The present invention relates to the field of jet aircraft engines and/or other supersonic nozzles, and, more particularly, to a method and device to reduce the noise produced by jet aircraft engines and/or other supersonic nozzles through the use of corrugated seals for the secondary internal divergent flaps of the nozzle. Furthermore, the present invention contemplates the use of prism-shaped extensions or chevrons attached to the primary outer flaps of the nozzle for further reduction of noise without any loss of aero-performance.
The method and device of the present invention has particular applicability for the jet engines of a military aircraft, such as the U.S. Navy's F/A-18 E/F Super Hornet aircraft in performance of the Field Carrier Landing Practice (FCLP) mission profile. During performance of the FCLP mission profile, military aircraft, such as the F/A-18 E/F, operate with variable area engine nozzles which are scheduled to be highly overexpanded. This means that the nozzle exit static pressure is significantly below the surrounding ambient pressure at the aircraft's altitude above ground level. This overexpanded exhaust flow contains shocks in the exhaust plumes, the presence of which generates an efficient noise production mechanism known as “shock noise.” For a further discussion of shock noise, reference is made to Seiner, J. M., 1984, “Advances in High-Speed Jet Aeroacoustics,” Invited Lecture, AIAA Paper No. 84-2275. This publication is incorporated herein by this reference.
Furthermore, it is well-recognized that an overexpanded nozzle has a lower aerodynamic performance efficiency than one that is fully expanded, i.e., where the exhaust static pressure equals the local aircraft ambient pressure. See Liepman, H. W., and Roshko, A., 1985, “Elements of Gasdynamics,” Dover Publications, Inc., Mineola, N.Y., a publication which is also incorporated herein by this reference. In any event, reduction of shock noise can generally be accomplished by design of the nozzle geometry to achieve fully expanded flow at the nozzle exit, where the exhaust static pressure is equal to ambient pressure.
In addition to shock noise, an additional efficient noise generating mechanism is present within a supersonic exhaust regardless of whether it contains shocks. This noise generating mechanism is referred to as Mach wave emission. See Seiner, J. M., Bhat, T. R. S., and Ponton, M. K., 1994, “Mach Wave Emission From a High Temperature Supersonic Jet,” AIAA J., Vol. 32, No. 12, pp. 2345-2350, a publication which is also incorporated herein by this reference. To minimize this noise source requires that the high-speed exhaust be forced to mix with the slower moving surrounding air to achieve lower velocities in the exhaust plume than would otherwise occur naturally. Lower exhaust velocities, combined with reduced levels of the turbulent Reynolds shear stress, lead to reduction of turbulence-generated noise, including Mach wave emission.
Accordingly, it would be desirable to provide a method and device to substantially reduce shock noise by providing a nozzle design and construction to achieve fully expanded flow at the nozzle exit, while at the same time, generating the appropriate counter-rotating vorticity to force low speed mixing of surrounding ambient air with the high-speed exhaust to reduce turbulence-generated noise.
The present invention is a method and device to reduce the noise produced by jet aircraft engines and/or other supersonic nozzles through the use of corrugated seals for the secondary internal divergent flaps of the nozzle.
In one exemplary embodiment of the present invention, each corrugated seal has a cross-sectional shape of a truncated super ellipse of high aspect ratio with a circular quadrant extension from each side of the super ellipse to create a substantially horizontal portion at the surface of the corrugated seal. After determining the nozzle area distribution for shock-free flow at a particular power setting, the difference between the original cross-sectional area of the nozzle at any given point along the length of the nozzle and the calculated cross-sectional area for shock-free flow can be computed. This difference is then divided by the number of corrugated seals to be installed. By making such a computation at discrete axial locations along the length of the nozzle, and assuming that the general cross-sectional shape of the corrugated seal remains constant, a topological surface geometry for each corrugated seal is established.
Once these corrugated seals are installed in the nozzle, they serve not only to eliminate shock-generated noise, but also generate a counter-rotating vorticity to force low speed mixing of surrounding ambient air with the high-speed exhaust. Lower exhaust velocities, combined with reduced levels of the turbulent Reynolds shear stress, lead to reduction of turbulence-generated noise, including Mach wave emission.
Furthermore, the present invention contemplates the use of prism-shaped extensions or chevrons attached to the primary outer flaps of the nozzle to control thrust augmentation associated with corrugated seals and enhance the level of forced mixing for additional noise reduction without any loss of aero-performance.
The present invention is a method and device to reduce the noise produced by jet aircraft engines and/or other supersonic nozzles through the use of corrugated seals for the secondary internal divergent flaps of the jet aircraft engine. Furthermore, the present invention contemplates the use of prism-shaped extensions or chevrons attached to the primary outer flaps of the nozzle to control thrust augmentation associated with corrugated seals and enhance the level of forced mixing for additional noise reduction without any loss of aero-performance.
