary semi-crystalline thermoplastic materials may generally include, but are not limited to polyolefins, polyamides, fluropolymer, ethyl-methyl acrylate, polyesters, polycarbonates, and/or acetals. More specifically, exemplary semi-crystalline thermoplastic materials may include polybutylene terephthalate (PBT), polyethylene terephthalate (PET), polypropylene, polyphenyl sulfide, polyethylene, polyamide (nylon), polyetherketone, or any other suitable semi-crystalline thermoplastic material.


In addition, certain thermoplastic resins provided herein, such as PMMA and polyamides, for example, can be impregnated into structural fabrics via infusion via VARTM or other suitable infusion methods known in the art. One example of an infusible PMMA based resin system may be Elium® from Arkema Corporation. In such embodiments, infusible thermoplastics can be infused into fabrics/fiber materials as a low viscosity mixture of resin(s) and catalyst. Thus, upon curing, infusible thermoplastic resins form a thermoplastic matrix in situ to make a fiber-reinforced composite. The resulting thermoplastic-based composite is thermally reversible, unlike thermoset resins. An advantage of using infusible thermoplastics over other methods of making thermoplastic fiber reinforced laminates is the reduction in capital equipment needed for methods that require large presses to manufacture large scale laminates needed to be applicable to many wind blade components. In still another embodiment, the skins described herein may be formed of a thermoplastic prepreg that requires b-staging with a catalyst, heat, or light to complete the polymerization.


Further, the thermoset components and/or materials as described herein generally encompass a plastic material or polymer that is non-reversible in nature. For example, thermoset materials, once cured, cannot be easily remolded or returned to a liquid state. As such, after initial forming, thermoset materials are generally resistant to heat, corrosion, and/or creep. Example thermoset materials may generally include, but are not limited to, some polyesters, some polyurethanes, esters, epoxies, or any other suitable thermoset material.


In addition, as mentioned, the thermoplastic and/or the thermoset material as described herein may optionally be reinforced with a fiber material, including but not limited to glass fibers, carbon fibers, polymer fibers, wood fibers, bamboo fibers, ceramic fibers, nanofibers, metal fibers, basalt fibers, or similar or combinations thereof. In addition, the direction of the fibers may include multi-axial, unidirectional, biaxial, triaxial, or any other another suitable direction and/or combinations thereof. Further, the fiber content may vary depending on the stiffness required in the corresponding blade component, the region or location of the blade component in the rotor blade 16, and/or the desired weldability of the component.


More specifically, as shown, the main blade structure 15 may include any one of or a combination of the following: a pre-formed blade root section 20, a pre-formed blade tip section 22, one or more one or more continuous spar caps 48, 50, 51, 53, one or more shear webs 35 (FIGS. 6-7), an additional structural component 52 secured to the blade root section 20, and/or any other suitable structural component of the rotor blade 16. Further, the blade root section 20 is configured to be mounted or otherwise secured to the rotor 18 (FIG. 1). In addition, as shown in FIG. 2, the rotor blade 16 defines a length or span 23 that is equal to the total length between the blade root section 20 and the blade tip section 22. As shown in FIGS. 2 and 6, the rotor blade 16 also defines a width or chord 25 that is equal to the total length between a leading edge 24 of the rotor blade 16 and a trailing edge 26 of the rotor blade 16. As is generally understood, the width or chord 25 may generally vary in length with respect to the length or span 23 as the rotor blade 16 extends from the blade root section 20 to the blade tip section 22.


Referring particularly to FIGS. 2-4, any number of blade segments 21 or panels having any suitable size and/or shape may be generally arranged between the blade root section 20 and the blade tip section 22 along a longitudinal axis 27 in a generally span-wise direction. Thus, the blade segments 21 generally serve as the outer casing/covering of the rotor blade 16 and may define a substantially aerodynamic profile, such as by defining a symmetrical or cambered airfoil-shaped cross-section. In additional embodiments, it should be understood that the blade segment portion of the blade 16 may include any combination of the segments described herein and are not limited to the embodiment as depicted. In addition, the blade segments 21 may be constructed of any suitable materials, including but not limited to a thermoset material or a thermoplastic material optionally reinforced with one or more fiber materials. More specifically, in certain embodiments, the blade panels 21 may include any one of or combination of the following: pressure and/or suction side segments 44, 46, (FIGS. 2 and 3), leading and/or trailing edge segments 40, 42 (FIGS. 2-6), a non-jointed segment, a single-jointed segment, a multi jointed blade segment, a J-shaped blade segment, or similar.


More specifically, as shown in FIG. 4, the leading edge segments 40 may have a forward pressure side surface 28 and a forward suction side surface 30. Similarly, as shown in FIG. 5, each of the trailing edge segments 42 may have an aft pressure side surface 32 and an aft suction side surface 34. Thus, the forward pressure side surface 28 of the leading edge segment 40 and the aft pressure side surface 32 of the trailing edge segment 42 generally define a pressure side surface of the rotor blade 16. Similarly, the forward suction side surface 30 of the leading edge segment 40 and the aft suction side surface 34 of the trailing edge segment 42 generally define a suction side surface of the rotor blade 16. In addition, as particularly shown in FIG. 6, the leading edge segment(s) 40 and the trailing edge segment(s) 42 may be joined at a pressure side seam 36 and a suction side seam 38. For example, the blade segments 40, 42 may be configured to overlap at the pressure side seam 36 and/or the suction side seam 38. Further, as shown in FIG. 2, adjacent blade segments 21 may be configured to overlap at a seam 54. Thus, where the blade segments 21 are constructed at least partially of a thermoplastic material, adjacent blade segments 21 can be welded together along the seams 36, 38, 54, which will be discussed in more detail herein. Alternatively, in certain embodiments, the various segments of the rotor blade 16 may be secured together via an adhesive (or mechanical fasteners) configured between the overlapping leading and trailing edge segments 40, 42 and/or the overlapping adjacent leading or trailing edge segments 40, 42.


In specific embodiments, as shown in FIGS. 2-3 and 6-7, the blade root section 20 may include one or more longitudinally extending spar caps 48, 50 infused therewith. For example, the blade root section 20 may be configured according to U.S. application Ser. No. 14/753,155 filed Jun. 29, 2015 entitled “Blade Root Section for a Modular Rotor Blade and Method of Manufacturing Same” which is incorporated herein by reference in its entirety.


Similarly, the blade tip section 22 may include one or more longitudinally extending spar caps 51, 53 infused therewith. More specifically, as shown, the spar caps 48, 50, 51, 53 may be configured to be engaged against opposing inner surfaces of the blade segments 21 of the rotor blade 16. Further, the blade root spar caps 48, 50 may be configured to align with the blade tip spar caps 51, 53. Thus, the spar caps 48, 50, 51, 53 may generally be designed to control the bending stresses and/or other loads acting on the rotor blade 16 in a generally span-wise direction (a direction parallel to the length or span 23 of the rotor blade 16) during operation of a wind turbine 10. In addition, the spar caps 48, 50, 51, 53 may be designed to withstand the span-wise compression occurring during operation of the wind turbine 10. Further, the spar cap(s) 48, 50, 51, 53 may be configured to extend from the blade root section 20 to the blade tip section 22 or a portion thereof. Thus, in certain embodiments, the blade root section 20 and the blade tip section 22 may be joined together via their respective spar caps 48, 50, 51, 53.


In addition, the spar caps 48, 50, 51, 53 may be constructed of any suitable materials, e.g., a thermoplastic or thermoset material or combinations thereof. Further, the spar caps 48, 50, 51, 53 may be pultruded from thermoplastic or thermoset resins. As used herein, the terms “pultruded,” “pultrusions,” or similar generally encompass reinforced materials (e.g., fibers or woven or braided strands) that are impregnated with a resin and pulled through a stationary die such that the resin cures, solidifies, or undergoes polymerization. As such, the process of manufacturing pultruded members is typically characterized by a continuous process of composite materials that produces composite parts having a constant cross-section. Thus, the pre-cured composite materials may include pultrusions constructed of reinforced thermoset or thermoplastic materials. Further, the spar caps 48, 50, 51, 53 may be formed of the same pre-cured composites or different pre-cured composites. In addition, the pultruded components may be produced from rovings, which generally encompass long and narrow bundles of fibers that are not combined until joined by a cured resin.


Referring to FIGS. 6-7, one or more shear webs 35 may be configured between the one or more spar caps 48, 50, 51, 53. More particularly, the shear web(s) 35 may be configured to increase the rigidity in the blade root section 20 and/or the blade tip section 22. Further, the shear web(s) 35 may be configured to close out the blade root section 20.


In addition, as shown in FIGS. 2 and 3, the additional structural component 52 may be secured to the blade root section 20 and extend in a generally span-wise direction so as to provide further support to the rotor blade 16. For example, the structural component 52 may be configured according to U.S. application Ser. No. 14/753,150 filed Jun. 29, 2015 entitled “Structural Component for a Modular Rotor Blade” which is incorporated herein by reference in its entirety. More specifically, the structural component 52 may extend any suitable distance between the blade root section 20 and the blade tip section 22. Thus, the structural component 52 is configured to provide additional structural support for the rotor blade 16 as well as an optional mounting structure for the various blade segments 21 as described herein. For example, in certain embodiments, the structural component 52 may be secured to the blade root section 20 and may extend a predetermined span-wise distance such that the leading and/or trailing edge segments 40, 42 can be mounted thereto.


Referring now to FIGS. 8A-8F and FIGS. 9A-9B, the present disclosure is directed to embodiments of an apparatus 200 and methods of manufacturing composite components 210, such as rotor blade panels 21 having at least one printed reinforcement grid structure 62 formed via 3-D printing (e.g., blade segments illustrated in regard to FIGS. 2-7). As such, in certain embodiments, the composite component 210 may include the rotor blade panel 21 further including a pressure side surface, a suction side surface, a trailing edge segment, a leading edge segment, or combinations thereof 3-D printing, as used herein, is generally understood to encompass processes used to synthesize three-dimensional objects in which successive layers of material are formed under computer control to create the objects. As such, composite components 210 of almost any size and/or shape can be produced from digital model data. It should further be understood that the methods of the present disclosure are not limited to 3-D printing, but rather, may also encompass more than three degrees of freedom such that the printing techniques are not limited to printing stacked two-dimensional layers, but are also capable of printing curved shapes.


Referring now to FIGS. 8A-8F, an apparatus 200 for manufacturing a composite component 205 is generally provided. The composite component 210 may generally define all or part of the rotor blade 16 or rotor blade panel 21 such as described in regard to FIGS. 2-7. The apparatus 200 includes a mold 58 onto which the composite component 210 is formed. The mold 58 is disposed within a grid 205 defined by a first axis 201 and a second axis 202 generally perpendicular to the first axis 201. A plurality of printheads 220 disposed within the grid 205 in adjacent arrangement along the first axis 201 or the second axis 202. The plurality of printheads 220 is coupled to a first frame assembly 230 above the mold 58. The mold 58, the plurality of printheads 220, or both, is moveable along the first axis 201 and the second axis 202. Each machine head 225 of the plurality of printheads 220 is moveable independently of one another along a third axis 203.


In the embodiment generally provided in FIGS. 8A and 8B, each machine head 225 of the plurality of printheads 220 is disposed in an adjacent arrangement along the first axis 201. The first axis 201 may generally correspond to at least a length or span 23 (FIG. 2) of the composite component 210, such as embodiments of the rotor blade 16 or rotor blade panel 21 described in regard to FIGS. 2-7. For example, the first axis 201 may be substantially parallel to the span 23 (FIG. 2) of the rotor blade panel 21. In one embodiment, the first axis 201 is approximately parallel, plus or minus 10% of the first axis 201. In another embodiment, the first axis 201 is substantially parallel with the trailing edge of the main portion of the spar cap.


The second axis 202 may generally correspond to at least a width or chord 25 (FIG. 2) of the composite component 210, such as embodiments of the rotor blade 16 or rotor blade panel 21 described in regard to FIGS. 2-7. For example, the second axis 202 may be substantially parallel to the width or chord 25 (FIG. 2) of the rotor blade panel 21. The width or chord 25 of the composite component 210 is generally perpendicular to the length or span 23 of the composite component 210. In one embodiment, the second axis 202 is approximately parallel, plus or minus 10% of the second axis 202.


