Patent Grant
9120151
The present invention generally relates to titanium aluminide components and methods for manufacturing the same, and more particularly relates to substantially defect-free titanium aluminide components and methods for manufacturing the same from articles formed by consolidation processes.
Components with relatively complex three-dimensional (3D) geometries may raise difficult fabrication issues. Gas turbine engine components may have relatively complex three-dimensional (3D) geometries, including components with internal surfaces defining internal passages including internal hollow areas, internal channels, internal openings, or the like (collectively referred to herein as “internal passages”) for cooling, weight reduction, or otherwise. Additive manufacturing (AM) processes (including those which form “cores” for subsequent conventional casting) as well as other powder consolidation processes such as wrought/forgings, metal injection moldings (MIM), etc. have been developed to manufacture components having relatively complex three dimensional geometries. As used herein, the term “powder consolidation process” refers to a process in which a powdered build material is used to form an intermediate article that is used to manufacture the final component. The powdered build material is densified with bonding between adjacent atoms. Consolidation processes other than powder consolidation processes (e.g., a liquid media consolidation process, a wire feedstock consolidation process, or the like) have also been used to form an intermediate article that is used to manufacture the final component.
Intermediate articles formed from powder consolidation processes and other consolidation processes may have significant surface porosity and cracks (hereinafter “surface-connected defects”), and internal porosity and cracks (hereinafter “internal defects”). For high performance engine components that operate at high stresses and in high temperature environments, and that must endure hot flow path gases and may endure high turbine rotational speeds (e.g., in the case of rotating turbine engine components), such surface-connected and internal defects (collectively referred to herein as “defects”) are unacceptable as the structural integrity, cosmetic appearance, functionality, and mechanical properties (i.e., the “metallurgical quality”) of the component manufactured from such intermediate article may be compromised.
Conventional encapsulation and subsequent hot isostatic pressing (HIP) processing of nickel- and cobalt-based superalloy articles formed by additive-manufacturing processes have resulted in components with reduced defects, but the manufacture of substantially defect-free titanium aluminide components from articles formed by additive-manufacturing processes and other consolidation processes still needs improvement. As used herein, the term “substantially defect-free” refers to a titanium aluminide component in which greater than 95% of the defects (both surface-connected and internal defects) present in the intermediate article have been eliminated.
In general, titanium aluminide alloys are lightweight when compared to nickel-based superalloys which have approximately twice the density of titanium aluminide. Titanium aluminide alloys can maintain their structural integrity (excellent creep (time to 0.5% strain) properties (930 hours @ 40 ksi for Howmet Ti-47Al-2Nb-1Mn-0.5W-0.5Mo-0.2Si (W—Mo—Si Alloy or WMS-Cast+HIP+HTT 1850° F.) during high temperatures (up to about 900° C. for Ti-43.5Al-4Nb-1Mo-0.1B (TNMB1)), and are therefore particularly desirable for manufacturing high performance components, such as turbine engine components. The use of titanium aluminide alloy as a superalloy replacement in manufacturing turbine engine components can significantly reduce engine weight, resulting in significant fuel savings and other benefits. However, titanium aluminide alloys have generally proved difficult to process, have limited heat treatability, and generally have low ductility (2%) when compared to Inconel 718 (3%) at room temperature (about 25 to about 35° C.). For example, the relatively low ductility of titanium aluminide alloys as compared with nickel- and cobalt-based superalloys combined with the very nature of a powder consolidation process in which titanium aluminide powders may be sintered (fused) to form the article results in significant cracking and porosity that are not sufficiently reduced by conventional encapsulation and HIP processing.
Accordingly, it is desirable to provide substantially defect-free titanium aluminide components and methods for manufacturing the same from articles formed by consolidation processes. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
Methods are provided for manufacturing a titanium aluminide component. In accordance with one exemplary embodiment, the method comprises providing an intermediate article comprised of a titanium aluminide alloy and formed by a consolidation process. The intermediate article is encapsulated with an aluminum-containing encapsulation layer. The intermediate article is compacted after the encapsulation step.
