Metal working – Method of mechanical manufacture – Rocket or jet device making
Reexamination Certificate
1998-11-12
2001-11-27
Rosenbaum, I. Cuda (Department: 3726)
Metal working
Method of mechanical manufacture
Rocket or jet device making
C029S890020
Reexamination Certificate
active
06321449
ABSTRACT:
The present invention relates to methods of forming internal channels in components. More particularly, this invention is directed to materials and methods for forming a cooling channel beneath the surface of an air-cooled component, such as a blade, vane, shroud, combustor or duct of a gas turbine engine.
BACKGROUND OF THE INVENTION
Higher operating temperatures for gas turbine engines are continuously sought in order to increase their efficiency. However, as operating temperatures increase, the high temperature durability of the components of the engine must correspondingly increase. Significant advances in high temperature capabilities have been achieved through formulation of iron, nickel and cobalt-based superalloys, though components formed from such alloys often cannot withstand long service exposures if located in certain sections of a gas turbine engine, such as the turbine, combustor or augmentor.
A common solution is to provide internal cooling of turbine, combustor and augmentor components, at times in combination with a thermal barrier coating. Airfoils of gas turbine engine blades and vanes often require a complex cooling scheme in which cooling air flows through cooling channels within the airfoil and is then discharged through carefully configured cooling holes at the airfoil surface. Convection cooling occurs within the airfoil from heat transfer to the cooling air as it flows through the cooling channels. In addition, fine internal orifices can be provided to direct cooling air flow directly against inner surfaces of the airfoil to achieve what is referred to as impingement cooling, while film cooling is often accomplished at the airfoil surface by configuring the cooling holes to discharge the cooling air flow across the airfoil surface so that the surface is protected from direct contact with the surrounding hot gases within the engine.
In the past, cooling channels have typically been integrally formed with the airfoil casting using relatively complicated cores and casting techniques. More recently, U.S. Pat. Nos. 5,626,462 and 5,640,767, both to Jackson et al. and commonly assigned with the present invention, teach a method of forming a double-walled airfoil by depositing an airfoil skin over a separately-formed inner support wall (e.g., a spar) having surface grooves filled with a sacrificial material. After the airfoil skin is formed, preferably by deposition methods such as plasma spraying and electron-beam physical vapor deposition (EBPVD), the sacrificial material is removed to yield a double-walled airfoil with cooling channels that circulate cooling air against the interior surface of the airfoil skin.
In Jackson et al., the sacrificial material is a braze alloy deposited in excess amounts in a spar groove, with the excess being removed by machining or another suitable technique so that the surface of the braze alloy is flush with the surrounding surface of the spar. The sacrificial material is then removed after deposition of the airfoil skin by melting/extraction, chemical etching, pyrolysis or another suitable method. Though braze alloys have been successful in the process disclosed by Jackson et al., efforts have continued to develop other materials that better meet the requirements described previously. Notably, sacrificial materials proposed for other applications have been tried without success. For example, a combination of K
2
SO
4
and Na
2
AlO
3
was experimented with as a sacrificial backfill material, but found to be corrosive and severely attacked a spar formed of Rene N5, a General Electric nickel-based superalloy having a nominal composition, in weight percent, of Ni-7.5Co-7.0Cr-6.5Ta-6.2Al-5.0W-3.0Re-1.5Mo-0.15Hf-0.05C-0.004B-0.01Y. Other known sacrificial materials, including those disclosed in U.S. Pat. No. 4,956,037 to Vivaldi and U.S. Pat. No. 5,249,357 to Holmes et al., are unable to withstand high-temperature deposition processes such as EBPVD.
In view of the above, it would be desirable if improved sacrificial materials and processes were available that could ensure that all of the aforementioned requirements of the sacrificial material were adequately met to produce an air-cooled component with a deposited skin that is substantially free of surface defects.
BRIEF SUMMARY OF THE INVENTION
According to the present invention, there are provided sacrificial materials and methods for forming an internal channel in an article, and particularly a cooling channel in an air-cooled component, such as a blade, vane, shroud, combustor or duct of a gas turbine engine. Each of the methods generally entails forming a substrate to have a groove recessed in its surface. The sacrificial material is deposited and consolidated in the groove so that the groove is completely filled. A permanent layer is then deposited on the surface of the substrate and over the sacrificial material in the groove, after which the sacrificial material is removed from the groove to form a channel in the substrate beneath the permanent layer.
Four embodiments of this invention are disclosed, each of which generally entails the use of different candidates for the sacrificial material. The preferred process for depositing the permanent layer on the spar and sacrificial material is electron beam physical vapor deposition (EBPVD). In a first embodiment of the invention, the sacrificial material is either NaCl, KBO
2
, NiCl
2
, MgSO
4
, NiF
2
, NaAlO
2
, or mixtures of NaAlO
2
and NaAlSiO
4
, and is deposited in the form of a paste. In a second embodiment, the sacrificial material is formulated to enable depositing and consolidating the material in the groove at low temperatures (i.e., cold pressing), preferably less than 200° C. Suitable sacrificial materials for this process are KBr, NaCl, NiBr
2
, BN, and mixtures of talc (Mg
6
[Si
8
O
20
](OH)
4
) and pyrophyllite (Al
4
[Si
8
O
20
](OH)
4
). In a third embodiment, the sacrificial material is deposited and then sintered in the groove at an elevated temperature (i.e., hot pressing). Sacrificial materials suitable for this process are MgF
2
, NiF
2
, and mixtures of talc and pyrophyllite. Finally, the fourth embodiment of this invention employs as the sacrificial material MoO
3
or another material capable of being sublimed above a certain temperature. This method entails depositing a relatively compliant layer over the sacrificial material, heating the sacrificial material to remove the sacrificial material by sublimation, and then depositing a second, less compliant layer on the first layer to produce a multilayer skin on the substrate.
In accordance with the above, the present invention identifies certain compositions suitable for use as sacrificial materials when appropriately processed by one of the four above-noted methods. The sacrificial materials of this invention and their associated process requirements address the aforementioned requirements for the sacrificial material, particularly with respect to exhibiting adequate adhesion to the spar and minimal shrinkage prior to and during the deposition step. As a result, the disclosed materials and processes are able to produce air-cooled components with deposited skins that are substantially free of surface defects.
Other objects and advantages of this invention will be better appreciated from the following detailed description.
REFERENCES:
patent: 3595025 (1971-07-01), Stockel et al.
patent: 4582678 (1986-04-01), Niino et al.
patent: 4584171 (1986-04-01), Niino et al.
patent: 4956037 (1990-09-01), Vivaldi
patent: 5075966 (1991-12-01), Mantkowski
patent: 5249357 (1993-10-01), Holmes et al.
patent: 5626462 (1997-05-01), Jackson et al.
patent: 5640767 (1997-06-01), Jackson et al.
patent: 5820337 (1998-10-01), Jackson et al.
Dobbs James Ross
Dupree Paul Leonard
Jackson Melvin Robert
Zhao Ji-Cheng
Cuda Rosenbaum I.
DiConza Paul J.
General Electric Company
Ingraham Donald S.
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