1. Field of the Invention
The present disclosure relates generally to additive manufacturing, and more particularly to particulate materials for additive manufacturing techniques.
2. Description of Related Art
Aircraft commonly employ electrical and electromagnetic components such as motors, inductors, sensors, and power distribution systems. Such electrical and electromagnetic components often include electrical conductors. The electrical conductors generally include etchings, laminations, windings or other structures formed from an electrically conductive material with geometry suitable for the type of electrical power intended to be applied to the electrical conductor. The material is typically selected for a specific property or set of properties, such as electrical conductivity, thermal conductivity, dielectric strength, or magnetic permeability. Such conductors commonly include copper or copper alloys owing to the generally favorable properties of such materials. In some applications electrical and electromagnetic components formed by such materials may operate relatively close to the maximum ampacity of the material forming the electrical conductor. Such electrical conductors may also be relatively heavy due to the use of bulk copper, particularly in relatively high current applications contemplated in some types of aircraft electrical systems.
Such conventional electrical and electromagnetic components and methods of making electrical components have generally been considered satisfactory for their intended purpose. However, there is still a need in the art for improved electrical and electromagnetic components. The present disclosure provides a solution for this need.
A method of making a composite material includes disposing a carbon-based particulate material, such as graphene platelets, in an activation solution, and activating surfaces of the carbon-based particulate material using the activation solution. Once the surfaces of the carbon-based material are activated a metallic coating is applied to the activated surfaces, thereby forming a composite material. The composite material is then recovered as a particulate, the particles forming the particulate material having carbon-based particle bodies with a metallic coating that are suitable for fusing together to form electrical conductors using an additive manufacturing technique.
In certain embodiments, the carbon based particulate material includes graphene particulate. The graphene particulate includes one or more graphene platelets with a plate-like body and having a metallic coating. The plate-like body can have an irregular shape. The plate-like body can define a hole, a cavity, or a depression. The plate-like body can have one or more edges. The composite material can form a relatively fine particulate material, and may include either or both micro and nanoparticles.
In accordance with certain embodiments, the metallic coating can extend over substantially the entire surface of the one or more graphene platelets. The metallic coating may have a uniform thickness over the surface of the graphene platelet. The metallic coating can be fixed to features defined by the graphene platelet, such as the holes, cavities, depressions, and/or edges. The metallic coating can include an electrically conductive material, such as copper, gold, or any other suitable electrically conductive material. The composite material may have greater ampacity than a copper-containing conductor, may be less dense than bulk copper or copper-containing alloys, and may be more dense than the constituent graphene particulate.
It is also contemplated that, in accordance with certain embodiments, the composite material can be integrated (e.g. fused) to form an electrical conductor. The electrical conductor can be a discrete structure, such as a wire or winding for an electrical component of an aircraft electrical system. The electrical conductor can form a layer, such as a foil, for a circuit board. In certain embodiments the layer (or foil) can form a conductor for a high current capacity device, and can have a current rating from 5 to 15 amps or any suitable range. The conductor can be integral with a component of an electrical system, such artwork defined on a printed circuit board or within circuitry of a solid-state device. The electrical conductor may be formed from the composite material using an additive manufacturing process, such as with laser engineering net shaping, a laser fusing, electron beam fusing, powder bed fusion, cold spray, kinetic metallization, wire arc, or any other suitable additive manufacturing technique.
In another aspect, a method of making a composite material includes disposing a carbon-based particulate material, such as graphene platelets or carbon nanotubes, in an activation solution. Surfaces of the carbon-based particulate material are then activated using the activation solution. A metallic coating is thereafter developed (or applied) to the activated surfaces of the carbon-based particulate material.
In embodiments, the activation solution(s) can include tin dichloride and/or palladium chloride. Activating surfaces of the carbon-based particulate material can include using a plurality of activation solutions, such as by sequentially disposing the carbon-based particulate material in first activation solution including a tin dichloride solution, and thereafter disposing the carbon-based particulate material in a second activation solution including a palladium chloride solution. Subsequent to disposing the carbon-based particulate material in the one or more activation solutions the material can be removed from the activation solution, such as by filtering, rinsed, such as with de-ionized water, and/or dried to remove the de-ionized water (and/or residual activation solution) from the carbon-based particulate material.
In accordance with certain embodiments, applying the metallic coating to the carbon-based particulate material can include coating the carbon-based particulate material using an electroless plating technique. Applying the metallic coating can include disposing the carbon-based particulate material with activated surfaces in a plating solution, and agitating the mixture for a predetermined period of time. The plating solution can include copper (II) sulfate pentahydrate, disodium ethylenediaminetetraacetate dihydrate, and hydrazine, and applying the metallic coating can occur within a temperature range between 30 and 50 degrees Celsius, and in an exemplary embodiment at about 40 degrees Celsius. The plating solution may have a pH that is between 10.5 and 13, and in exemplary embodiment can have a pH of about 12. The metallic coating can be a first metallic coating, and the method can further include applying a second metallic coating over the entire first metallic coating, such as by (a) activating the surface of the first metallic coating in one or more activation solutions as described above, (b) disposing the metallic coated carbon-based particulate material in a second plating solution, and (c) developing the second coating using an electroless plating technique.
These and other features of the systems and methods of the subject disclosure will become more readily apparent to those skilled in the art from the following detailed description of the preferred embodiments taken in conjunction with the drawings.