In various embodiments, the first frame assembly 230 may generally define a gantry system such as to articulate the plurality of printheads 220 along the first axis 201 and the second axis 202. In various embodiments, the plurality of printheads 220 defines a front head 221 and a rear head 222 along the first axis 201. In one embodiment, the plurality of printheads 220 is arranged along the first axis 201 at least approximately 50% or greater of the length 23 of the composite component 210 to be formed by the apparatus 200. In still other embodiments, the plurality of printheads 220 is arranged along the first axis 201 at least approximately 70% or greater of the length 23 of the composite component 210 to be formed by the apparatus 200. In still yet other embodiments, the plurality of printheads 220 is arranged along the first axis 201 at least approximately 100% or greater of the length 23 of the composite component 210 to be formed by the apparatus 200. In various embodiments (e.g., FIG. 8A), the plurality of printheads 220 may extend at least the entire length or span 23, or greater, of the mold 58 or composite component 210 to be formed.


In the embodiment generally provided in FIGS. 8A through 8D, at least the mold 58 or the plurality of printheads 220 is moveable to dispose (e.g., position, place, or arrange) at least the front head 221 along the first axis 201 beyond the length or span 23 of the composite component 210 along a first direction 211. Furthermore, the mold 58, the plurality of printheads 220, or both, is moveable to dispose at least the rear head 222 along the first axis 201 beyond the length or span 23 (FIG. 2) of the composite component 210 (e.g., defining the rotor blade panel 21) along a second direction 212 opposite of the first direction 211.


Referring now to the embodiment generally provided in FIG. 8B, at least a portion of the first frame assembly 230 may be moveable along the second axis 202 greater than the width or chord 25 of the composite component 210, such as defining the rotor blade panel 21. For example, the plurality of printheads 220 may be moveable greater than the width or chord 25 of a first composite component 213. The plurality of printheads 220 may be disposed over a second composite component 214 disposed adjacent to the first composite component 213 along the second axis 202. As such, the apparatus 200 may enable the plurality of printheads 220 to proceed to print and deposit one or more rib structures 64 (FIGS. 10-32) the second composite component 214 while the rib structures 64 at first composite component 213 solidify or cure upon the outer skin 56. The outer skin 56 described herein may be formed using a variety of manufacturing methods. In various embodiments, a second frame 232 of the first frame assembly 230 is moveable to place, position, or otherwise dispose the plurality of printheads 220 at least equal to or greater than the width or chord 25 of the composite component 210.


Referring now to the embodiment generally provided in FIG. 8B, the first frame assembly 230 may further define a supporting member 236 extended along the second axis 202. The supporting member 236 may generally define a portion of the first frame assembly 230 such as to provide structural support to the plurality of printheads 220. For example, the supporting member 236 may mitigate curvature or sagging of the plurality of printheads 220 across the spanwise adjacent arrangement. The supporting member 236 may generally partition the plurality of printheads 236 into a plurality of the plurality of printheads 236, such as each are supported to a separate or independently moveable second frame 232, such as further described below.


Referring now to FIGS. 8A-8E, the first frame assembly 230 may include a first frame 231 movable along the first axis 201 and a second frame 232 coupled to the first frame 231. The first frame 231 may generally be coupled to a base frame 235 permitting articulation or movement along the first axis 201. The base frame 235 may generally define a rail assembly, track structure, glide, automated guide vehicle (AGV), or other configuration enabling the first frame 231 to move along the first axis 201. In the embodiment generally provided in FIG. 8A, the plurality of printheads 220 is moveably coupled to the second frame 232 such that the plurality of printheads 220 is moveable generally in unison along the first axis 201, the second axis 202, or both. As described in regard to FIG. 8B, the second frame 232 may be moveable along the second axis 202 such as to place, position, arrange, or otherwise dispose the plurality of printheads 220 at least along the entire width or chord 25 of the composite component 210. Still further, the second frame 232 may be moveable along the second axis 202 such as to dispose the plurality of printheads 220 proximate to the second composite component 214 (e.g., vertically over the second composite component 214 along the third axis 203).


The second frame 231 further enables movement of at least one machine head 225 along the third axis 203 independent of another machine head 225. The third axis 203 generally corresponds to a vertical distance over the grid 205. More specifically, the third axis 203 corresponds to a vertical distance over the rotor blade panel 21. As such, each machine head 225 of the plurality of printheads 220 is moveable independently of one another along the third axis 203 to independently define a vertical distance over the grid 205, or more specifically, the rotor blade panel 21.


Referring now to the embodiments generally provided in FIGS. 8C and 8D, a plurality of the first frame 231 may be disposed on the base frame 235. Each first frame 231 may be independently moveable on the base frame 235. For example, each first frame 231 may be independently moveable along the first axis 201. In various embodiments, each first frame 231 may be independently moveable along the first axis 201 in opposite directions (e.g., one or more first frames 231 toward the first direction 211 and another or more first frames 231 toward the second direction 212).


As another example, in reference to the embodiment generally provided in FIGS. 8C and 8D, the first frame 231 may further displace along the first axis 201 such as to provide vertical clearance along the third axis 203 relative to one or more of the composite components 210. In various embodiments, the first frame assembly 230 defines a plurality of the first frame 231 to which one or more of the second frame 232 is attached to each of the first frame 231. For example, referring to FIG. 8C, one of the first frame 231a may translate or move along the first axis 201 on the base frame 235 to position the plurality of printheads 220 and the first frame 231a away from one or more of the composite components 210, such as generally depicted at the first frame 231b in FIG. 8D.


For example, the first frame assembly 230 may displace, translate, or otherwise move to apply the outer skin 56 onto the mold 58, and for removing the composite component 210 such as the rotor blade panel 21 from the mold 58 at least partially along the third axis 203. As another example, one or more of the first frame 231 of the first frame assembly 230, such as the first frame 231a depicted in FIG. 8C, may translate such as depicted at the first frame 231b in FIG. 8D, to enable movement of another first frame 231, such as depicted at 231c in FIG. 8D, to translate along the first axis 201. In various embodiments, the plurality of printheads 220 at one of more of the first frame 231 (e.g., 231a, 231b, 231c) may define varying combinations of printheads 225 such that one first frame 231 (e.g., 231c) may translate over one or more molds 58 to perform a function specific to one first frame 231 in contrast to another first frame 231 (e.g., 231a, 231b). Referring now to FIGS. 9A and 9B, further exemplary embodiments of the apparatus 200 are generally provided. The embodiments generally provided in FIGS. 9A and 9B may be configured substantially similarly as shown and described in regard to FIGS. 8A, 8B, 8C, and 8D. In the embodiments generally provided in FIGS. 9A and 9B, the first axis 201 may generally correspond to a width or chord 25 (FIG. 2) of composite component 210 and the second axis 202 may generally correspond to a length or span 23 (FIG. 2) of the composite component 210. For example, in various embodiments, the first axis 201 is substantially parallel to at least a width or chord 25 (FIG. 2) of the rotor blade panel 21. The second axis 202 is substantially parallel to at least a length or span 23 (FIG. 2) of the rotor blade panel 21. In one embodiment, the mold 58, the plurality of printheads 220, or both, is moveable to dispose at least the front head 221 along the first axis 201 greater than the width or chord 25 of the rotor blade panel 21 along the first direction 211.


In the embodiment generally provided in FIGS. 9A and 9B, the mold 58, the plurality of printheads 220, or both, is moveable to dispose at least the rear head 222 along the first axis 201 beyond the width or chord 25 (FIG. 2) of the rotor blade panel 21 along a second direction 212. As such, the plurality of printheads 220 occupies at least the entire length or span 23 of the rotor blade panel 21 to deposit materials for one or more structures of the rotor blade panel 21 such as described in regard to FIGS. 2-7. Still further, the plurality of printheads 220 is moveable to provide vertical clearance over the mold 58, the rotor blade panel 21, or both to enable access to the mold 58 and/or the rotor blade panel 21 from at least partially along the third axis 203.


Referring still to the exemplary embodiments generally provided in FIGS. 8A, 8B, 8C, 8D, 8E, 9A, and 9B, the apparatus 200 may further define a fourth axis 204. The fourth axis 204 is generally defined at the plurality of printheads 220. For example, referring more specifically to the embodiment generally provided in FIG. 8E, the fourth axis 204 is generally defined by the axis upon which the plurality of printheads 220 is arranged (e.g., the first axis 201 shown in FIGS. 8A-8D) and a vertical distance along the third axis 203. The fourth axis 204 generally defines an axis about which one or more of the printheads 225 may rotate or pivot independently of one another. For example, each machine head 225 generally defines a working end 227 proximate to the composite component 210 (e.g., a grid structure 62 of the rotor blade panel 21). The plurality of printheads 220 is configured to dispose the working end 227 of one or more of the printheads 225 at an angle 228 relative to the grid 205, the mold 58, or both.


In various embodiments, the apparatus 200, such as at the second frame 232, at the plurality of printheads 220, or both, is configured to move or pivot along the fourth axis 204 to dispose the working end 227 of one or more printheads 225 at an angle relative to the grid 205 between approximately 0 degrees and approximately 175 degrees.


Referring still to FIG. 8E, in another embodiment, the apparatus 200 may further define a fifth axis 206 around which one or more of the printheads 225 may rotate. The fifth axis 206 is generally defined perpendicular to the fourth axis 204 and the second axis 202. The fifth axis 206 is further generally defined through each machine head 225 such as to define a machine head centerline axis, such as generally depicted in FIG. 8A. In one embodiment, the machine head 225 may rotate approximately 360 degrees around the fifth axis 206. More specifically, the working end 227 of each machine head 225 may rotate approximately 360 degrees around the fifth axis 206.


Referring back to FIG. 8A, each machine head 225 may define the machine head centerline axis 226 at least partially along third axis 203. Each adjacent pair of centerline axes 226, 226a may define a distance 224 corresponding to a desired spacing of a structure of the composite component 210 to be formed onto the mold 58, such as a desired cell size of the grid structure 62. In various embodiments, the center to center distance 224 of each machine head 225 may generally correspond to a desired spacing or multiple of the desired spacing of a desired rib member 64 (FIG. 17) to be formed by the apparatus 200, such as further described herein. More specifically, in various embodiments, the center to center distance 224 of each pair of printheads 225 may generally correspond to a spacing or distance 97 of the grid structure 62 (FIG. 17).


For fastest cycle time with a single row of printheads, the desirable center to center spacing 224 would correspond to the grid cell size. In one embodiment, a single printhead 220 can trace the grid pattern corresponding to one row (in this case, 280 mm spanwise cell spacing during a motion from one side of the chord and back to the other side of the chord). In cases where tighter cell spacing is required, cell spacing is ideally defined as evenly divisible into the spacing. For an embodiment using 280 mm spacing, spanwise cell spacing is ideally 280 mm or 140 mm or 70 mm, etc. For 280 mm spacing with 280 mm spaced printheads 220, the apparatus 200 only has to travel across the chord (i.e., across the chord of the desired grid design within the blade shape) one time to make the pattern. For 140 mm spacing, the apparatus 200 has to travel across the chord one time and then come back one time. For 70 mm spacing, the apparatus 200 has to travel across the chord a total of four times. It should be understood that the aforementioned printer paths are provided as examples only and are not meant to be limiting. Rather, the present disclosure is meant to encompass additional pathways for printing the grid structures 62 in addition to those specifically described herein.


Another benefit to having a single row of printheads 220 that span substantially the entire length of the span is that the apparatus 200 provides optimal production cycle time as all printed grid structures can be completed in one continuous zone, unless the apparatus separates the grid into multiple zones as described herein.


