The technical field of this disclosure relates generally to a thermal barrier coating that comprises an insulating layer having one or more layers of hollow microspheres and, more specifically, to methods of preparing the same.
Thermal barrier coatings are a class of insulating coatings designed for application to metal surfaces that operate at elevated temperatures. For example, in certain industries, such as the automotive industry, the advent of new materials and advanced thermomechanical systems along with an interest in exhaust heat management has created a need for certain metal component parts to be able to endure intense heat and thermal loading over a prolonged period of time. The internal combustion engine and the engine exhaust system are two notable systems within an automobile where thermal barrier coatings can be useful due to the temperatures associated with combusting an air/fuel mixture and the management of combustion byproducts. Thermal barrier coatings are theoretically well suited for these and other applications since they can effectively limit the thermal exposure of the underlying metal and prevent heat from escaping to the surrounding ambient environment, which can extend the life of the component part and improve system efficiencies. While a variety of thermal barrier coatings are already known, the pursuit of new thermal barrier coatings and related techniques for applying those coatings to simple and complex part surfaces is ongoing.
A method of forming a thermal barrier coating on a metal component part according to one embodiment of the disclosure includes several steps. First, a metallic precursor setting layer is adhered onto a surface of a ferrous alloy or nickel alloy component part. The precursor setting layer is a layer of copper, a copper alloy, or a nickel alloy. Second, hollow microspheres are located against the component part so that the hollow microspheres contact the metallic precursor setting layer. The hollow microspheres have an outer layer of nickel, a nickel alloy, iron, or an iron alloy. Third, the metallic precursor setting layer is heated to a temperature above the liquidus temperature of the precursor setting layer to melt the precursor setting layer and wet a layer of hollow microspheres located adjacent to the surface of the component part. Fourth, the precursor setting layer is cooled to a temperature below the solidus temperature of the precursor setting layer to solidify the precursor setting layer and bond the layer of hollow microspheres to the surface of the component part. Fifth, the hollow microspheres that are not bonded by the metallic precursor setting layer are moved away from the component part. And sixth, the ferrous alloy or nickel alloy component part and the layer of hollow microspheres bonded to the surface of the component part are heated to sinter the hollow microspheres to each other and to the surface of the component part such that a solid state joint is formed between the layer of hollow microspheres and the surface of the ferrous alloy or nickel alloy component part.
The hollow microspheres, the metallic precursor setting layer, and the ferrous alloy or nickel alloy component part may be further defined. The hollow microspheres may be constructed in a variety of ways to support their outer layer of nickel, a nickel alloy, iron, or an iron alloy. In one embodiment, for example, at least some of the hollow microspheres include a hollow glass base wall coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy. In another embodiment, at least some of the hollow microspheres include a hollow polymeric base wall coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy. And, in still another embodiment, at least some of the hollow microspheres include a hollow ceramic base wall coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy. Moreover, the ferrous alloy or nickel alloy component part may be an engine piston, an intake valve, an exhaust valve, an engine block, an engine head, an exhaust gas pipe, or a turbocharger housing, to name but a few examples, and the metallic precursor setting layer may be adhered in place to a thickness that ranges from 0.1 μm to 20 μm.
The several steps of the disclosed method for forming the thermal barrier coating may be performed in certain preferred ways. To be sure, the ferrous alloy or nickel alloy component part and the layer of hollow microspheres bonded to the surface of the component part may be heated to sinter those entities together and thereby form the solid state joint by heating the microspheres and the component part to a temperature below the solidus temperature of the precursor setting layer for a period of time at least until the metallic precursor setting layer dissolves into the outer layer of the hollow microspheres and the ferrous alloy or nickel alloy component part. For example, if the precursor setting layer is copper, the solidus and liquidus temperature of the metallic precursor setting layer is the melting temperature of copper or 1085° C. In that regard, heating the metallic precursor setting layer to above the liquidus temperature comprises heating the metallic precursor setting layer to above 1085° C., cooling the metallic precursor setting layer to below the solidus temperature comprises cooling the metallic precursor setting layer to below 1085° C., and an option for heating the ferrous alloy or nickel alloy component part and the layer of hollow microspheres to sinter the hollow microspheres to each other and to the surface of the component part would be to heat the layer of hollow microspheres and the component part to a temperature in the range of 800° C. and 1085° C.
