EP-3422365-B1 - STRUCTURES FORMED FROM HIGH TECHNOLOGY CONDUCTIVE PHASE MATERIALS

Inventors

• Sheedy, Paul
• SCHMIDT, WAYDE R.

Dates

Publication Date

20260506

Application Date

20180628

Claims (6)

1. A method of forming a bulk product comprising the step of: coating a particulate conductive phase material (20) with a binder phase using a deposition coating process, and forming the coated conductive phase material into a bulk material; wherein there is an intermediate layer coating (24) between the conductive phase and the binder phase, and wherein the intermediate layer coating (24) is a metal carbide and the binder phase is a transition metal; wherein the binder phase coating (23) is less than 100 microns thick; and wherein said binder phase transition metal is copper, said intermediate layer coating is molybdenum carbide, and said particulate conductive phase material is graphene.
2. The method as set forth in claim 1, wherein the particulate conductive phase materials are in the shape of at least one of a powder, fibers, nanotubes, whiskers, spheres, and platelets.
3. The method as set forth in any preceding claim, wherein the deposition process is one of molecular layer deposition, atomic layer deposition, and vapor phase, spray, paint, plating, solution dipping, electrostatic or electrophoretic deposition or other suspension deposition methods.
4. The method as set forth in any preceding claim, wherein the particulate conductive phase materials (20) are in the shape of at least one of two dimensional materials, single layer materials, powder, fibers, nanotubes, whiskers, spheres, and platelets.
5. The method as set forth in any preceding claim, wherein the bulk material is at least one of sheet stock, tape, ribbons, wires, or other geometries including a final component.
6. A component comprising: at least a portion of a component body formed of a particulate conductive material (20) coated by a binder phase coating (23) formed into bulk material, such that the component body includes both binder phase coating and the particulate conductive material, and said conductive phase material includes at least one of two dimensional materials, single layer materials, graphene, boron nitride nanotubes, aluminum nitride and molybdenum disulphide (MoS 2 ), wherein the particulate conductive phase material are in the shape of at least one of a powder, fibers, nanotubes, whiskers, spheres, and platelets; wherein there is an intermediate layer coating (24) between the conductive phase and the binder phase, and wherein the intermediate layer coating (24) is a metal carbide and the binder phase is a transition metal; wherein the binder phase coating (23) is less than 100 microns thick; and wherein said binder phase transition metal is copper, said intermediate layer coating is molybdenum carbide, and said particulate conductive phase material is graphene.

Description

BACKGROUND OF THE INVENTION This application relates to a method and structures wherein a binder layer is coated onto highly engineered conductive materials. Modern industrial systems are becoming more and more complex and the challenges are increasing. As examples, the ability to transmit high voltage and current levels through electric conductors raises challenges for the materials historically utilized. In addition, heat exchangers are being challenged with higher and higher heat loads. Again the materials which have historically been utilized may not be sufficiently conductive. Highly engineered modern materials are better equipped to provide the required conductivity. However, in general, such materials are not yet widely available in bulk form appropriate for manufacture of fuel components. Typically, materials, such as graphene, carbon nanotubes, boron nitride nanotubes, aluminum nitride, or molybdenum disulphide (MoS2) may be examples of such highly engineered materials. Such materials may be available as fibers, nanotubes, whiskers, spheres, platelets, powder, etc. In such particulate shapes, the materials are not easily manufactured into real world components. CN 105861866 A discloses a metal-matrix composite material and preparation method thereof. SUMMARY OF THE INVENTION A method of forming a bulk product is provided as claimed in claim 1 and includes the step of coating a particulate conductive phase material with a binder phase using a deposition coating process. Then the coated conductive phase material is formed into a bulk material. A method of forming a bulk product includes the step of coating a particulate conductive phase material with a binder phase and forming the coated conductive phase material into a bulk material. The conductive phase material is graphene. A component is also discosed, as claimed in claim 6. These and other features may be best understood from the following drawings and specification. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows an example of a highly engineered conductive material.Figure 2 shows a coating applied to the material.Figure 3 shows a consolidation stage.Figure 4 shows one real world component manufactured by this method.Figure 5 shows another real world component.Figure 6 shows a process flow to create a bulk product using the described method DETAILED DESCRIPTION A highly engineered conductive material 20 is illustrated in Figure 1. As mentioned above, the material includes graphene. Other examples of conductive materials include carbon nanotubes, boron nitride nanotubes, aluminum nitride, molybdenum disulphide (MoS2), various carbides or nitrides, such as those of Ti and Si, other related materials and mixtures thereof. Also, the materials may be single layer or two-dimensional materials. So-called "2D" materials are crystalline materials formed of a single layer of atoms. While these materials are shown in this figure as powders, they may also be fibers, nanotubes, whiskers, spheres, platelets, etc., including combinations of these. Collectively, these are referred to as particulate conductive phase material. The particulate conductive phase material used in the method of claim 1 and of the component of claim 6 is graphene. The conductivity may be electric and/or thermal depending on the final application. As examples, graphene platelets have extremely high electrical and thermal conductivity in-plane. Aluminum nitride has high thermal conductivity, but very low electrical conductivity. Other properties of these several considered materials are also known. The particulate conductive materials are coated with a binder phase layer. This is shown in Figure 2, at 22. The conductive phase material 20 is shown in an inner portion and the binder coating 23 is shown outwardly. Intermediate or interlayers 24 may also be included. The binder layer is extremely thin and may be provided such as by atomic layer deposition. Other deposition coating processes may be used. The binder phase is copper. The binder phase coating has a thickness of less than 100 microns. The binder layer materials are selected for their capability to preferentially deform or flow with the highly engineered materials during the consolidation step as described below. In some applications, the binder phase may be on the order of 1 nanometer to 100 microns in thickness. The binder phases are primarily selected as metals for their beneficial thermal and electrical conductivities, subsequent processability, as well as resistance to corrosion in corrosive environments. The interlayer coatings can include one or more metal, metallic carbides or other compounds to enhance wetting of the binder layer, or to provide another beneficial function such as modifying the thermal or electrical conductivity, altering the layer thickness, introducing a reactive phase, controlling the coefficient of thermal expansion and the like. A metallic outer coating of copper may be applied as the binder phase o