For example, the spacing or distance 97 of the grid structure 62 may correspond to a spacing or distance between each pair of rib members 64 along a first direction 76 or second direction 78. Still further, the spacing or distance 97 of the rib members 64 may refer to a spacing or distance between each pair of first rib members 66 or second rib members 68. As another example, each structure of the composite component 210 to be formed may define a dimension X of length or width (e.g., spacing or distance 97 shown in FIG. 17). The desired center to center spacing (i.e., the distance 224) of each adjacent pair of printheads 225 may be at least approximately equal the dimension X of the structure. As another example, the desired center to center spacing (i.e., the distance 224) of each adjacent pair of printheads 225 may be at least approximately a multiple of the dimension X of the structure. For example, the center to center spacing may be two times (i.e., 2×), or three time (i.e., 3×), or four times (i.e., 4×), etc. of the dimension of the structure. As still another example, the plurality of printheads 225 may generally move along a first direction (e.g., first direction 211 depicted in FIGS. 8A-8F or FIGS. 9A-9B) to form the structure, and then move along a second direction (e.g., second direction 212 depicted in FIGS. 8A-8F or FIGS. 9A-9B) opposite of the first direction to further form the structure.


As yet another example, when the plurality of printheads 220 are generally parallel with the length 23 of the composite component 210, such as generally depicted in FIGS. 8A-8F, the center to center spacing or distance 224 along the first axis 201 may generally correspond to or at least approximately equal the desired spacing or distance 97 of the grid structure 62 generally depicted in FIG. 17 along a direction corresponding to the first axis 201. As still another example, when the plurality of printheads 220 are generally parallel with the width 25 of the composite component 210, such as generally depicted in FIGS. 9A-9B, the center to center spacing or distance 224 along the first axis 201 may generally correspond to or at least approximately equal the desired spacing or distance 97 of the grid structure 62 generally depicted in FIG. 17 along another direction corresponding to the first axis 201. Still further, as previously described, the center to center spacing or distance 224 may be a multiple of the spacing or distance 97 of the grid structure 62. In one embodiment, the center to center spacing or distance 224 may be more specifically an integer multiple of the spacing or distance 97 of the grid structure 62.


Furthermore, the spacing 97 of the grid structure 62 along a second direction (e.g., second direction 212 along the first axis 201 to which the plurality of printheads 220 is aligned) is modifiable via the instructions at the controller of the apparatus 200 as the center to center spacing 97 of the grid structure 62 along the opposite direction (e.g., first direction 211) is generally independent of the center to center spacing or distance 224 of the printheads 225 when moving the plurality of printheads 220 along the same direction in which the plurality of printheads 220 is aligned.


It should further be noted that the spacing or distance 97 of the grid structure 62 along a second direction opposite of the first direction may be modified via instructions at the controller (e.g., computer numeric control) of the apparatus 200 as the formed structure (e.g., second member 68, FIG. 17) along the second direction may generally be independent of another structure (e.g., first member 66, FIG. 17) along the first direction relative to the spacing 97 between each pair of members.


Referring to FIG. 8E, in another embodiment, the apparatus 200 further defines a second plurality of printheads 220a adjacent to the plurality of printheads 220 coupled to the second frame 232. For example, the second plurality of printheads 220a may be disposed on an opposing or another side or face of the second frame 232 such disposing the second plurality of printheads 220a adjacent to the plurality of printheads 220 along the second axis 202. As previously described, the second plurality of printheads 220a may be independently moveable along the third axis 203 relative to the plurality of printheads 220. Still further, each machine head 225 may be independently moveable along the third axis 203 relative to another machine head 225.


In various embodiments, such as generally provided in FIG. 8E, two or more of the printheads 225 may operate in together to print or deposit a material, fluid, or both, to the mold 58. For example, the machine head 225 of the plurality of printheads 220 may deposit or extrude a first resin material to form a grid structure 62 of the composite component 210. The machine head 225 of the second plurality of printheads 220A may deposit or extrude a second resin material, same as or different from the first resin material. As another example, the machine head 225 of the second plurality of printheads 220A may provide a flow of fluid, such as air, inert gas, or liquid fluid, to clear or clean the surface onto which the grid structure 62 is formed. In another embodiment, the machine head 225 of the second plurality of printheads 220A may provide a heat source such as to aid curing of the resin material deposited onto the surface. In still another embodiment, the machine head 225 may define a surface preparation tool, such as an abrasion tool, deburr tool, or cleaning tool.


Referring now to FIGS. 9A and 9B, further embodiments of the apparatus 200 are generally provided. The embodiments generally provided in regard to FIGS. 9A and 9B are configured substantially similarly as one or more of the embodiments shown and described in regard to FIGS. 8A-8F. However, in FIGS. 9A and 9B, the first axis 201 is substantially parallel to the width or chord 25 of the composite component 210 (e.g., the rotor blade panel 21). The second axis 202 is further defined substantially parallel to the length or span 23 of the composite component 210. The plurality of printheads 220 are in adjacent arrangement along the first axis 201, such as to extend generally along the width or chord 25 of the composite component 210.


Referring still to FIGS. 9A and 9B, the first frame assembly 230 may generally include a plurality of the second frame 232 to which the plurality of printheads 220 are attached to each. For example, the plurality of second frames 232 may each be independently moveable along the second axis 202 (e.g., along the length or span 23 of the rotor blade panel 21), such as generally depicted in FIG. 9B. Furthermore, the plurality of printheads 220 coupled to each second frame 232 may each be independently moveable along the first axis 201 (e.g., along the width or chord 25 of the rotor blade panel 21). Referring now to FIG. 9B, one or more of the plurality of printheads 220 coupled to each second frame 232 may be moveable away from the mold 58 or composite component 210 such as to provide an opening or vertical clearance along the third axis 203. The clearance or opening may enable placement and removal of the mold 58, the outer skin 56, or both, such as described in regard to FIGS. 8A-8F.


In various embodiments, the plurality of printheads 220 may be arranged along the first axis 201 at least approximately 50% or greater of the width 25 of the composite component 210 to be formed by the apparatus 200. In still other embodiments, the plurality of printheads 220 is arranged along the first axis 201 at least approximately 70% or greater of the width 25 of the composite component 210 to be formed by the apparatus 200. In still yet other embodiments, the plurality of printheads 220 is arranged along the first axis 201 at least approximately 100% or greater of the width 25 of the composite component 210 to be formed by the apparatus 200. In other embodiments (e.g., FIG. 9A), the plurality of printheads 220 may extend at least the entire width or chord 25, or greater, of the mold 58 or composite component 210 to be formed.


In one embodiment, the plurality of printheads 220, the mold 58, or both, is moveable to dispose at least the front head 221 along the first axis 201 beyond the width or chord 25 of the composite component 210 to be formed along the first direction 211. In another embodiment, the mold 58, the plurality of printheads 220, or both, is moveable to dispose at least the rear head 222 along the first axis 201 beyond the width or chord 25 of the composite component 210 along the second direction 212 opposite of the first direction 211. For example, the plurality of printheads 220 is moveable along the first axis 201 such as dispose one or more of the printheads 225 proximate to (e.g., adjacent or vertically over) the mold 58, the composite component 210, or both, along the first axis 201. The second frame 232 is moveable along the second axis 202 to dispose the plurality of printheads 220 along the length or span 23 of the composite component 210. One or more of the second frame 232 may be utilized to be moveable to encompass at least the entire length or span 23 of the composite component 210.


Referring still to the embodiments generally provided in FIGS. 8A-8F and FIGS. 9A-9B, the apparatus 200 may further include a controller configured to control operation of the apparatus 200. The controller, the plurality of printheads 220, and the first frame assembly 230 may together define a computer numeric control (CNC) device. In another embodiment, the controller, the plurality of printheads 220, the first frame assembly 230, and the second frame assembly 240 together define a CNC device. In various embodiments, one or more of the printheads 225 of each plurality of printheads 220 may define a material deposition tool defining at least one or more of an extruder, a filament dispensing head, a tape deposition head, a paste dispensing head, a liquid dispensing head, or one or more of a curing tool, a material conditioning tool, or a vacuum tool. At least one or more of the plurality of printheads 220 is configured to dispense a material from at least one machine head 225 at one or more flow rates, temperatures, and/or pressures independently of one or more other printheads 225. Still further, the material conditioning tool may include a surface preparation tool, such as a cleaning or polishing device, a deburr tool, or other abrasion tool, such as a grinding machine head. The vacuum tool may include a vacuum to remove debris, fluid, chips, dust, shavings, excess material in general, or foreign matter in general.


It should further be appreciated that the embodiments of the apparatus 200 may include the controller further including one or more processors and one or more memory devices utilized for executing at least one of the steps of the embodiments of the method described herein. The one or more memory devices can store instructions that when executed by the one or more processors cause the one or more processors to perform operations. The instructions or operations generally include one or more of the steps of embodiments of the method described herein. The instructions may be executed in logically and/or virtually separate threads on the processor(s). The memory device(s) may further store data that may be accessed by the processor(s). The apparatus 200 may further include a network interface used to communicate, send, transmit, receive, or process one or more signals to and from the controller and to/from at least one of the first frame assembly 230, the second frame assembly 240, the mold 58, or the plurality of printheads 220.


The present disclosure is further directed to methods for manufacturing composite components 210 having at least one printed reinforcement grid structure 62 formed via 3-D printing, or composite tape deposition reinforcement grid structure 62, or combinations thereof. As such, in certain embodiments, the composite structure 210 may define the rotor blade panel 21 such as described in regard to FIGS. 2-7. The rotor blade panel 21 may include a pressure side surface, a suction side surface, a trailing edge segment, a leading edge segment, or combinations thereof 3-D printing, as used herein, is generally understood to encompass processes used to synthesize three-dimensional objects in which successive layers of material are formed under computer control to create the objects. As such, objects of almost any size and/or shape can be produced from digital model data. It should further be understood that the methods of the present disclosure are not limited to 3-D printing, but rather, may also encompass more than three degrees of freedom such that the printing techniques are not limited to printing stacked two-dimensional layers, but are also capable of printing curved shapes.


Referring now to FIG. 8F, the embodiment of the apparatus 200 generally provided is configured substantially similarly to one or more of the embodiments shown or described in regard to FIGS. 8A-8E. However, in FIG. 8F, the apparatus 200 further includes a second frame assembly 240 at least partially surrounding the first frame assembly 230. The second frame assembly 240 includes a first axis frame 241 extended at least partially along the first axis 201 and a second axis frame 232 extended at least partially along the second axis 202. An extendable third axis member 243 is coupled to the second axis frame 242. A holding device 245 is coupled to the third axis member 243. The holding device 245 is configured to couple to the outer skin 56, the mold 58, or both, for movement or translation to the grid 205 vertically under the plurality of printheads 220 along one or more of the first axis 201, the second axis 202, or the third axis 203.


In various embodiments, the holding device 245 is configured to affix to and release from an outer skin 56 to place or remove from the mold 58 at the grid 205. In one embodiment, the holding device 245 defines a vacuum/pressure tool. For example, the holding device 245 may apply a vacuum against the outer skin 56 such as to generate a suction force that affixes the outer skin 56 onto the holding device 245. The second frame assembly 240 translates the holding device 245 along at least one of the first axis 201 and the second axis 202 and extends along the third axis 203 to place the outer skin 56 onto the mold 58. The holding device 245 may further discontinue vacuum to release the outer skin 56 onto the mold 58. In various embodiments, the holding device 245 may further apply a vacuum through the outer skin 56, such as through one or more openings, to generate a suction force pulling the outer skin 56 to the mold 58. The holding device 245 may further apply a pressure, such as a force of air or inert gas, or press upon the outer skin 56 such as by extending the third axis member 243 toward the mold 58 along the third axis 203. For example, applying pressure upon the outer skin 56 and the mold 58 seals at least a perimeter of the outer skin 56 onto the mold 58. In other embodiments, the mold 58 may include a vacuum tool or vacuum line to generate a suction force pulling the outer skin 56 onto the mold 58.


In one embodiment, the holding device 245 may further apply thermal energy (e.g., heat) to at least a portion of the outer skin 56 such as to enable the outer skin 56 to at least substantially conform to a contour of the mold 58. For example, heating at least a portion of the fiber-reinforced outer skin 56 may generally include heating at least a portion of the outer skin 56 to at least a first temperature threshold. In various embodiments, the first temperature threshold defines a temperature at least approximately between a glass transition temperature of the resin material and a melting temperature of the resin material of the fiber reinforced outer skin 56.