Methods are provided for manufacturing a titanium aluminide component from an intermediate article formed by a consolidation process in accordance with yet another exemplary embodiment of the present invention. The method comprises encapsulating the intermediate article with an aluminum-containing encapsulation layer to form an encapsulated article. The intermediate article is comprised of a titanium aluminide alloy material. The aluminum-containing encapsulation layer comprises an aluminide encapsulation layer, a MCrAlY encapsulation layer wherein the M comprises nickel, cobalt, or a combination of nickel and cobalt, or a TiAlCr encapsulation layer. The encapsulated article is compacted.
Substantially defect-free titanium aluminide components are provided in accordance with yet another exemplary embodiment of the present invention. The component is comprised of a compacted three-dimensional article comprised of titanium aluminide and formed by a consolidation process and an aluminum-containing encapsulation layer on at least one surface of the compacted three-dimensional article. The aluminum-containing encapsulation layer comprises an aluminide, MCrAlY wherein M is cobalt, nickel, or a combination of cobalt and nickel, or TiAlCr.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and
The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. As used herein, the term “exemplary” means serving as an example, instance, or illustration. Thus, any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. All of the embodiments described herein are exemplary embodiments provided to enable persons skilled in the art to make or use the invention and not to limit the scope of the invention which is defined by the claims. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary, brief description of the drawings, or the following detailed description.
Various exemplary embodiments are directed to titanium aluminide components and methods for manufacturing the same from articles formed by known consolidation processes. The titanium aluminide components are three-dimensional and may be solid or have internal passages as hereinafter described. As used herein, the term “a powder consolidation process” refers to, for example, an additive manufacturing process such as electron beam melting or direct metal laser fusion in which sequential deposit layers of powdered build material are fused and solidified according to a three-dimensional (3D) model. Other additive manufacturing processes and consolidation processes may also be employed. As noted previously, the as-built article (hereinafter referred to as an “intermediate article”) formed by a consolidation process may have internal porosity and cracks (hereinafter “internal defects”) and surface porosity and cracks (hereinafter “surface-connected defects”) (the internal defects and surface-connected defects are referred to collectively herein as simply “defects”). The term “internal defects” also includes interface defects such as bond failures and cracks at the interfaces between successive cross-sectional layers, a problem often referred to as “delamination.” The cracks develop at interfaces or cut through or across deposit layers due to stresses inherent with the powder consolidation process and/or metallurgy of the build material. The term “surface-connected defects” as used herein includes porosity and cracks that are connected to the surface of the article. According to exemplary embodiments as described herein, the intermediate article is encapsulated such that the surface-connected defects are effectively converted into internal defects, i.e., an aluminum-containing encapsulation layer effectively converts the surface-connected defects into internal defects. The encapsulated article then undergoes a compaction process such as a hot isostatic pressing (HIP) process to substantially eliminate the internal defects, as well as any final treatments, to produce a substantially defect-free titanium aluminide component or simply “finished component”. As used here, the term “substantially defect-free” refers to a component in which greater than 95% of the defects (both surface-connected and internal defects) present in the intermediate article have been eliminated. The substantially defect-free titanium aluminide component is able to operate at high stresses (greater than 400 Mpa) and in high temperature environments (i.e., at temperatures up to about 900° C.), able to endure hot flow path gases (i.e., flow path gases at temperatures up to about 900° C.) and high turbine rotational speeds (i.e., turbine rotational speeds between 0 to 90,000 rpm) if necessary.