Prior to heating the ferrous alloy or nickel alloy component part and the hollow microspheres to sinter the hollow microspheres to each other and to the surface of the component part, additional layers of hollow microspheres may be deposited on top of the first initially deposited layer. To deposit a second layer of hollow microspheres, the method of forming a thermal barrier coating may further include adhering a second metallic precursor setting layer onto the layer of hollow microspheres bonded to the surface of the ferrous alloy or nickel alloy component part. The metallic precursor setting layer may again be a layer of copper, a copper alloy, or a nickel alloy. Next, hollow microspheres are located against the component part so that the hollow microspheres contact the second metallic precursor setting layer overlying the layer of hollow microspheres bonded to the surface of the component part. The hollow microspheres have an outer layer of nickel, a nickel alloy, iron, or an iron alloy. The second metallic precursor setting layer is then heated to a temperature above its liquidus temperature to melt the second metallic precursor setting layer and wet a second layer of hollow microspheres located adjacent to the layer of hollow microspheres bonded to the surface of the component part, followed by cooling the second metallic precursor setting layer to a temperature below its solidus temperature to solidify the second metallic precursor setting layer and bond the second layer of hollow microspheres to the layer of hollow microspheres bonded to the surface of the component part. Any hollow microspheres that are not bonded to the second metallic precursor setting layer are eventually moved away from the component part.
More than one additional layer of hollow microspheres may be deposited on top of the first initially deposited layer. Indeed, the additional steps recited above with regard to depositing the second layer of hollow microspheres may be repeated as many times as desired to sequentially deposit additional layers of hollow microspheres on top of the second layer of hollow microspheres. Once all the layers of the hollow microspheres are deposited, the heating of the ferrous alloy or nickel alloy component part and the layer of hollow microspheres to sinter the hollow microspheres to each other and to the surface of the ferrous alloy or nickel alloy component part includes sintering all of the sequentially applied layers of hollow microspheres together and to the surface of the ferrous alloy or nickel alloy component part.
A method of forming a thermal barrier coating on a metal component part according to another embodiment of the disclosure includes several steps. First, one or more layers of hollow microspheres are deposited onto a surface of a ferrous alloy or nickel alloy component part. The hollow microspheres of each of the one or more layers have an outer layer of nickel, a nickel alloy, iron, or an iron alloy, and each of the one or more layers of hollow microspheres is bonded to either the surface of the ferrous alloy or nickel alloy component part or to a previously deposited layer of hollow microspheres by a metallic precursor setting layer of copper, a copper alloy, or a nickel alloy. Second, the one or more layers of hollow microspheres and the ferrous alloy or nickel alloy component part are heated to sinter the hollow microspheres to each other and to the surface of the component part to thereby produce an insulating layer. And third, a gas-impermeable sealing layer is applied over the insulating layer to form a thermal barrier coating over the surface of the ferrous alloy or nickel alloy component part.
Depositing a first layer of hollow microspheres onto the surface of the ferrous alloy or nickel alloy component part may include adhering a metallic precursor setting layer onto the surface of the ferrous alloy or nickel alloy component part followed by placing hollow microspheres in contact with metallic precursor setting layer, heating the metallic precursor setting layer to a temperature above its liquidus temperature to melt the metallic precursor setting layer and wet a layer of hollow microspheres, cooling the metallic precursor setting layer to a temperature below its solidus temperature to solidify the metallic precursor setting layer and bond the layer of hollow microspheres to the surface of the component part, and moving hollow microspheres that are not bonded to the metallic precursor setting layer away from the component part. Only this first layer of hollow microspheres may be deposited or, alternatively, additional layers of hollow microspheres may be deposited on top of the first layer.