In various embodiments, applying thermal energy to the outer skin 56 via the holding device 245 may occur before applying pressure or vacuum to the outer skin 56 to affix to the mold 58. In other embodiments, applying thermal energy to the outer skin 56 may occur at least approximately simultaneously as applying pressure or vacuum to the outer skin 56 to affix to the mold 58. In still other embodiments, applying thermal energy to the outer skin 56 may occur after applying pressure or vacuum to the outer skin 56 to affix the outer skin 56 to the mold 58.


Another embodiment of the method of manufacturing the composite component 210 includes manufacturing a plurality of the composite components 210. The method includes the steps generally described above in regard to FIGS. 8A-8F and FIGS. 9A-9B. The method may further include placing a second fiber-reinforced outer skin 56a onto a second mold 58a via the holding device 245. The second mold 58a is generally disposed adjacent to the first mold 58, such as adjacent along the first axis 201 or the second axis 202, such as generally shown and described in regard to FIGS. 8C, 8D, and 8F.


The method generally includes heating at least a portion of the second fiber-reinforced outer skin 56a to at least a first temperature threshold, applying pressure onto the second outer skin 56a and the second mold 58a to seal at least a perimeter of the second outer skin 56a onto the second mold 58a, and forming a plurality of rib members 62 at the second outer skin 56a, such as described in regard to the first outer skin 56.


It should be appreciated that the method generally includes translating, via the first frame assembly 230 the plurality of printheads 220 along one or more of the first axis 201, the second axis 202, or the third axis 203 proximate to the first outer skin 56, such as to print, apply, or deposit the resin material to form the grid structure 56 or to prepare the surface of the outer skin 56 (e.g., clean, machine, remove material, apply heat, apply cooling fluid, etc.). Approximately concurrently, or serially, the second frame assembly 240 may translate the holding device 245 along the first axis 201, the second axis 202, or the third axis 203 to dispose the second outer skin 56a proximate to the mold 58a when the plurality of printheads 220 is proximate to the first outer skin 56 at the first mold 58. As such, the second frame assembly 240 and holding device 245 may operate on the second outer skin 56a and the second mold 58a while another composite component 210 of the first outer skin 56 is being developed.


The method may further include translating, via the first frame assembly 230, the plurality of printheads 220 along one or more of the first axis 201, the second axis 202, or the third axis 203 proximate to the second outer skin 56a at the second mold 58a and translating, via the second frame assembly 240, the holding device 245 to the first mold 58 when the plurality of printheads 220 is proximate to the second outer skin 56a at the second mold 58a. As such, the holding device 245 may proceed to remove or otherwise operate on the first outer skin 56 from the first mold 58 via the holding device 245. Following completion of the composite component 210 at the second mold 58a, the holding device 245 may further translate to the second mold 58a to remove the composite component 210. Generally, prior to or following forming of the composite component 210 via the plurality of printheads 220, the holding device 245 generally translates along one or more of the first axis 201, the second axis, or the third axis 203 away from the mold 58 to enable access for the plurality of printheads 220 to form the composite component 210.


Referring particularly to FIGS. 8F and 12, one embodiment of the method includes placing a mold 58 relative to an apparatus 200. More specifically, as shown in the illustrated embodiments, the method may include placing the mold 58 into the grid 205. Further, as shown in FIGS. 8F, 10, and 12, the method of the present disclosure further includes forming one or more fiber-reinforced outer skins 56 in the mold 58 of the composite component 210 (e.g., rotor blade panel 21). In certain embodiments, the method includes placing onto the mold 58 the outer skin(s) 56 that may include one or more continuous, multi-axial (e.g., biaxial) fiber-reinforced thermoplastic or thermoset outer skins. Further, in particular embodiments, the method of forming the fiber-reinforced outer skins 56 may include at least one of injection molding, 3-D printing, 2-D pultrusion, 3-D pultrusion, thermoforming, vacuum forming, pressure forming, bladder forming, automated fiber deposition, automated fiber tape deposition, or vacuum infusion.


Composite materials, such as may be utilized in the composite component 210, may generally include a fibrous reinforcement material embedded in matrix material, such as a polymer material (e.g., polymer matrix composite, or PMC). The reinforcement material serves as a load-bearing constituent of the composite material, while the matrix of a composite material serves to bind the fibers together and act as the medium by which an externally applied stress is transmitted and distributed to the fibers.


The bonding or securing of the grid structure 62 with the outer skin(s) 56 can be accomplished in several different ways. For example, in one embodiment, the method may also include forming the grid structure 62 directly to the fiber-reinforced outer skin(s) 56 via one or more of the plurality of printheads 220 of the apparatus 200. Forming the grid structure 62 may include applying or depositing a composite tape onto the outer skin 56. PMC materials may be fabricated by impregnating a fabric or continuous unidirectional tape with a resin (prepreg), followed by curing. For example, multiple layers of prepreg may be stacked or laid-up together to the proper thickness and orientation for the part, such as the grid structure 62, and then the resin may be cured or solidified via one or more printheads 220 to render a fiber reinforced composite component 210. The bundles of fibers may be impregnated with a slurry composition prior to forming the preform or after formation of the preform. The preform may then undergo thermal processing via one or more of the plurality of printheads 220 or the holding device 245, such as to solidify or cure the composite component 210, or a portion thereof, such as the grid structure 62. In one embodiment, overlapping nodes may be used to connect the grid structure 62 with the outer skin(s) 56. In another embodiment, stiffener structures can be used to secure a printed or a bonded grid structure 62 with the outer skin(s) 56.


In alternative embodiments, rather than printing the grid structure 62 directly onto the outer skin(s) 56, the grid structure 62 may be pre-formed (e.g., using a technique other than printed) or pre-printed in the mold (without the skins in place) and then subsequently secured to the outer skin(s), e.g., after thermoforming. For example, in one embodiment, the grid structure 62 may be bonded to the outer skin(s) 56 via an adhesive. Such application may include, for example, applying an adhesive to a bottom surface of the grid structure 62, e.g., via a roller.


In addition, as shown, the outer skin(s) 56 of the rotor blade panel 21 may be curved. In such embodiments, the method may include forming the curvature of the fiber-reinforced outer skins 56. Such forming may include providing one or more generally flat fiber-reinforced outer skins, forcing the outer skins 56 into a desired shape corresponding to a desired contour via the holding device 245, and maintaining the outer skins 56 in the desired shape during printing and depositing. The method may further include heating at least a portion of the fiber-reinforced outer skin 56 to at least a first temperature threshold defining a temperature at least approximately between a glass transition temperature of the resin material and a melting temperature of the resin material. As such, the outer skins 56 generally retain their desired shape when the outer skins 56 and the grid structure 62 printed thereto are released. In addition, the apparatus 200 may be adapted to include a tooling path that follows the contour of the rotor blade panel 21.


The method may also include printing and depositing the grid structure 62 directly to the fiber-reinforced outer skin(s) 56 via the apparatus 200. More specifically, as shown in FIGS. 11, 12, 14, and 17, the apparatus 200 is configured to print and deposit a plurality of rib members 64 that intersect at a plurality of nodes 74 to form the grid structure 62 onto an inner surface of the one or more fiber-reinforced outer skins 56. As such, the grid structure 62 bonds to the fiber-reinforced outer skin(s) 56 as the structure 62 is being deposited, which eliminates the need for additional adhesive and/or curing time. For example, in one embodiment, the apparatus 200 is configured to print and deposit the rib members 64 onto the inner surface of the one or more fiber-reinforced outer skins 56 after the formed skin(s) 56 reach a desired state that enables bonding of the printed rib members 64 thereto, i.e., based on one or more parameters of temperature, time, and/or hardness. Therefore, in certain embodiments, wherein the skin(s) 56 are formed of a thermoplastic matrix, the apparatus 200 may immediately print the rib members 64 thereto as the forming temperature of the skin(s) 56 and the desired printing temperature to enable thermoplastic welding/bonding can be the same). More specifically, in particular embodiments, before the skin(s) 56 have cooled from forming, (i.e., while the skins are still hot or warm), the apparatus 200 is configured to print and deposit the rib members 64 onto the inner surface of the one or more fiber-reinforced outer skins 56. For example, in one embodiment, the apparatus 200 is configured to print and deposit the rib members 64 onto the inner surface of the outer skins 56 before the skins 56 have completely cooled. In addition, in another embodiment, the apparatus 200 is configured to print and deposit the rib members 64 onto the inner surface of the outer skins 56 when the skins 56 have partially cooled. Thus, suitable materials for the grid structure 62 and the outer skins 56 can be chosen such that the grid structure 62 bonds to the outer skins 56 during deposition. Accordingly, the grid structure 62 described herein may be printed using the same materials or different materials.


In addition, in certain embodiments, the grid structure 62 may be constructed of an amorphous material that includes fibers, e.g., up to 55% critical limits. In a preferred embodiment, the grid structure 62 may, as an example, be constructed of polybutylene terephthalate (PET), Polyethylene terephthalate glycol (PETG), polyurethane (PU), or the like. In additional embodiments, the grid structure 62 may also be made of any workable combination of acrylonitrile butadiene styrene, polycarbonate, and PMMA (e.g., Elium® resin).


For example, in one embodiment, a thermoset material may be infused into the fiber material on the mold 58 to form the outer skins 56 using vacuum infusion. As such, the vacuum bag is removed after curing and the one or more thermoset grid structures 62 can then be printed onto the inner surface of the outer skins 56. Alternatively, the vacuum bag may be left in place after curing. In such embodiments, the vacuum bag material can be chosen such that the material would not easily release from the cured thermoset fiber material. Such materials, for example, may include a thermoplastic material such as poly methyl methacrylate (PMMA) or polycarbonate film. Thus, the thermoplastic film that is left in place allows for bonding of thermoplastic grid structures 62 to the thermoset skins with the film in between.


In addition, the method of the present disclosure may include treating the outer skins 56 to promote bonding between the outer skins 56 and the grid structure 62. More specifically, in certain embodiments, the outer skins 56 may be treated using flame treating, plasma treating, chemical treating, chemical etching, mechanical abrading, embossing, elevating a temperature of at least areas to be printed on the outer skins 56, and/or any other suitable treatment method to promote the bonding via one or more of the printheads 225 such as shown and described in regard to FIGS. 8A-8F and FIGS. 9A-9B. In additional embodiments, the method may include forming the outer skins 56 with more (or even less) matrix resin material on the inside surface to promote the bonding, such as via the plurality of printheads 220, or in conjunction with the second plurality of printheads 220a, such as shown and described in regard to FIG. 8E. In additional embodiments, the method may include varying the outer skin thickness and/or fiber content, as well as the fiber orientation.


Further, the method of the present disclosure includes varying the design of the grid structure 62 (e.g., materials, width, height, thickness, shapes, etc., or combinations thereof). As such, the grid structure 62 may define any suitable shape so as to form any suitable structure component, such as the spar cap 48, 50, the shear web 35, or additional structural components 52 of the rotor blade 16. For example, as shown in FIG. 13, the apparatus 200 may begin printing the grid structure 62 by first printing an outline of the structure 62 and building up the grid structure 62 with the rib members 64 in multiple passes. As such, printheads 225 of the apparatus 200 can be designed to have any suitable thickness or width so as to disperse, deposit (e.g., deposit a composite fiber tape) or extrude a desired amount of resin material to create rib members 64 with varying heights and/or thicknesses. Further, the grid size can be designed to allow local buckling of the face sheet in between the rib members 64, which can influence the aerodynamic shape as an extreme (gust) load mitigation device.


More specifically, as shown in FIGS. 11-17, the rib members 64 may include, at least, a first rib member 66 extending in a first direction 76 and a second rib member 68 extending in a different, second direction 78. In several embodiments, as shown in FIG. 17, the first direction 76 of the first set 70 of rib members 64 may be generally perpendicular to the second direction 78. More specifically, in certain embodiments, the first direction 76 may be generally parallel to a chord-wise direction of the rotor blade 16 (i.e., a direction parallel to the width or chord 25 (FIG. 2)), whereas the second direction 78 of the second set 72 of rib members 64 may be generally parallel with a span-wise direction of the rotor blade 16 (i.e., a direction parallel to the length or span 23 (FIG. 2)). In still various embodiments, the first direction 76 may correspond to a direction along the first axis 201 generally shown and described in regard to FIGS. 8A-8F and FIGS. 9A-9B. Alternatively, the second direction 78 may generally correspond to a direction along the second axis 202 generally shown and described in regard to FIGS. 8A-8F and FIGS. 9A-9B. Alternatively, in one embodiment, an off-axis orientation (e.g., from about 20° to about 70° relative to the first axis 201 or the second axis 202) may be provided in the grid structure 62 to introduce bend-twist coupling to the rotor blade 16, which can be beneficial as passive load mitigation device. Alternatively, the grid structure 62 may be parallel the spar caps 48, 50.