While the advantages of the present invention as described herein will be described with reference to a turbine component (a high pressure turbine blade shown in
The turbine component 200 may include an airfoil 202 with a generally concave pressure side 204 and a generally convex suction side 206 opposed thereto. Each airfoil 202 may be coupled to a platform 210 that defines an inner boundary for the hot combustion gases that pass over airfoil 202 during engine operation. An attachment area 212 may be integrally formed on the underside of the platform 210 for mounting the turbine component 200 within the turbine section 100 (
As shown in
The intermediate article is formed from a powdered build material comprising a titanium aluminide (TiAl) alloy. Titanium aluminide alloys maintain their structural integrity during high temperatures (above 700° C.) and for long exposure durations (hereinafter “long-term temperature capabilities”), in addition to being lightweight. TiAl based alloys have a strong potential to increase the thrust-to-weight ratio in the aircraft engine. This is especially the case with engine low pressure turbine blades and the high pressure compressor blades that are conventionally manufactured from Ni based superalloys, which are nearly twice as dense as TiAl based alloys. However, as noted previously, titanium aluminide alloys have relatively low ductility (i.e., (2%) when compared to Inconel 718 (3%) at room temperature (about 25 to about 35° C.) and poor oxidation and creep resistance when compared to high strength nickel-based superalloys. Therefore, it is important that titanium aluminide components used in high stress, high temperature gas turbine applications be substantially defect-free and oxidation protected.
Exemplary titanium aluminide alloys for the substrate build material are provided below along with their chemical composition, in atomic percent (at. %):
Titanium aluminide alloys
Titanium aluminides have three major intermetallic compounds: gamma TiAl, alpha 2-Ti3Al and TiAl3. Ti-48Al-2Cr-2Nb (atomic percent), hereinafter named Ti-48-2-2 is a gamma titanium aluminide. Gamma aluminide turbine blades based on Ti-48-2-2 are nearly as strong as nickel based alloys up to 760° C. (1400° F.) and half the weight. The density of gamma TiAl is about 4.0 g/cm3. Gamma TiAl also has excellent mechanical properties and oxidation and corrosion resistance at elevated temperatures (over 600° C.), which makes it a good replacement for traditional Ni based superalloy components in aircraft turbine engines.
Powder consolidation processes for forming the intermediate article are well known in the art. Powder consolidation processes include, for example, additive manufacturing (AM) processes (including those which form “cores” for subsequent conventional casting) such as electron beam melting (EBM) or direct metal laser fusion (DMLF) in which sequential deposited layers of powdered build material are fused and solidified according to a three-dimensional model of the component, as hereinafter described. “Additive Manufacturing” is defined by the American Society for Testing and Materials (ASTM) as the “process of joining materials to make objects from 3D model data, usually layer upon layer, as opposed to subtractive manufacturing methodologies, such as traditional machining and casting.” In an additive manufacturing process, for example, the intermediate turbine article 500 (
Other examples of additive manufacturing techniques include: micro-pen deposition in which liquid media is dispensed with precision at the pen tip and then cured (actually a liquid media consolidation process); selective laser sintering in which a laser is used to sinter a powder media in precisely controlled locations; laser wire deposition in which a wire feedstock is melted by a laser and then deposited and solidified in precise locations to build the product (a wire feedstock consolidation process); and laser engineered net shaping. In general, additive manufacturing techniques provide flexibility in free-form fabrication without geometric constraints, fast material processing time, and innovative joining techniques. These are collectively referred to as “consolidation processes.” A consolidation process may be a “powder consolidation process” in which the build material is powder, a “liquid media consolidation process” in which the build material is liquid media, or a “wire feedstock consolidation process” in which the build material is wire feedstock.
In a particular exemplary embodiment, direct metal laser fusion (DMLF) (an exemplary powder consolidation process) is used to produce the intermediate turbine article 500. DMLF is a commercially available laser-based rapid prototyping and tooling process by which complex parts may be directly produced by precision melting and solidification of metal powder into successive layers of larger structures, each layer corresponding to a cross-sectional layer of the 3D component. DMLF may include direct metal laser sintering (DMLS). DMLS is an additive manufacturing process that fuses powder metal in progressive deposit layers. Further details about an exemplary DMLS technique are provided below with reference to
The fabrication device 410 includes a build container 412 with a fabrication support 414 carrying the intermediate turbine article 500 to be formed from the build material 470. The fabrication support 414 is movable within the build container 412 in a vertical direction and is adjusted in such a way to define a working plane 416. The delivery device 430 includes a powder chamber 432 with a delivery support 434 that supports the build material 470 and is also movable in a vertical direction. The delivery device 430 further includes a roller or wiper 436 that transfers build material 470 from the delivery device 430 to the fabrication device 410.