Of particular importance to the present invention, the nozzle 10 includes circumferentially spaced primary outer divergent flaps 12, which are pivotable to alter the cross-sectional area as the gas exits the nozzle 10. Furthermore, the nozzle 10 includes secondary internal divergent flaps 14. The relationship and positioning of the respective flaps 12, 14 is further illustrated in
In determining the appropriate geometry for these corrugated engine seals 20 to maximize their ability to reduce noise, first, it is important to identify the pertinent aircraft altitudes with engine power settings that define the mission profile. Furthermore, aircraft configuration, such as wing loading, landing gear position, and flap position, are important for proper determination of aircraft speed at a particular power setting. As mentioned above, the present invention has particular applicability for the jet engines of a supersonic aircraft, such as the U.S. Navy's F/A-18 E/F Super Hornet aircraft in performance of the Field Carrier Landing Practice (FCLP) mission profile. This aircraft uses F404-402 engines manufactured by General Electric Aircraft Engines (“GEAE”) Cincinnati, Ohio.
Then, certain operating parameters of the aircraft and engines associated with the defined mission profile must be determined. This can be achieved through the running of an installed engine cycle deck for the engine, which is a simulation that generates aerothermal numerical representations to characterize engine performance. Often, engine cycle decks for specific engines are available from the engine manufacturer or the U.S. Government Federal Laboratory responsible for a military aircraft's mission.
In any event, the most effective noise reduction design is often associated with the maximum engine thrust for the particular mission. The maximum thrust for the U.S. Navy's F/A-18 E/F Super Hornet or other military aircraft is commonly referred to as “Military Engine Power” or “Mil-Pwr.” From the installed engine cycle deck, the engine nozzle pressure ratio, exit static pressure, engine total temperature after mixing with the fan engine flow, engine weight flow, throat area, nozzle exit area, and ambient pressure and temperature at altitude are determined at Mil-Pwr. Isentropic equations, such as those described in Liepman, H. W., and Roshko, A., 1985, “Elements of Gasdynamics”, Dover Publications, Inc., Mineola, N.Y. (referenced above), can then be used to compute the nozzle exit Mach number and Mach number for fully expanded flow where the exit static pressure matches that of ambient pressure.
After determining the operating parameters at Mil-Pwr or another power setting of interest, a Method of Characteristics (MOC) solution is obtained based on the actual throat area and an exit area that that produces fully expanded flow for the nozzle pressure ratio and total temperature as determined from the engine cycle deck. For engine nozzles with standard, substantially flat seals, a high-order polygonal exit area is assumed. For example, for the GEAE F404-402 engines referenced above, a twelve-sided exit area is assumed. MOC nozzle codes are generally available from various sources, including U.S. Government Federal Laboratories.
The MOC solution provides an area distribution from the throat of the nozzle to exit of the nozzle that produces shock-free flow. In other words, the MOC solution establishes a optimal cross-sectional area at axial locations along the length of the nozzle for producing shock-free flow. Of course, this area distribution includes values that are always smaller than the existing nozzle area distribution if the flow was overexpanded, and values that are greater if the flow was underexpanded. As mentioned above, military aircraft generally have variable area engine nozzles which are scheduled to be highly overexpanded.
Once the optimal area distribution from the throat of the nozzle to exit of the nozzle has been determined through the MOC solution, the appropriate geometry and dimensions for the corrugated seals 20 can be determined. Referring now to
In any event, the numerical dimensions of the corrugated seals 20 are selected so as to provide the area distribution required to produce shock-free flow. In other words, and as mentioned above, the MOC solution establishes a optimal cross-sectional area at axial locations along the length of the nozzle for producing shock-free flow. Thus, the penetration of the corrugated seals 20 into the exhaust flow (i.e., the height of the seals) is determined by the difference in area distribution of the original nozzle compared to the calculated area distribution for shock-free flow.
Specifically, after having determined the area distribution for shock-free flow at a particular power setting (e.g., Mil-Pwr), the difference between the original cross-sectional area of the nozzle at any given point along the length of the nozzle and the calculated cross-sectional area for shock-free flow can be computed. This difference is then divided by the number of corrugated seals 20 to be installed. As mentioned above, in the exemplary embodiment illustrated in
By making such a computation at discrete axial locations along the length of the nozzle, and assuming that the general cross-sectional shape of the corrugated seal 20 remains constant, a topological surface geometry for the corrugated seal 20 is established. In other words, the slope or contour of the corrugated seal 20 along its length is established, perhaps as best illustrated in
Therefore to the extent that the method of the present invention is applied to a jet engine design, it may be generally characterized as including the following steps: (1) identifying a mission profile and power setting of interest for the engine; (2) determining certain operating parameters of the engine based on the mission profile; (3) obtaining a Method of Characteristics (MOC) solution based on the certain operating parameters that produces fully expanded flow; (4) determining an appropriate geometry and dimensions for a predetermined number of corrugated seals based on the MOC solution; and (5) installing such corrugated seals in the engine nozzle.