Moreover, as shown in FIGS. 15 and 16, one or more of the first and second rib member(s) 66, 68 may be printed to have a varying height along a length 84, 85 thereof. In alternative embodiments, as shown in FIGS. 18 and 19, one or more of the first and second rib member(s) 66, 68 may be printed to have a uniform height 90 along a length 84, 85 thereof. In addition, as shown in FIGS. 11, 14, and 17, the rib members 64 may include a first set 70 of rib members 64 (that contains the first rib member 66) and a second set 72 of rib members 64 (that contains the second rib member 68).


In such embodiments, as shown in FIGS. 15 and 16, the method may include forming (e.g., via tape deposition) or printing (e.g., via extrusion) a maximum height 80 of either or both of the first set 70 of rib members 64 or the second set 72 of rib members 64 at a location substantially at (i.e., +/−10%) a maximum bending moment in the rotor blade panel 21 occurs. For example, in one embodiment, the maximum bending moment may occur at a center location 82 of the grid structure 62 though not always. As used herein, the term “center location” generally refers to a location of the rib member 64 that contains the center plus or minus a predetermined percentage of an overall length 84 of the rib member 64. For example, as shown in FIG. 15, the center location 82 includes the center of the rib member 64 plus or minus about 10%. Alternatively, as shown in FIG. 16, the center location 82 includes the center plus or minus about 80%. In further embodiments, the center location 82 may include less than plus or minus 10% from the center or greater than plus or minus 80% of the center.


In addition, as shown, the first and second sets 70, 72 of rib members 64 may also include at least one tapering end 86, 88 that tapers from the maximum height 80. More specifically, as shown, the tapering end(s) 86, 88 may taper towards the inner surface of the fiber-reinforced outer skins 56. Such tapering may correspond to certain blade locations requiring more or less structural support. For example, in one embodiment, the rib members 64 may be shorter at or near the blade tip and may increase as the grid structure 62 approaches the blade root. In certain embodiments, as shown particularly in FIG. 16, a slope of the tapering end(s) 86, 88 may be linear. In alternative embodiments, as shown in FIG. 15, the slope of the tapering end(s) 86, 88 may be non-linear. In such embodiments, the tapering end(s) 86, 88 provide an improved stiffness versus weight ratio of the panel 21.


In additional embodiments, one or more heights of intersecting rib members 64 at the nodes 74 may be different. For example, as shown in FIG. 18, the heights of the second set 72 of rib members 64 are different than the intersecting first rib member 66. In other words, the rib members 64 can have different heights for the different directions at their crossing points. For example, in one embodiment, the span-wise direction rib members 64 may have a height twice as tall as the height of the chord-wise direction rib members 64. In addition, as shown in FIG. 18, the second set 72 of rib members 64 may each have a different height from adjacent rib members 64 in the second set 72 of rib members 64. In such embodiments, as shown, the method may include printing each of the second set 70 of rib members 64 such that structures 64 having greater heights are located towards the center location 82 of the grid structure 62. In addition, the second set 70 of rib members 64 may be tapered along a length 85 thereof such that the rib members 64 are tapered shorter as the rib members approach the blade tip.


In further embodiments, as mentioned, the rib members 64 may be printed with varying thicknesses. For example, as shown in FIG. 17, the first set 70 of rib members 64 define a first thickness 94 and the second set 72 of rib members 64 define a second thickness 96. More specifically, as shown, the first and second thicknesses 94, 96 are different. In addition, as shown in FIGS. 20 and 21, the thicknesses of a single rib member 64 may vary along its length.


Referring particularly to FIG. 17, the first set 70 of rib members 64 and/or the second set 72 of rib members 64 may be evenly spaced. In alternative embodiments, as shown in FIGS. 20 and 21, the first set 70 of rib members 64 and/or the second set 72 of rib members 64 may be unevenly spaced. For example, as shown, the additive methods described herein enable complex inner structures that can be optimized for loads and/or geometric constraints of the overall shape of the rotor blade panel 21. As such, the grid structure 62 of the present disclosure may have shapes similar to those occurring in nature, such as organic structures (e.g., bird bones, leaves, trunks, or similar). Accordingly, the grid structure 62 can be printed to have an inner blade structure that optimizes stiffness and strength, while also minimizing weight.


In several embodiments, the cycle time of printing the rib members 64 can also be reduced by using a rib pattern that minimizes the amount of directional change. For example, 45-degree angled grids can likely be printed faster than 90-degree grids relative to the chord direction of the proposed printer, for example. As such, the present disclosure minimizes printer acceleration and deceleration where possible while still printing quality rib members 64.


In another embodiment, as shown in FIGS. 10 and 14, the method may include printing a plurality of grid structures 62 onto the inner surface of the fiber-reinforced outer skins 56. More specifically, as shown, the plurality of grid structures 62 may be printed in separate and distinct locations on the inner surface of the outer skins 56.


Certain advantages associated with the grid structure 62 of the present disclosure can be better understood with respect to FIG. 22. As shown, the graph 100 illustrates the stability of the rotor blade 16 (represented as the buckling load factor “BLF”) on the y-axis versus the weight ratio on the x-axis. Curve 102 represents the stability versus the weight ratio for a conventional sandwich panel rotor blade. Curve 104 represents the stability versus the weight ratio for a rotor blade having a non-tapered grid structure constructed of short fibers. Curve 106 represents the stability versus the weight ratio for a rotor blade having a non-tapered grid structure without fibers. Curve 108 represents the stability versus the weight ratio for a rotor blade having a grid structure 62 constructed of tapered rib members 64 with 1:3 slope and without fibers. Curve 110 represents the stability versus the weight ratio for a rotor blade having a grid structure 62 constructed of tapered rib members 64 with 1:2 slope and without fibers. Curve 112 represents the stability versus the weight ratio for a rotor blade 16 having a grid structure 62 containing short fibers having a first thickness and being constructed of tapered rib members 64 with 1:3 slope. Curve 114 represents the stability versus the weight ratio for a rotor blade 16 having a grid structure 62 containing short fibers having a second thickness that is less than the first thickness and being constructed of tapered rib members 64 with 1:3 slope. Thus, as shown, rib members 64 containing fibers maximize the modulus thereof, while thinner rib members minimize the weight added to the rotor blade 16. In addition, as shown, higher taper ratios increase the buckling load factor.


Referring now to FIGS. 23-25, various additional features of the grid structure 62 of the present disclosure are illustrated. More specifically, FIG. 23 illustrates a partial, top view of one embodiment of the printed grid structure 62, particularly illustrating one of the nodes 74 thereof. As shown, the apparatus 200 may form at least one substantially 45-degree angle 95 for a short distance at one or more of the plurality of nodes 74. As such, the 45-degree angle 95 is configured to increase the amount of abutment or bonding at the corners. In such embodiments, as shown, there may be a slight overlap in this corner node.


Referring particularly to FIG. 24, a partial, top view of one embodiment of the printed grid structure 62 is illustrated, particularly illustrating a start printing location and an end printing location of the grid structure 62. This helps with the startup and stop of printing the ribs. When the apparatus 200 begins to print the rib members 64 and the process accelerates, the extruders may not perfectly extrude the resin material. Thus, as shown, the apparatus 200 may start the printing process with a curve or swirl to provide a lead in for the rib member 64. By extruding this swirl at the start location, the printheads 225 are given time to more slowly ramp up/down their pressure, instead of being required to instantaneously start on top of a narrow freestanding starting point. As such, the swirl allows for the grid structures 62 of the present disclosure to be printed at higher speeds.


In certain instances, however, this start curve may create a small void 99 (i.e., the area within the swirl) in the start region which can create issues as the void 99 propagates up through ongoing layers. Accordingly, the apparatus 200 is also configured to end one of the rib members 64 within the swirl of the start region so as to prevent the void 99 from developing. More specifically, as shown, the apparatus 200 essentially fills the start curve of the one of the rib members 64 with an end location of another rib member 64.


Referring particularly to FIG. 25, an elevation view of one embodiment of one of the rib members 64 of the printed grid structure 62 is illustrated, particularly illustrating a base section 55 of the rib members 64 having a wider W and thinner T first layer so as to improve bonding of the grid structure 62 to the outer skins 56 of the rotor blade panel 21. To form this base section 55, the apparatus 200 prints a first layer of the grid structure 62 such that the individual base sections 55 define a cross-section that is wider and thinner than the rest of the cross-section of the rib members 64. In other words, the wider and thinner base section 55 of the rib members 64 provides a larger surface area for bonding to the outer skins 56, maximum heat transfer to the outer skins 56, and allows the apparatus 200 to operate at faster speeds on the first layer. In addition, the base section 55 may minimize stress concentrations at the bond joint between the structure 62 and the outer skins 56.


Referring now to FIGS. 26-31, the apparatus 200 described herein is also configured to print at least one additional feature 63 directly to the grid structure(s) 62, wherein heat from the printing bonds the additional features 63 to the structure 62. As such, the additional feature(s) 63 can be directly 3-D printed into the grid structure 62. Such printing allows for the additional feature(s) 63 to be printed into the grid structure 62 using undercuts and/or negative draft angles as needed. In addition, in certain instances, hardware for various blade systems can be assembled within the grid structure 62 and then printed over to encapsulate/protect such components.


For example, as shown in FIGS. 26-29, the additional feature(s) 63 may include auxiliary features 81 and/or assembly features 69. More specifically, as shown in FIGS. 26 and 27, the assembly feature(s) 69 may include one or more alignment structures 73, at least one handling or lift feature 71, one or more adhesive gaps or standoffs 95, or one or more adhesive containment areas 83. For example, in one embodiment, the apparatus 200 is configured to print a plurality of handling features 71 to the grid structure 62 to provide multiple gripping locations for removing the rotor blade panel 21 from the mold 58. Further, as shown in FIG. 24, one or more adhesive containment areas 83 may be formed into the grid structure 62, e.g., such that another blade component can be secured thereto or thereby.


In particular embodiments, as shown in FIGS. 27 and 28, the alignment or lead in structure(s) 73 may include any spar cap and/or shear web alignment features. In such embodiments, as shown, the grid structure(s) 62 may printed such that an angle of the plurality of rib members 64 is offset from a spar cap location so as to create an adhesive containment area 83. More specifically, as shown, the adhesive containment areas 83 are configured to prevent squeeze out of an adhesive 101. It should be further understood that such adhesive containment areas 83 are not limited to spar cap locations, but may be provided in any suitable location on the grid structure 62, including but not limited to locations adjacent to the leading edge 24, the trailing edge 26, or any other bond locations.


In further embodiments, the alignment structure(s) 73 may correspond to support alignment features (e.g., for support structure 52), blade joint alignment features, panel alignment features 75, or any other suitable alignment feature. More specifically, as shown in FIG. 27, the panel alignment features 75 may include a male alignment feature 77 or a female alignment feature 79 that fits with a male alignment feature 77 or a female alignment feature 79 of an adjacent rotor blade panel 21.


Further, as shown in FIG. 30, the additional feature(s) 63 may include at least one auxiliary feature 81 of the rotor blade panel 21. For example, in one embodiment, the auxiliary features 81 may include a balance box 67 of the rotor blade 16. In such embodiments, the step of printing the additional feature(s) 63 into the grid structure(s) 62 may include enclosing at least a portion of the grid structure 62 to form the balance box 63 therein. In additional embodiments, the auxiliary feature(s) 81 may include housings 87, pockets, supports, or enclosures e.g. for an active aerodynamic device, a friction damping system, or a load control system, ducting 89, channels, or passageways e.g. for deicing systems, one or more valves, a support 91, tubing, or channel around a hole location of the fiber-reinforced outer skins, a sensor system having one or more sensors 103, one or more heating elements 105 or wires 105, rods, conductors, or any other printed feature. In one embodiment, for example, the supports for the friction damping system may include sliding interface elements and/or free interlocking structures. For example, in one embodiment, the 3-D printed grid structure 62 offers the opportunity to easily print channels therein for providing warmed air from heat source(s) in the blade root or hub to have a de-icing effect or prevent ice formation. Such channels allow for air contact directly with the outer skins 56 to improve heat transfer performance.