During operation, the fabrication support 414 is lowered and the delivery support 434 is raised. The roller or wiper 436 scraps or otherwise pushes a portion of the build material 470 from the delivery device 430 to form the working plane 416 in the fabrication device 410. The laser 460 emits a laser beam 462, which is directed by the scanner 440 onto the build material 470 in the working plane 416 to selectively fuse the build material 470 into a cross-sectional deposit layer of the intermediate turbine article 500. More specifically, the laser beam 462 selectively fuses the powder of the build material 470 into larger structures by rapidly melting the powder particles. As the scanned laser beam 462 moves on, heat is conducted away from the previously melted area, thereby leading to rapid cooling and resolidification. As such, based on the control of the laser beam 462, each deposit layer of build material 470 will include unsintered build material 470 and sintered build material that forms the cross-sectional deposit layer of the intermediate turbine article 500. Any suitable laser and laser parameters may be used, including considerations with respect to power, laser beam spot size, and scanning velocity.
While additive manufacturing processes for forming the intermediate article have been described, other powder consolidation processes may be used to form the intermediate article as noted previously. For example, the intermediate article as exemplified by intermediate turbine article 500 (
As a result of the powder consolidation process (and other consolidation processes), as noted previously, the intermediate article may include both internal porosity and cracks (internal defects 502), and surface porosity and cracks (or surface-connected defects 504) within the substrate 506 (See
In a subsequent step 310 and additionally referring to
According to exemplary embodiments, the encapsulation layer 606 of the encapsulated article 600 comprises an aluminum-containing encapsulation layer. The aluminum-containing encapsulation layer is compatible with the titanium aluminide substrate and is formed by an encapsulation process, as hereinafter described. In various embodiments, the aluminum-containing encapsulation layer comprises an aluminide encapsulation layer comprising TiAl, TiAl3, or a combination thereof.
The TiAl encapsulation layer may be formed by suspending the intermediate article above a pack of simple aluminide vapor in vacuum, at about 1850° F. to about 1975° F. for about 430 minutes to about 450 minutes and a partial pressure of argon. The aluminide alloy vapor composition comprises about 55 to about 57 weight percent chromium and about 43 to about 45 weight percent aluminum for a total of 100 weight percent. The vapor coating mixture comprises about 66 to about 68 wt % aluminide alloy vapor composition and about 32 to about 34 wt % Al2O3. About 0.6 to about 1.2 grams/pound of NH4Cl may be used as the activator.
The TiAl3 encapsulation layer may be formed by a pack aluminizing process or an out of pack aluminizing process as known to one skilled in the art, followed by a diffusion heat treatment at about 1125 to about 1175° F. for about 7 to about 9 hours. The TiAl3 encapsulation layer comprises about 75 at % aluminum and 25 at % titanium. As the TiAl3 intermetallic is very brittle, the encapsulated article should be carefully handled.
An aluminide encapsulation layer may be used to encapsulate an external surface of the intermediate article, an internal surface (if present) as hereinafter described, or both the external and internal surfaces of the intermediate article (see, e.g.,
In another exemplary embodiment, the aluminum-containing encapsulation layer comprises MCrAlY wherein M comprises nickel, cobalt, or a combination of nickel and cobalt. An exemplary MCrAlY encapsulation layer for a TiAl intermediate article includes, for example, Co27Cr9Al0.5Y, Ni30Cr11Al0.5Y, Co32Ni21Cr8Al0.5Y, and Ni23Co18Cr12.5Al0.5Y. The MCrAlY encapsulation layer may be formed on the external surface of the intermediate article by applying the MCrAlY encapsulation layer by, for example, EBPVD, cathodic arc or magnetron sputtering processes. Thermal spray processes such as, for example, LPPS, HVOF, and Ar-shrouded plasma spray may also be used to form the MCrAlY encapsulation layer. Such processes are well known to one skilled in the art.