So that those skilled in the art to which the subject disclosure appertains will readily understand how to make and use the devices and methods of the subject disclosure without undue experimentation, embodiments thereof will be described in detail herein below with reference to certain figures, wherein:
Reference will now be made to the drawings wherein like reference numerals identify similar structural features or aspects of the subject disclosure. For purposes of explanation and illustration, and not limitation, a partial view of an exemplary embodiment of a composite material in accordance with the disclosure is shown in
Referring now to
Graphene bodies 12 each have a respective platelet body 14. Platelet body 14 includes one or more holes (or cavities) 16 that extend through platelet body 14. Platelet body 14 also has one or more edges 18 defined at a periphery of platelet body 14 and/or hole (or cavity 16). At the outer periphery of platelet body 14 edge 18 traces an irregular shape and bounds a plate-like body, which is illustrated in an exaggerated, two-dimensional form in
Composite material 10 includes a metallic coating 20 is disposed over a surface 22 of platelet body 14. Surface 22 includes the area of platelet body 14, edge 18, and the portions of platelet body 14 bounding hole (or cavity) 16. Metallic coating 20 has a coating thickness D that is substantially uniform over the entire surface of platelet body 14—including surface 22, edge 18, and the interior of hole (or cavity) 16. It is contemplated that coating 20 is a monolayer with a thickness of about fifty (50) microns. As indicated in the progression indicated with reference letters A-C, it is contemplated that the graphene platelets (shown in A) have coating 20 be applied (shown in B) and that the coated platelet bodies are thereafter be integrated into a composite conductor 50 (shown in C). Composite conductor 50 may be a discrete structure for an aircraft electrical system, such as a wire or cable. Alternatively, composite conductor 50 may be integrally formed with an electronic component such as artwork formed on a printed circuit board or feature defined within a solid-state device.
Referring to
With reference to
Once the surfaces of the graphene platelets have been activated the metallic coating is applied to the graphene platelets, as shown with box 130. The metallic coating can be applied using an electroless plating technique, as shown with box 132, and can be applied such that uniform metallic coating or predetermined thickness is fixed to (and overlays) the graphene platelet body. Electroless plating exploits a redox reaction that can deposit metals such as elemental copper upon particulate substrates such as graphene platelets without using an electrical current. Electroless plating allows for depositing copper evenly along edges, inside holes and over irregularly shaped features presented by the graphene platelets to provide a uniform metallic coating. Advantageously, deposition may occur over substantially the entire body, which can be advantageous for materials including graphene where the ratio of surface area to mass is relatively high. In embodiments, coating the graphene platelets may include disposing the activated graphene platelets in a plating solution for a predetermined time interval, e.g. 1-2 hours. In certain embodiments, the activated graphene platelet-activation solution mixture is agitated (stirred) to facilitate development of the coating over activated surfaces of the graphene platelets.
Once the metallic coating has been developed on activated surfaces of the graphene platelets the platelets are treated, as shown with box 140. This may include rinsing the coated graphene platelets using de-ionized water. It may also include drying the coated the graphene platelets to accelerate removal of the de-ionized water and/or residual plating solution from the coated graphene platelets. As also indicated by arrow 170, surface activation, application of the coating, and post-coating treatment can be iteratively repeated for purpose of developing a coating of suitable thickness—thereby controlling the ratio of metal to graphene in the resulting composite material.
Optionally, method 100 can also include recovery of the coated graphene platelets to produce a powdered particulate material, as shown with box 150. The powdered particulate material can be used to form a composite conductor, e.g. composite conductor 50 (shown in
Referring now to
Optionally, method 200 may include two or more surface activation steps. For example, subsequent to the disposing the graphene platelets in the tin chloride activation solution, the graphene platelets may be disposed in a palladium chloride solution, as shown with box 240. After a predetermined time interval (typically several minutes) the graphene platelets can then be removed from the palladium chloride activation solution, as shown with box 250. Removal of the activated graphene platelets may include further filtration, as shown with box 252, and further rinsing and/or drying, as shown with box 260. Either or both to the surface activation operations may be repeated iteratively, as indicated by arrow 270, such that surfaces of the graphene platelets can be suitably condition for application of the metallic coating.
In an exemplary embodiment of method 200, a predetermined amount of graphene platelets are activated by successive exposures to a relatively dilute tin chloride solution and a relatively dilute palladium chloride solution—activating surfaces of the graphene platelets and rendering them amenable to coating.
With reference to
Returning to
With reference to
Coated graphene particles are then available for extraction from the plating solution that have a density that is greater than graphene, have ampacity similar to that of graphene, and have electrical conductivity similar to that of bulk copper. Once recovered from the plating solution, the coated graphene platelets can form a composite material suitable as feedstock for an additive manufacturing process, such as laser engineered net shaping, laser fusion, powder bed fusion, electron beam fusion, laser sintering, cold spray, kinetic metallization, wire arc or other suitable additive manufacturing techniques. Advantageously, the input energy from certain additive manufacturing techniques enables densification of the powder while forming a functional structure or article (e.g. a discrete or integrated composite conductive structure).
The methods and systems of the present disclosure, as described above and shown in the drawings, provide for conductors with superior properties including reduced size and weight for a given ampacity in relation to bulk copper or copper alloy conductors. The conductors have the electrical properties of graphene (i.e. high ampacity) and copper (i.e. high electrical conductivity), and may further provide improved thermal conduction and/or reduced voltage drop relative to bulk copper or copper alloy conductors. While the apparatus and methods of the subject disclosure have been shown and described with reference to preferred embodiments, those skilled in the art will readily appreciate that changes and/or modifications may be made thereto without departing from the scope of the subject disclosure.
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