In particular embodiments, the sensor system may be incorporated into the grid structure(s) 62 and/or the outer skins 56 during the manufacturing process. For example, in one embodiment, the sensor system may be a surface pressure measurement system arranged with the grid structure 62 and/or directly incorporated into the skins 56. As such, the printed structure and/the skins 56 are manufactured to include the series of tubing/channels needed to easily install the sensor system. Further, the printed structure and/or the skins 56 may also provide a series of holes therein for receiving connections of the system. Thus, the manufacturing process is simplified by printing various structures into the grid structure 62 and/or the skins 56 to house the sensors, act as the static pressure port, and/or act as the tubing that runs directly to the outer blade skin. Such systems may also enable the use of pressure taps for closed loop control of the wind turbine 10.


In still further embodiments, the mold 58 may include certain marks (such as a positive mark) that are configured to create a small dimple in the skin during manufacturing. Such marks allow for easy machining of the holes in the exact location needed for the associated sensors. In addition, additional sensor systems may be incorporated into the grid structures and/or the outer or inner skin layers 56 to provide aerodynamic or acoustic measurements so as to allow for either closed loop control or prototype measurements.


In addition, the heating elements 105 described herein may be flush surface mounted heating elements distributed around the blade leading edge. Such heating elements 105 allow for the determination of the angle of attack on the blade by correlating temperature/convective heat transfer with flow velocity and the stagnation point. Such information is useful for turbine control and can simplify the measurement process. It should be understood that such heating elements 105 may also be incorporated into the outer or inner skin layers 56 in additional ways and are not required to be flush mounted therein.


Referring back to FIG. 26, the method according to the present disclosure may include placing a filler material 98 between one or more of the rib members 64. For example, in certain embodiments, the filler material 98 described herein may be constructed of any suitable materials, including but not limited to low-density foam, cork, composites, balsa wood, composites, or similar. Suitable low-density foam materials may include, but are not limited to, polystyrene foams (e.g., expanded polystyrene foams), polyurethane foams (e.g., polyurethane closed-cell foam), polyethylene terephthalate (PET) foams, other foam rubbers/resin-based foams and various other open cell and closed cell foams.


Referring back to FIG. 29, the method may also include printing one or more features 93 onto the outer skins 56, e.g., at the trailing and/or leading edges of the rotor blade panels 21. For example, as shown in FIG. 29, the method may include printing at least one lightning protection feature 96 onto at least one of the one or more fiber-reinforced outer skins 56. In such embodiments, the lightning protection feature 93 may include a cooling fin or a trailing edge feature having less fiber content than the fiber-reinforced outer skins 56. More specifically, the cooling fins may be directly printed to the inside surface of the outer skins 56 and optionally loaded with fillers to improve thermal conductivity but below a certain threshold to address lightning related concerns. As such, the cooling fins are configured to improve thermal transfer from the heated airflow to the outer skins 56. In additional embodiments, such features 93 may be configured to overlap, e.g., such as interlocking edges or snap fits.


Referring now to FIGS. 31 and 32, the additional feature(s) 63 may include an adhesive gap 95 or stand-off, which may be incorporated into the grid structures 62. Such standoffs 95 provide a specified gap between two components when bonded together so to minimize adhesive squeeze out. As such, the standoffs 95 provide the desired bond gap for optimized bond strength based on the adhesive used.


Referring now to FIGS. 33-34, further embodiments of an apparatus for manufacturing composite components 210 are illustrated. As mentioned, the printing strategy according to the present disclosure utilizes multiple printheads to generate a continuous structure over a three-dimensional surface. One of the features of previous embodiments is the use of the multiple printheads 220 mounted onto the same gantry in a manner that all heads 220 can move simultaneously in the X and Y directions but independently in the Z direction, which can significantly reduce the programming and control complexity versus completely independent motion of the printheads, thereby preventing collisions among the printheads 220 within the same gantry system.


For example, as shown in FIGS. 33A, 33B, and 34, the apparatus 300 includes a mold 58 onto which the composite component 210 can be formed. The mold 58 is disposed within a grid 305 defined by a first axis 301 and a second axis 302 generally perpendicular to the first axis 301. A plurality of printheads 320 disposed within the grid 305 in adjacent arrangement along the first axis 301 or the second axis 302. The plurality of printheads 320 is coupled to a first frame assembly 330 above the mold 58. The mold 58, the plurality of printheads 320, or both, is moveable along the first axis 301 and the second axis 302. Further, each machine head 320 is moveable independently of one another along a third axis 303.


Referring particularly to FIG. 33B, still another embodiment of the apparatus 300 may include two (or more) rows of printheads 320 (either in the spanwise or chordwise directions), e.g., on a single gantry, so as to reduce layer time if needed. Therefore, in such embodiments, the number of rows of printheads would be determined based at least partly on the desired layer time of a given material system to deliver optimal layer bonding strength. In such embodiments, each row of printheads 320 is only required to cover a portion of the distance of a given grid design, thereby reducing overall layer or recoat time. As used herein, the layer or recoat time generally refers to the elapsed time from when material is deposited in one position and then new material is deposited on top of the previously-printed material in another layer. Thus, when the grid structure 62 includes multiple zones printed via multiple printheads, the printhead can traverse multiple islands of discrete zones (each with their own discrete layers) and different printheads can print material on top of material deposited by another printhead. Therefore, the elapsed time can be an important consideration, as it can vary greatly depending on the design of the grid structure 62 and the tool pathing selected of the various printheads. For example, in one embodiment, the longest recoat time may lead to the weakest link regarding layer bonding strength.


Such apparatuses may be useful, for example, when forming inboard regions of the rotor blade 16. Further, in an embodiment, each row can be rigidly connected together on the same gantry (so all printheads move in unison in X and Y directions). In alternative embodiments, each row of printheads may be on independent gantry that would allow a degree of freedom in the direction generally perpendicular to the printhead rows. In further embodiments, the spacing between each of the rows may also be configured to allow for printing of each section and allows for either no spanwise gaps or allows for one or more spanwise gaps to allow for the assembly of spanwise structural members as described herein.


In certain embodiments, the printheads described herein may be aligned in the gantry along the X (spanwise) axis and at uniform intervals for convenience and simplicity and/or to accommodate the physical size of the pellet feed extruder that comprises the printheads. In other embodiments, however, depending on the grid structure design, the printhead-to-printhead spacing can be non-uniform. Moreover, in certain embodiments, the printheads may not be aligned along the X axis or any axis.


When printing with multiple printheads, however, it is also important that printed material in a given layer comes into contact with recently printed material from another printhead while both materials are at temperatures above their glass transition temperature to allow for diffusion or thermal welding to sufficiently occur to form a bond between each material layer. Another important aspect of multiple printheads is the pathway taken by a second printhead as it deposits material in contact with material deposited by a first printhead. For example, it is important to note that with a typical three-axis system or one with only three degrees of freedom for the printhead movement, it is impractical to simultaneously print material from two or more printheads at the same basic location without the physical printhead hardware from colliding and damaging the system. As a result, there is both a time lag consideration and also a pathway consideration that can affect the quality of the nodes of the grid system of the present invention. A node is defined herein as any intersection with a printed grid structure from two or more printed roads. A road is defined as the physical material deposited by a printhead in a single pass in one layer.


The printheads 220 of apparatus 200 of FIG. 8A, as an example, are generally evenly spacing (e.g., at about 280 millimeters (mm) apart) in a linear array that covers most of the span length of the part to be printed. Such an arrangement allows the printheads 220 to print an orthogonal uniform grid structure with cell spacing of approximately 70 mm. Further, the developed path of printed material results in two types of nodes. A first type of node results from the second printhead passing directly over and through the road from the first printhead. A second type of node resulted in a printed road that connected by running alongside a previously printed road. These second types of nodes are generally of higher quality (i.e., with respect to strength and/or structural integrity) than the first type. In the first type, for example, a void is often created in the second road as it passes over/through the first road on the backside of the node intersection.


Thus, the present disclosure is further directed to the apparatus 300 in FIGS. 33A, 33B, and 34 that alters the material deposition rate to increase material deposition as the second printhead passes the node to fill in the material void that is caused by the displacement of deposited material as the printhead passes over the first printed road. In addition, the present disclosure is also directed to an apparatus 300 that can slow the printhead speed as the node is crossed by the second printhead to reduce or eliminate the void caused higher speed deposition through the node.


In particular, the apparatus 300 illustrated in FIGS. 33A, 33B, and 34 allows for modification to the grid structure design and the printed road paths to eliminate the first type of nodes where possible. As such, the overall quality of the grid structure can be improved without the use of more sophisticated control techniques needed to compensate for the extrusion flow disruption issues. One method to achieve a grid structure having predominately second types of nodes is illustrated in FIGS. 35-39, wherein such design may be generally referred to herein as a “stacked cup” design.


Thus, as shown in this embodiment, each printhead 320 within the printer gantry is configured to move in unison in X and Y print directions (generally corresponding to spanwise and chordwise directions relative to the blade geometry). Moreover, in such embodiments, the Z direction motion is independent for each printhead 320. Regarding the X and Y motion, the stacked-cup grid patterns are made via all printheads 320 within the same gantry moving in generally the chordwise direction, followed by a turn generally towards spanwise motion. In particular embodiments, the chordwise motion sets the width of the pattern, whereas the spanwise motion sets the length of the pattern. Both the chordwise and spanwise motions are not necessarily parallel to X and Y axes. Rather, in particular embodiments, the spanwise motion angle relative to the X axis can be used to control the amount of overlap of the second type of nodes of the stacked cup structure. More particularly, in an embodiment, if the angle is 0 degrees, a true linear array of printheads that all start at the same Y axis/chordwise value will result in a node that is a complete overlap (undesirable), whereas a shallow angle will result in a partial overlap based on the length of the stacked cup pattern and the angle from the Y axis.


Still further benefits of the stacked-cup grid design may also include material optimization in both the spanwise and chordwise direction to maximize buckling performance compared to designs that are more sinusoidal in nature. This feature leads to optimized performance to weight ratio compared to a sinusoidal type design. In addition, another aspect of the present disclosure is the ability to optimize the radii of the stacked cup design to optimize print speed based on the given printer design. For example, FIGS. 35-36 illustrate grid structures 62 having a stacked-cup design with blunt edges 120, whereas FIGS. 37-40, 49A, 49B illustrate grid structures 62 having a stacked-up design with curved edges 122 having a certain radii. In such embodiments, tighter radii may require reduced print speeds due to the mass and inertia of the apparatus 300, whereas larger radii enables continuous print speeds through the direction changes which allows for higher quality and more consistent printed roads at faster overall layer cycles. For instance, in one embodiment, the grid patterns can be designed in such a way that continuous printing is possible without cross-over nodes 124.


Referring now to FIGS. 39 and 40, the width, height, thickness, and node overlap, if any, of one embodiment of the grid structure 62 is illustrated. Thus, grid properties of the overall structure 62 can be optimized using the length and width of the stacked-cup design, the width of the printed road, the angle that determines the amount of overlap at the first type of node intersection, as well as the length of the second type of node intersection. For example, as shown in FIGS. 35 and 36, the cups may be angled to manage the overlap between adjacent rows of cups. Alternatively, as shown in FIGS. 37 and 38, the joggles (curves) at the overlapping grid portions can be used to manage the overlap. Thus, such features allow the cell size width of the grid structure 62 to remain the same throughout, if desired. Still another method of managing the overlapping portions may include using complete overlap, i.e., the printed paths are in complete alignment. In such embodiments, there are no joggles or angles, but rather, all orthogonal ribs. In particular, as shown in FIGS. 49A and 49B, different embodiments of the stacked-cup design of the grid structure 62 are illustrated. For example, FIG. 49A illustrates a staggered stacked-cup design as shown at node 57, whereas FIG. 49B illustrates an inline stacked-cup design as shown at node 57.