Similarly, depositing each additional layer of hollow microspheres onto the surface of the ferrous alloy or nickel alloy component part may include adhering another metallic precursor setting layer onto a previously deposited layer of hollow microspheres, placing hollow microspheres in contact with the another metallic precursor setting layer, heating the another metallic precursor setting layer to a temperature above its liquidus temperature to melt the another precursor setting layer and wet another layer of hollow microspheres located adjacent to the previously deposited layer of hollow microspheres, cooling the another metallic precursor setting layer to a temperature below its solidus temperature to solidify the another precursor setting layer and bond the another layer of hollow microspheres to the previously deposited layer of hollow microspheres, and moving hollow microspheres that are not bonded to the another metallic precursor setting layer away from the component part
The hollow microspheres, the insulating layer formed from the deposited layers of hollow microspheres, and the gas-impermeable sealing layer may be further defined. For example, the hollow microspheres in each of the one or more layers of hollow microspheres may comprise (1) glass base walls coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy, (2) polymeric base walls coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy, or (3) ceramic base walls coated externally with a layer of nickel, a nickel alloy, iron, or an iron alloy. Furthermore, regarding the insulating layer, it may have a thickness that ranges from 5 μm to 5 mm depending on the size of the hollow microspheres and the number of layers of hollow microspheres deposited onto the surface of the component part. The gas-impermeable sealing layer applied over the insulating layer may be composed of nickel, stainless steel, a nickel-based superalloy, vanadium, molybdenum, or titanium.
In some implementations of the method of forming a thermal barrier coating, the metallic precursor setting layer that bonds each layer of hollow microspheres to either the surface of the ferrous alloy or nickel alloy component part or to a previously applied layer of hollow microspheres is composed of copper. The liquidus and solidus temperatures of copper are the same—i.e., 1085° C. Accordingly, when each of the metallic precursor setting layer is composed of copper, an option for heating the ferrous alloy or nickel alloy component part and the one or more layers of hollow microspheres to sinter the hollow microspheres to each other and to the surface of the ferrous alloy or nickel alloy component part would be to heat the component part and the one or more layers of hollow microspheres to a temperature in the range of 800° C. and 1085° C.
Thermal barrier coatings are useful in a wide range of applications where protection of the underlying metal from elevated temperatures and/or insulation against heat loss to the surrounding ambient environment is desired. In the present disclosure, a thermal barrier coating is described that includes an insulating layer comprised of one or more layers of hollow microspheres that are sintered to each other and to a surface of a ferrous alloy or nickel alloy component part. The hollow microspheres and the surface of the ferrous alloy or nickel alloy component part are sintered in the sense that they are metallurgically joined together by a solid state joint that results from the dissolution of a metallic precursor setting layer that originally bonds each layer of hollow microspheres in place. Due to the relatively high void volume associated with the hollow microspheres in the aggregate, the insulating layer exhibits a low thermal conductivity and a low heat capacity, which obstructs heat transfer through the insulating layer and thus the thermal barrier coating as a whole while allowing surface temperatures of the thermal barrier coating to readily fluctuate or swing in response to changes to its exposed thermal environment.
The ferrous alloy or nickel alloy component part 16 may be any of a wide variety objects that are subjected to aggressive thermal environments including, but not limited to, a piston, an intake or exhaust valve, an exhaust gas manifold, an engine block, an engine head, exhaust gas piping, a turbocharger housing, or a gas turbine or aero-engine part blade, to name but a few specific examples. In the context of an automobile, the ferrous alloy or nickel alloy component part 16 is typically a vehicle component in which the thermal barrier coating 10 that covers the surface 14 is exposed to combustion gas products that can have temperatures as high as 1800° C. depending on the type of engine (e.g., gasoline, diesel, etc.) and the composition of the combustible air/fuel mixture (e.g., rich, lean, or stoichiometric). Of course, the thermal barrier coating 10 may be applied to a diverse array of component parts designed for other applications besides automobile applications. Several examples of common ferrous alloys and nickel alloys that may constitute the component part 16 are 430F, 304, and 303 stainless steel, M2 and M50 high speed steel, cast iron (such as a diesel head), Inconel (i.e., a family of nickel-chromium-based superalloys), Hastelloy (a family of nickel-based superalloys), and other superalloys.