Exemplary EBPVD conditions for applying the MCrAlY encapsulation layer on the external surface of the intermediate article comprising a titanium aluminide alloy are as follows:
Exemplary magnetron sputtering conditions for forming or applying the MCrAlY encapsulation layer on the exterior surface of the intermediate article are as follows:
The thickness of the MCrAlY encapsulation layer applied by the magnetron sputtering process on the exterior surface of the intermediate article comprised of a titanium aluminide alloy is about 1 mil to about 2 mils, although other thicknesses may be used. It is to be understood that other magnetron sputtering conditions may be used for forming the MCrAlY encapsulation layer on the external surface of the intermediate article comprising the titanium aluminide alloy.
In another exemplary embodiment, the aluminum-containing encapsulation layer comprises a TiAlCr encapsulation layer. Exemplary TiAlCr encapsulation layers include, for example, Ti34/38Al-12/16Cr, wt % and may be applied to the titanium aluminide intermediate article by, for example, EBPVD, cathodic arc, or magnetron sputtering physical vapor deposition processes. The MCrAlY and TiAlCr encapsulation layers may not be formed on the internal surface(s) of the internal passage(s) because it is very difficult to coat internal surfaces through physical vapor deposition processes.
In a subsequent step 320 and additionally referring to
The hot isostatic pressing (HIP) process may be used to reduce or eliminate internal defects in the encapsulated article, whether the internal defects were originally present in the intermediate article or converted into internal defects by the previous encapsulation step used to bridge and cover the surface-connected defects, effectively converting the surface-connected defects into internal defects in preparation for the subsequent hot isostatic pressing (HIP) step. In general, the HIP process will not reduce defects such as porosity or cracks that are connected to the surface of the component. Instead, the encapsulation layer 606 provided in previous step 310 functions to internalize any such surface connected defects (e.g., surface connected porosity and cracks) such that the HIP process is effective at reducing or eliminating the internal defects in the intermediate article. The reduction in internal defects, such as porosity and cracks, resulting from the HIP process, as illustrated in
In a step 330 and additionally referring to
As noted above, and illustrated in FIGS. 2 and 5-8, the intermediate turbine article 500 and finished turbine component (200 of
In this exemplary embodiment, to encapsulate the internal surface(s) of the internal passage(s), an aluminide comprising the TiAl or the TiAl3 in the form of a Sermaloy™ J slurry available from, for example, Sermatech International or Praxair Surface Technologies, Inc. is applied on the internal surface(s) within the internal passages of the intermediate article by pumping the slurry through the internal passage(s) and thereafter heating the intermediate article with the applied slurry to a temperature of about 1400° F. to about 1800° F. in a protective atmosphere (vacuum or Ar) of a vacuum furnace, thereby forming the encapsulation layer on the inside surface(s) to ensure that the encapsulation layer 1002 spans the surface porosity and cracks 906 within the internal passages and on the external surface. The thickness of the aluminide encapsulation layer on the internal passage surfaces may be from about 25 to about 75 μm thick. The encapsulation layer 1002 effectively converts the surface porosity and cracks 906 into internal porosity and cracks.
In the next step, as shown in
Accordingly, exemplary embodiments may eliminate or reduce both internal and external defects in titanium aluminide components manufactured from articles formed by consolidation processes, thereby providing substantially defect-free titanium aluminide components. The substantially defect-free titanium aluminide components can operate at high stresses and in high temperature environments, able to endure hot flow path gases and high turbine rotational speeds if necessary while significantly reducing turbine engine weight, resulting in fuel and other cost savings. In addition, the method according to exemplary embodiments may be performed with fewer, if any, finishing steps.
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. Various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims and their legal equivalents.
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