In still further embodiments, as shown in FIGS. 42 and 45-48, the grid structure 62 may be formed with straight lines 126 having an angled portion 128 at certain locations to allow for the second type of node described herein. As shown, with the angled portions 128, the angle can change based on the spanwise length of the grid spacing. Using the orthogonal lines with joggles/angled portions allows for uniformity between printed zones of different grid cell dimensions. In addition, this design allows for easier matchup to finite element models, CAD design, and simpler connections between spanwise zones because end features between each zone can be the same from the cup angle perspective.


As mentioned, the apparatus 200 of FIG. 8A may have a printhead spacing of about 280 mm. Therefore, in order to print a grid pattern with a tighter cell spacing of 70 mm for example, each printhead 220 must travel back and forth across the area to be printed about four times before starting the next layer. Depending on the material used for printing, the temperature of the skin on the mold during printing, ambient temperature and other factors that can affect how quickly the printed material cools, the layer time can affect the properties of the printed grid structure 62. In particular, if the previous layer printed has cooled too much before depositing the next layer, the quality of the grid structure can be negatively impacted.


Thus, some solutions for addressing the aforementioned concerns may include enclosing the printer volume in an oven or providing external heat sources to reheat the previously-deposited material just prior to next layer deposition. At the size of the components targeted for this process, however, a full oven enclosure may not be practical. Moreover, the large number of printheads 220 and tight spacing also presents practical considerations for adding additional heat sources to each printhead 220. Therefore, as shown in FIGS. 41-42 and 45-48, in an embodiment, rather than printing a continuous grid structure 62, the apparatuses 200, 300 described herein can alter the grid design by breaking the grid structure 62 into two or more zones or grid segments 65. Thus, by reducing the grid area into smaller zones 65, previously printed layers cool less, which can result in better layer bonding and better node bonding.


In such embodiments, where layer cycle time is important to improve the layer adhesion strength (e.g., printing on a layer that has had too much time to cool off results in poor layer to layer bonding in the printing process), the layer time can be reduced within a zone 65 by reducing the path length required for each layer. Therefore, in one embodiment, the printheads of the apparatuses 200, 300 may be configured to complete fewer cells per layer. In one embodiment, such as shown in FIG. 8A, as an example, which may include 280 mm center to center spacing and in which 70-mm cell spacing is desired, the printheads 220 typically make four passes back and forth across the chord of the zone. However, by accepting a disconnect between portions of the printed grid structure 62, either by an overlap within the structure that is acceptable for the application even though the grid material is not continuously connected, by connecting the material with additional structural members and/or adhesives, or by 3-D printing additional material as part of an additional printing step, layer/recoat time can be substantially reduced. In this example, the grid structure 62 can be printed in discontinuous sections, respecting the physical limitations of the printheads to avoid collisions on successive printing steps. This can reduce a print zone that needed to be printed in four chordwise passes to as little as one pass, thereby reducing the layer time.


In yet another embodiment, the printheads 320 of the apparatus 300 can be programmed to print the grid structure(s) 62 described herein according to a particular path. For example, in one embodiment, the printheads 320 may deposit the print material in a continuous manner that does not travel back and forth across the chord on the same path. In other words, the printheads 320 may travel and print material in one direction on the chord, and then may deposit grid material as it travels back on another portion of the chord where possible. In such embodiments, additionally printed material is prevented from being stacked atop recently deposited material immediately as the extruder returns across the chord.


Referring particularly to FIGS. 43A and 43B, simplified, schematic diagrams of another embodiment of an apparatus 300 for manufacturing composite components 210 are illustrated. In particular, as shown, the apparatus 300 may include a plurality of groups 310 of a smaller number of printheads 320 arranged to print separate spanwise zones. For example, in the illustrated embodiment, three groups 310 of printheads 320 are illustrated. In such embodiments, the printheads 320 can be staggered in printing, e.g., covering up to six (6) print zones that are typically traversed by the gantry in two-passes. Thus, as shown from FIG. 43A to FIG. 43B, after printing a first set of spanwise zones (FIG. 43A), the groups 310 of printheads 320 can move or shift (FIG. 43B) a certain spanwise length to a second set of spanwise zones. It should be understood that many combinations are possible with this approach and FIGS. 43A and 43B are provided examples only.


Though this embodiment may have an increased cycle time, e.g., as compared to FIG. 8A, the overall system generally provides more customization options from printed zone to printed zone because the spacing determined by the X axis (spanwise) travel can be different between each printed zone. For example, in one embodiment, it can be easier to customize the spanwise cell length of the grid structure 62 from zone to zone. For example, in an embodiment, the apparatus described herein may include a full span of printheads on the same gantry with multiple degrees of freedom that are independent of spanwise or chordwise motion or rotational motion about the gantry arm axis. In another embodiment, the apparatus described herein may include a full span of printheads on the same gantry without additional degrees of freedom of the individual printheads. Such a system must move in unison, whereas a partial span of printheads moves in unison printing in one zone, shifts at least a zone length spanwise and prints again, with the option to deliver a different pattern than in the previous zone.


Thus, in one embodiment that includes multiple, independent groups of printheads, as an example, a first group of printheads can print a first zone of the grid structure 62 while a second group of printheads remains idle. Then, the two groups of printheads may simultaneously print second and third zones together (e.g., with no gap between the second and third zones, but with a gap between the first and second zones. Moreover, in such embodiments, the first and second groups of printheads may then print fourth and fifth zones together with a gap between the first and fourth zones. The second group of printheads may then print a sixth zone by itself with a gap between zones five and six. It should be understood by those having ordinary skill in the art that such a printing scheme is provided as an example only and may other printing methods may be utilized by the multiple groups of printheads so as to form any suitable composite component.


In any embodiment, where one or more of the printheads remain idle for any period of time, the resonance time of the material may be considered and managed so as not to degrade the printed material, thereby resulting in poor material quality of the printed grid structure 62. Thus, in an embodiment, an idle group of printheads that have material loaded therein may preferably be moved to a purging location to remove material and wait for reload until the gantry is needed for further printing.


In one embodiment, as shown in FIG. 38, the grid structures 62 may be printed with gaps between adjacent rows such that the gaps can be subsequently filled with adhesive 130 when cooled. In another embodiment, as shown in FIG. 37, rather than using adhesives, grid ridges can be printed with high overlaps between adjacent rows and used to provide a shear connection between adjacent rows. In yet another embodiment, interface bridge pieces may be used. Grid ridges are typically printed in closely spaced sections and the sections are then connected with such interface pieces. Additional shear connection with the skin may also be used to reinforce the interface bridge pieces.


Moreover, as shown in FIGS. 33A, 41, 42, and 45-48, with the printheads 320 being generally aligned in the X axis, the multiple zones 65 may be separated by spanwise or chordwise gaps 132, 134. For example, in some embodiments, certain mechanical properties need to be achieved by the grid structure(s) 62 described herein. As such, by providing gaps 132, 134 between the grid structures 62 and/or varying the size of such gaps 132, 134, varying structural profiles 136 can be arranged therebetween (e.g., hat-shaped, C-shaped, U-shaped, square, rectangular, etc.) to provide the desired characteristics of a given component.


For example, as shown in FIGS. 44-48, one or more structural members 136 can be provided on the inner surface of the blade panel before, during, or after printing. Accordingly, in such embodiments, the printheads 320 can then subsequently print in, around, adjacent, or underneath the structural member(s) 136 to build up the grid structure(s) 62. The structural member(s) described herein may be constructed of any suitable materials, such as any of the materials described herein. For example, in one embodiment, the structural member(s) 136 may be a fiber-reinforced polymer or a pultrusion bonded or otherwise secured to the inner surface. In addition, in an embodiment, the structural member(s) 136 may have any suitable shape, such as tubular, rectangular, square, U-shaped, etc. and may include or be absent of flanges. In certain embodiments, as shown in FIGS. 44A, 44B, and 44C, where flanges 138 are included, the printheads 320 can deposit print material between the skins 56 and the opposing flanges 138 so as to support local buckling of the skin 56 in the unsupported region. More particularly, as shown in FIGS. 44A, 44B, and 44C, optional adhesive 131 and/or additional grid ribs 133 can be utilized below the structural member(s) 136 (e.g., when using a hat-shaped profile) to provide support to the skin(s) 56 underneath the structural member(s) 136 that may preferably need support against local buckling. In such embodiments, the additional grid ribs may be printed prior to bonding of the structural member(s) 136.


Thus, in certain embodiments, as shown, the structural member(s) 136, which may be placed in any suitable location, allow for printing of various zones of the individual grid structures 62. Accordingly, in such embodiments, the structural member(s) 136 allow for separation of one large zone into two or more zones with one or more gaps therebetween. Such gaps can then be filled with the structural member(s) 136 described herein, which may have various lengths, including shorter and longer lengths, that can span across one or more printed zones 65.


In further embodiments, the structural member(s) 136, as well as any of the other materials described herein may be recycled into useful products. In such embodiments, extra print material, as well as process scrap, can be recycled by grinding materials and re-compounding the ground material into pellets that can be molded into new parts. For example, in one embodiment, the recycled pellets may be used in subsequent grid printing, injection molding, or extruded into other parts for use in other applications.


Moreover, in certain embodiments, the methods described herein may include using different thermoplastic materials in different areas of the grid structure 62. Accordingly, by printing the various zones of the individual grid structures 62, the methods according to the present disclosure provides the ability to easily vary materials across the structure 62. In contrast, if the entire grid structure 62 is printed 62 using printheads arranged across the entire span, it can be preferable to use the same or very similar materials such that the resins are as compatible as possible for thermoplastic welding. In still further embodiments, the methods described herein may include choosing to have different layer or recoat times between zones, that may also affect our material preference for each zone, for example. As a further example, a zone with a shorter layer or recoat time may benefit from a semi-crystalline formulation with a shorter process window versus a zone with a longer layer or recoat time, which may benefit from a more amorphous formulation with a longer process window. Accordingly, using different materials in different zones may be utilized for a variety of design considerations, including but not limited to cost optimization, structural and weight optimization, foamed versus non-foamed grid structures, etc. In addition, in embodiments that employ modular printer gantries (FIGS. 33A, 33B, and 34), the gantry can be dedicated to run the same material for the complete build and other gantries can be dedicated to run different materials as desired. In additional embodiments, the same gantry can be used to print one material (or blend of materials) in one zone, and then be purged of that material, reloaded with a new material, and then may print another zone. This process can be repeated for any number of zones.


For example, using such structural members 136 can be more challenging towards the tip 22 of the rotor blade 16 (where sweep and pre-bend of the blade design make accommodating long, straight rigid structures more challenging). In addition, in certain embodiments, modular components intended to be used further from the blade tip 22 can be more suited for long straight sections as they require less deviation to conform with the intended surface. Therefore, using spaced apart grid structures 62 with customized materials between the gaps can be beneficial in accommodating different areas of the blade having different structural needs.


In additional embodiments, assembling the structural member(s) 136 can be achieved using a variety of methods. For example, in one embodiment, such the structural member(s) 136 can be assembled after printing using, e.g., one or more of adhesives, mechanical fasteners, alignment features, etc., or combinations thereof. In particular embodiments, as an example, snap fit features and/or mechanical fasteners can be used to hold the component through the curing cycle of adhesives during assembly. In alternative embodiments, the structural member(s) 136 described herein can be assembled after vacuum forming but prior to printing using, e.g., adhesives. In additional embodiments, the structural member(s) 136 can also be assembled during the printing process. For example, in such embodiments, the structural member(s) 136 can also be assembled during the printing process using manual or automated means, both with and without pausing the printheads 320 (i.e., when the printheads were printing in another area).


In addition, the outer skin(s) 56 may include one or more registration marks or features integrated therein to aid in locating the structural member(s) 136 in certain locations. In particular embodiments, heat from the thermoforming mold can be used to also promote faster curing of the adhesive used. Another aspect of the apparatus 300 may also include printing directly onto the structural member(s) 136 to further connect the printed grid structures 62 to the structural member(s) 136. For example, if the structural member(s) 136 is constructed of a compatible thermoplastic or thermoplastic fiber reinforced component, such overlap printing can be particularly beneficial.