Each of the one or more layers 18 of hollow microspheres 20 includes microspheres 20 that are spread out in a length and width direction to cover a designated area of the surface 14 of the ferrous alloy or nickel alloy component part 16. The thickness 22 of each layer 18 of hollow microspheres 20 may range from 5 μm to 250 μm or, more narrowly, from 20 μm to 40 μm, depending on the diameter of the individual microspheres 20 included in that layer 18, and the overall thickness of the insulating layer 12 may accordingly range from 5 μm to 5 mm. The microspheres 20 are sintered to one another as well as to the surface 14 of the ferrous alloy or nickel alloy component part 16 by way of a solid state joint 26. In particular, the hollow microspheres 20 may be sintered directly to the surface 14 of the ferrous alloy or nickel alloy component part 16, which is the case for the layer 18 of microspheres 20 located immediately adjacent to that surface 14, or they may be indirectly sintered to the surface 14 through other intervening layers 18 of sintered hollow microspheres 20.
The solid state joint 26 joint that typifies the sintered state of the hollow microspheres 20 and the ferrous alloy or nickel alloy component part 16 is born from the dissolution of a metallic precursor setting layer into the microspheres 20 themselves as well as the ferrous alloy or nickel alloy component part 16. The precursor setting layer may be comprised of copper, a copper alloy, or a nickel alloy (described in more detail below). As such, an alloy 28 interconnects the microspheres 20 and infiltrates into the ferrous alloy or nickel alloy component part 16 a distance 30 of up to 1 mm from the surface 14. The alloy system 28 includes nickel and a maximum of 50 wt % copper along with other potential elements, such as zinc and/or tin, when disposed about only the microspheres 20, and may additionally include elements from the ferrous alloy or nickel alloy component part 16 in the portion of the joint 26 that extends the distance 30 into the component part 16. The solid state joint 26 thus includes two portions that compositionally may be the same or may differ from one another while still being part of an incessant alloy system.
The gas-impermeable sealing layer 24 is a high-melting temperature thin film layer or layers that covers and seals the insulating layer 12 against exposure to hot gasses. The sealing layer 24 has a thickness 32 that typically ranges from 1 μm to 20 μm or, more narrowly, from 1 μm to 5 μm, and provides an outer surface 34 of the thermal barrier coating 10. The outer surface 34 may be smooth. Having a smooth outer surface 34 may be desirable in some instances to prevent the creation of turbulent gas flow over the thermal barrier coating 10 while helping ensure that the heat transfer coefficient of the sealing layer 24 remains as low as possible. The material of the sealing layer 24 is selected so that the layer 24 can tolerate harsh thermal conditions yet be resilient enough to resist fracturing or cracking and to withstand thermal expansion/contraction relative to the underlying insulating layer 12. Some notable examples of materials that are suitable for the sealing layer 24 include nickel, stainless steel, nickel-based superalloys (e.g., Inconel, Hastelloy, etc.), vanadium, molybdenum, and titanium. The sealing layer 24 is preferably applied to the insulating layer 12 by way of any known thin-film deposition technique including, for example, electroplating and physical or chemical vapor deposition.