To confirm the efficacy of the method and device of the present invention as described above, 1/10th scale model testing of the corrugated seal geometry was conducted for certain power settings identified in the engine cycle deck for the F404-402 engines manufactured by General Electric Aircraft Engines of Cincinnati, Ohio.
Finally, as part of the model testing, a study was conducted to determine the potential for reduction of the exhaust plume infrared (IR) emission. In this regard, a short wave imaging radiometer was used to image the exhaust plume with and without the corrugated seals.
For further confirmation of the efficacy of the method and device of the present invention as described above, testing of a F404-400 engine manufactured by General Electric Aircraft Engines of Cincinnati, Ohio was conducted at the Naval Air Warfare Center Aircraft Division at Lakehurst, N.J. (NAWCADLKE). For purposes of this testing, the corrugated seals were designed for N2=95.5% (Point 8S of the engine cycle deck).
Furthermore, as part of the engine testing at NAWCADLKE, engine testing was also conducted using prism-shaped extensions, known as chevrons, attached to the nozzle and extending into the exhaust stream to achieve greater levels of forced mixing of the high-speed exhaust with the slower moving surrounding air. An exemplary embodiment of such a chevron 40 is illustrated in
Referring again to
Finally, similar to the model testing, a study was conducted to determine the potential for reduction of the exhaust plume infrared (IR) emission.
One of ordinary skill in the art will also recognize that additional embodiments and/or implementations are possible without departing from the teachings of the present invention or the scope of the claims which follow. This detailed description, and particularly the specific details of the exemplary embodiments and testing configurations disclosed therein, is given primarily for clarity of understanding, and no unnecessary limitations are to be understood therefrom, for modifications will become obvious to those skilled in the art upon reading this disclosure and may be made without departing from the spirit or scope of the claimed invention.
This divisional application claims benefit to U.S. Non-Provisional application No. 10/999,449, now allowed, filed Nov. 30, 2004 now U.S. Pat. No. 7,240,493, which claims priority to U.S. Provisional Patent Application Ser. No. 60/525,912 filed Dec. 1, 2003, the entire disclosure of which is incorporated herein by reference.
This invention was made with assistance from Grant Numbers N00014-02-1-0871 and N00014-02-1-0380 from the Office of Naval Research. The United States Government has rights to this invention.
Number | Name | Date | Kind |
---|---|---|---|
2801516 | Battle et al. | Aug 1957 | A |
2972226 | Geary | Feb 1961 | A |
2984068 | Eatock | May 1961 | A |
2999354 | Gallo et al. | Sep 1961 | A |
3184917 | Caoette et al. | May 1965 | A |
3251553 | Fitton et al. | May 1966 | A |
3892358 | Gisslen | Jul 1975 | A |
3979065 | Madden | Sep 1976 | A |
3982696 | Gordon | Sep 1976 | A |
4066214 | Johnson | Jan 1978 | A |
4077206 | Ayyagari | Mar 1978 | A |
4081137 | Sutton et al. | Mar 1978 | A |
4117671 | Neal et al. | Oct 1978 | A |
4422524 | Osborn | Dec 1983 | A |
4487017 | Rodgers | Dec 1984 | A |
4878618 | Hufnagel | Nov 1989 | A |
4994660 | Hauer | Feb 1991 | A |
5039014 | Lippmeier | Aug 1991 | A |
5120005 | Reedy | Jun 1992 | A |
5215256 | Barcza | Jun 1993 | A |
5232158 | Barcza | Aug 1993 | A |
5261605 | McLafferty et al. | Nov 1993 | A |
5269467 | Williams et al. | Dec 1993 | A |
5285637 | Barcza | Feb 1994 | A |
5437411 | Renggli | Aug 1995 | A |
5484105 | Ausdenmoore et al. | Jan 1996 | A |
5485959 | Wood et al. | Jan 1996 | A |
5667140 | Johnson et al. | Sep 1997 | A |
5683034 | Johnson et al. | Nov 1997 | A |
5713522 | Lundberg | Feb 1998 | A |
5771681 | Rudolph | Jun 1998 | A |
5797544 | Ward | Aug 1998 | A |
6082635 | Seiner et al. | Jul 2000 | A |
6347510 | McAlice et al. | Feb 2002 | B1 |
6626440 | Halling | Sep 2003 | B2 |
6968615 | More et al. | Nov 2005 | B1 |
7032835 | Murphy et al. | Apr 2006 | B2 |
Number | Date | Country | |
---|---|---|---|
20070246293 A1 | Oct 2007 | US |
Number | Date | Country | |
---|---|---|---|
60525912 | Dec 2003 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10999449 | Nov 2004 | US |
Child | 11769539 | US |