In additional embodiments, a spanwise structural members 136 can be used on the leading and/or trailing edge sides of the gap 132, 134 if desired, as well as individual chordwise ribs. Furthermore, design of the apparatus 300 can be optimized to minimize the gaps described herein, though a three-axis motion system typically cannot completely eliminate the gap without contacting the previously printed grid. In further embodiments, a four or more axis system can effectively print a new grid zone adjacent to a previously printed grid zone but with a significant tradeoff in complexity. In one embodiment, the gap(s) may be at least about 12 mm. In certain embodiments, where spanwise gaps are included, the apparatus 300 may be configured to structurally connect these zones together using various suitable techniques. For example, for relatively narrow gaps within the capability of a given adhesive, the gap(s) can be filled with adhesive either manually or via a dedicated adhesive dispensing device incorporated into the printer or as a separate standalone system. If adhesive is applied while the component still resides in the mold, heat from the vacuum forming (i.e., used to form the skins) and printing process can be utilized to accelerate cure of the adhesive.


Referring particularly to FIG. 51, a cross-sectional view of another embodiment of the composite component 210 including the printed grid structure 62 printed onto the skin(s) 56 according to the present disclosure is illustrated. As shown, the composite component 210 includes a scarf angle 135, which is beneficial since 3-D printers can print small overhangs. For example, in 3-D printing, small overhangs can be printed where, depending on the material and other printing factors, a small amount of material can be printed without support from material directly beneath it. Thus, by selecting an appropriate angle or arched shape, the first zone edge interfaces can be printed at a suitable angle or curved profile such that when the matching edges at the next zone are printed, the interface of each profile may match or overlap, thereby leaving a small gap suitable for adhesive bonding. In yet another embodiment, the scarf angle or interface curve can be selected such that when the second zone is printed, the angle or curved surface is sufficient to allow the matching grid with overhangs to prevent the printhead from striking the grid material from the first zone. In particular embodiments, the design of the printhead shape is one consideration for the design of the interface. For example, as shown in FIG. 53, a printhead with a 45-degree conical shaped extruder may be useful in printing a scarf angle interface of approximately 45-degrees or less. In certain embodiments, where the gaps are small, the area can be filled with adhesive or thermally welded by adding filler material. In the cases of overlaps or just matched printing, the grid structure 62 can be additionally thermally fused with addition of localized heating. In addition, as shown in FIG. 52, the grid structure 62 in the scarfed zone can also be reinforced using other options discussed herein and or by addition of a suitable plate 137, laminate, or the like that is bonded over the scarfed area on one or both sides.


In further embodiments, the adhesive(s) described herein can be applied in an automated way (e.g., via an adhesive dispensing system coupled with the apparatus 300 or a separate system) during the print cycle or manually after printing is complete. If desired, the mold temperature can also be adjusted higher or lower after the printing process is complete to optimize the adhesive cure cycle. For some adhesives, complete gap filling may create an exotherm from the curing adhesive which may cause local temperatures to rise too high and melt, burn or otherwise damage surrounding materials (grid, skin, etc.). In these cases, strategies to reduce the amount of adhesive and thus reduce the exothermic reaction impact may be considered.


Another gap filling technique is the insertion of one or more spanwise structural members 136 (such as shown in FIG. 47). Further, in an embodiment, one of the structural members 136 can be placed in a spanwise gap that is between two first zones and also in between two second first zones, while the same structural member crosses through a chordwise gap between the first and second zones. A benefit of including such structural members 136 may include, as an example, minimizing adhesives needed to connect printed zones to each other and to provide a connection means that is structurally superior to adhesive only connection methods. Further, the structural member(s) 136 may be constructed of any suitable material that can be connected to the grid structure 62 and/or skins 56 described herein. In addition to adhesives, other securement means may be used, such as mechanical fasteners and thermal welding, as well as snap fits designed into the printed grid structure 62 that can effectively hold the stiffening member in place after insertion.


In particular embodiments, a combination of connection means may be used to allow for easy insertion of the structural members 136 followed by secondary attachment to further secure the members in place. One benefit of the combination approach may be that the grid structure 62 can become its own fixture for holding the structural members 136 in place during adhesive cure or welding for example. Furthermore, in an embodiment, the printing of chordwise zones may be particularly useful for spanwise structural members 136 with the apparatus 300. In particular, the printing of chordwise zones allows for separating of one large zone into two or more chordwise zones with one or more spanwise gaps, with the spanwise gap(s) subsequently being filled not only with a short spanwise structural member (e.g., as shown in FIGS. 45 and 46) but also with a longer spanwise structural member 136 (as shown in FIG. 47 that can span (and therefore structurally connect) across multiple spanwise printed zones as well. However, if the apparatus 300 is arranged with the printheads 320 in a chordwise direction rather than a spanwise direction, then the spanwise zones would be desirable to cut down layer time.


In particular embodiments, as shown in FIGS. 45 and 46, various embodiments of the grid pattern 62 described herein, each including a plurality of structural member(s) 136 as described herein are illustrated. In particular, as shown in FIG. 45, each grid zone 65 is printed to face the same direction (i.e., all of the “cups” are open to the same direction. In such embodiments, a plurality of the structural members 136 can be placed between two grid zones 65 to connect such zones 65 together. Alternatively, as shown in FIG. 46, one grid zone 65 may face a first direction, whereas a second grid zone 65 may face an opposing direction. In such embodiments, a plurality of the structural members 136 can also be placed between the two grid zones 65 to connect such zones 65 together.


In addition, overlapping portions of the grid structures 62 described herein can be employed that allow for printed material to cross through the chordwise gap(s) between printed zones 65 such that the portions extend into the open cup area of the stacked cup design, provided that the appropriate distance between previously printed material from another zone is maintained to avoid printhead crash. In some cases, the present disclosure may also encompass printing an individual grid pattern using a single printhead that allows for this type of overlap between zones. This separate grid structure 62 will generally be a fast layer time design, but can add to the overall cycle time as it is independently printed with a single printhead between spanwise zones, i.e., unless there are additional printheads that can print in this area while other groups of printheads are printing elsewhere. An alternative embodiment, if the structural properties allow, the apparatus 300 may be configured to print multiple grid structures 62 that are independent and separate from each other to maximize layer time. In such embodiments, additional structural members 136 or fillers can be used to connect to the separate grid structures 62 so as to provide the desired level of panel rigidity. In another embodiment, one or more interlocking features may be secured within the gaps between the separate grid structures, such as for example, injection molded parts, separately printed parts, and/or any other suitable component.


For example, as shown in FIG. 48, an independent grid structure 162 can be first printed onto the outer skin(s) 56. Such independent grid structure 162, as an example, can be printed by a single printhead 320 before, during, or after other zones 65 are printed. Remaining grid zones 65 may be printed around the independent grid structure 162 and an optional adhesive 164 can be provided therebetween.


Moreover, as shown in FIG. 50, the grid structure 62 may be formed of multiple zones 65, with each zone 65 separated via a gap. In addition, as shown, though the zones 65 are separated by a gap, the zones 65 extend into each other, e.g., one of the U-shaped protrusions of one zone extends within a gap created by an adjacent zone.


This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

Claims
  • 1. An apparatus for manufacturing a composite component, the apparatus comprising: a mold onto which the composite component is formed, wherein the mold is disposed within a grid defined by a first axis and a second axis;a first frame assembly disposed above the mold; and,a first group of printheads coupled to the first frame assembly within the grid in an adjacent arrangement along the first axis, each of the printheads defining an extruder,wherein the first group of printheads is moveable together along at least one of the first axis and the second axis,a mechanism configured to articulate the first group of printheads about the mold; anda control unit configured to control the mechanism, the control unit comprising at least one processor, the processor configured to implement a plurality operations, the plurality of operations comprising: instructing the first group of printheads to deposit a first volume of fluid composite in a predesigned pattern at a first zone on the mold via the extruders to form a first plurality of printed rows;pausing depositing of the fluid composite;aligning the first group of printheads to a second zone on the mold; andinstructing the first group of printheads to deposit a second volume of the fluid composite in the predesigned pattern at the second zone to form a second plurality of printed rows, the first and second plurality of printed rows forming a grid structure, wherein adjacent printed rows in each of the first and second plurality of printed rows comprise side walls that partially overlap each other to define overlapping portions, and wherein the first and second plurality of printed rows of the first and second zones are separated by a gap.
  • 2. The apparatus of claim 1, wherein the first group of printheads extends along a length that is less than an overall length of the composite component.
  • 3. The apparatus of claim 1, further comprising a plurality of first groups of printheads mounted to the first frame assembly.
  • 4. The apparatus of claim 3, wherein two or more of the plurality of first groups of printheads move together along the first axis and/or the second axis.
  • 5. The apparatus of claim 1, wherein one or more of the plurality of first groups of printheads comprise multiple rows of print heads.
  • 6. The apparatus of claim 1, wherein at least two of the first groups of printheads are spaced apart from each other by a predetermined distance, such that, the at least two of the first groups of printheads print the fluid composite at the at least two first zones, then move to at least two second zones on the mold and then print the fluid composite at the at least two second zones.
  • 7. The apparatus of claim 1, wherein each of the plurality of printheads defines a centerline axis at least partially along a third axis, and wherein a distance between each adjacent pair of centerline axes of the plurality of printheads corresponds to a desired spacing of a structure of the composite component to be formed.
  • 8. The apparatus of claim 1, wherein the first axis is substantially parallel to a length of the composite component, and wherein the second axis is substantially parallel to a width of the composite component, and further wherein the width is generally perpendicular to the length of the composite component.
  • 9. The apparatus of claim 1, wherein the plurality of first groups of printheads is extended along the first axis equal to or greater than a length or a width of the composite component to be formed onto the mold.
  • 10. The apparatus of claim 1, further comprising a plurality of second groups of printheads mounted to a second frame assembly.
  • 11. The apparatus of claim 1, wherein the first and second zones are aligned along the first axis.
  • 12. The apparatus of claim 11, wherein the first axis is substantially parallel to at least a portion of a spar cap of a rotor blade.
  • 13. The apparatus of claim 1, wherein the first and second zones are aligned along the second axis.
  • 14. The apparatus of claim 1, wherein the mechanism is further configured to place one or more structural members in the gap between or adjacent to the first and second plurality of printed rows of the first and second zones.
  • 15. (canceled)
  • 16. The apparatus of claim 1, wherein the predesigned pattern comprises a stacked-cup design.
  • 17. The apparatus of claim 16, wherein each of the first and second plurality of printed rows comprise a plurality of U-shaped protrusions, and wherein the U-shaped protrusions of adjacent printed rows are inline with each other.
  • 18. The apparatus of claim 16, wherein each of the first and second plurality of printed rows comprise a plurality of U-shaped protrusions, and wherein the U-shaped protrusions of adjacent rows are offset from each other.
  • 19-26. (canceled)
  • 27. A composite component, comprising: a three-dimensional stabilizing structure; anda substantially two-dimensional monolithic panel at least partially enveloping and securing the stabilizing structure,wherein the stabilizing structure comprises a patterned architecture formed of a first plurality of printed rows and a second plurality of printed rows secured onto the monolithic panel, andwherein adjacent printed rows in each of the first and second plurality of printed rows comprise side walls that partially overlap each other to define overlapping portions, and wherein the first and second plurality of printed rows of the first and second zones are separated by a gap.
  • 28. The composite structure of claim 27, wherein the monolithic panel comprises: an inner skin at least partially vacuum infused or co-cured with an interface polymer layer.
  • 29. The composite structure of claim 28, wherein the inner skin and the interface polymer layer are rapid cured and subsequently post cured.
  • 30-40. (canceled)
CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Patent Application Nos. 63/043,184, 63/043,191, and 63/043,200, all three filed on Jun. 24, 2020, which are incorporated by reference herein in their entirety.

PCT Information
Filing Document Filing Date Country Kind
PCT/US2021/038807 6/24/2021 WO
Provisional Applications (3)
Number Date Country
63043184 Jun 2020 US
63043191 Jun 2020 US
63043200 Jun 2020 US