A method of forming the thermal barrier coating 10 is illustrated in
A representative depiction of each of the hollow microspheres 38 employed in the method set forth in
Referring now to
An initial or first layer 36 of hollow microspheres 38 is deposited onto the surface 14 of the ferrous alloy or nickel alloy component part 16 using the metallic precursor setting layer 40. As shown in
The metallic precursor setting layer 40 is preferably copper or a copper-zinc alloy. When composed of copper, the metallic precursor setting layer 40 constitutes “commercially pure copper,” such as any of the unalloyed copper grades C10100 to C13000, which typically include at least 99.9 wt % copper along with nominal amounts of industry accepted impurities. When composed of a copper-zinc alloy, the metallic precursor setting layer 40 constitutes a binary copper-zinc alloy system, along with nominal amounts of industry accepted impurities, such that its phase behavior is represented by the phase diagram shown in
After the metallic precursor setting layer 40 is adhered in place, a contingent of the hollow microspheres 38 is located against the ferrous alloy or nickel alloy component part 16 such that the hollow microspheres 38 contact the precursor setting layer 40, as shown in
The metallic precursor setting layer 40 is then heated to a temperature above its liquidus temperature to melt the metallic precursor setting layer 40, as shown in
Once the layer 36 of hollow microspheres 38 is sufficiently wetted, the metallic precursor setting layer 40 is cooled to a temperature below its solidus temperature to solidify the metallic precursor setting layer 40 from its previous melted or liquefied state, as shown in
The extra, non-bonded hollow microspheres 38 are moved away from the ferrous alloy or nickel alloy component part 16 following solidification of the metallic precursor setting layer 40. The non-bonded hollow microspheres 38 may be moved away by dumping them off of the surface 14, shaking the ferrous alloy or nickel alloy component part 16, removing the component part 16 from a mold cavity or bath that supported the contingent of hollow microspheres 38 against the component part 16, or any other appropriate technique for separating the non-bonded hollow microspheres 38 from the component part 16. Moving the non-bonded hollow microspheres 38 away from the ferrous alloy or nickel alloy component part 16 leaves behind the layer 36 of hollow microspheres 38 that is bonded to the surface 14 of the component part 16. This remaining bonded layer 36 is shown in
The melting and solidifying of the metallic precursor setting layer 40 in the presence of the contingent of hollow microspheres 38 thus functions to deposit the layer 36 of hollow microspheres 38 onto the surface 14 of the ferrous alloy or nickel alloy component part 16. Following deposition of the layer 36 of hollow microspheres 38, the ferrous alloy or nickel alloy component part 16 and the layer 36 of hollow microspheres 38 are heated to sinter the hollow microspheres 38 to each other and to the surface 14 of the component part 16, as shown in
The sintering that occurs from the dissolution of the precursor setting layer 40 into the outer layer 46 of the hollow microspheres 38 and the ferrous alloy or nickel alloy of the component part 16 fuses those entities together and forms the solid state joint 26 shown in
The discussion above with regards to
An example of how to form an insulating layer 12 having multiple stacked layers 18 of hollow microspheres 20 is represented in
The multiple layers 36 of hollow microspheres 38 and the ferrous alloy or nickel alloy component part 16 are then heated as described above to sinter the hollow microspheres 38 in the various layers 36 to each other and to the component part 16, thus fusing those entities together and forming the solid state joint 26, as shown in
Regardless of whether the insulating layer 12 includes a single layer 18 of hollow microspheres 20 or multiple layers 18 of hollow microspheres 20, the gas-impermeable sealing layer 24 is applied over insulating layer 12 to complete the formation of the thermal barrier coating 10 on the ferrous alloy or nickel alloy component part 16. The sealing layer 24, as discussed above, is typically 1 μm to 20 μm thick and is preferably composed of nickel, stainless steel, a nickel-based superalloy (e.g., Inconel, Hastelloy, etc.), vanadium, molybdenum, or titanium. Such materials may be applied onto the insulating layer 12 by a variety of thin-film deposition techniques including electroplating and physical or chemical vapor deposition. The sealing layer 24 may also be thin-film deposited separate from the insulating layer 12 and then subsequently laid onto the insulating layer 12 and heated to secure it in place. Still further, the sealing layer 24 may be separately thin-film deposited and then laid onto the one or more layers 36 of hollow microspheres 38 prior to sintering. In this way, the heating of the one or more layers 36 of hollow microspheres 38 and the ferrous alloy or nickel alloy component part 16 to sinter those entities together also serves to heat the sealing layer and secure it in place to the underlying insulating layer 12. The gas-impermeable sealing layer 24 may be a single thin-film deposited layer or it may be a combination of multiple thin-film deposited layers of the same or differing compositions.
The above description of preferred exemplary embodiments and specific examples are merely descriptive in nature; they are not intended to limit the scope of the claims that follow. Each of the terms used in the appended claims should be given its ordinary and customary meaning unless specifically and unambiguously stated otherwise in the specification.
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