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| United States Patent Application |
20070020099
|
| Kind Code
|
A1
|
|
Hutcheson; Florence V.
; et al.
|
January 25, 2007
|
Noise reduction of aircraft flap
Abstract
A reduction in noise radiating from a side of a deployed aircraft flap is
achieved by locating a slot adjacent the side of the flap, and then
forcing air out through the slot with a suitable mechanism. One, two or
even three or more slots are possible, where the slot is located at one
or more locations selected from a group of locations comprising a top
surface of the flap, a bottom surface of the flap, an intersection of the
top and side surface of the flap, an intersection of the bottom and side
surfaces of the flap, and a side surface of the flap. In at least one
embodiment the slot is substantially rectangular. A device for adjusting
a rate of the air forced out through the slot can also be provided.
| Inventors: |
Hutcheson; Florence V.; (Virginia Beach, VA)
; Brooks; Thomas F.; (Seaford, VA)
|
| Correspondence Name and Address:
|
NASA Langley Research Center
Mail Stop 141
Hampton
VA
23681-2199
US
|
| Assignee Name and Adress: |
US of America as represented by the Administrator of the National Aeronautics & Space Administration
|
| Serial No.:
|
169256 |
| Series Code:
|
11
|
| Filed:
|
June 22, 2005 |
| U.S. Current Class: |
416/90R |
| U.S. Class at Publication: |
416/090.00R |
| Intern'l Class: |
F01D 5/18 20060101 F01D005/18 |
Goverment Interests
ORIGIN OF THE INVENTION
[0001] The invention described herein was made by employees of the United
States Government and may be manufactured and used by or for the
Government of the United States of America for governmental purposes
without the payment of any royalties thereon or therefor.
Claims
1. An aircraft flap which reduces noise radiating from a side thereof when
the flap is deployed comprising: at least one slot located adjacent the
side of the flap; and a mechanism which forces air out through said at
least one slot when the flap is deployed.
2. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot is located on a top surface of the flap.
3. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot is located on a bottom surface of the flap.
4. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot is located on a side surface of the flap.
5. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot is located at an intersection of a side surface
and a top surface of the flap.
6. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot is located at an intersection of a side surface
and a bottom surface of the flap.
7. An aircraft flap which reduces noise as claimed in claim 1, wherein
said at least one slot comprises at least two slots located respectively
at two locations of a group of locations comprising a top surface of the
flap, a bottom surface of the flap, an intersection of the top and side
surface of the flap, an intersection of the bottom and side surfaces of
the flap, and a side surface of the flap.
8. An aircraft flap which reduces noise as claimed in claim 7, wherein
said at least one slot comprises at least slots located respectively at
at least three locations of a group of locations comprising a top surface
of the flap, a bottom surface of the flap, an intersection of the top and
side surface of the flap, an intersection of the bottom and side surfaces
of the flap, and a side surface of the flap.
9. An aircraft flap which reduces noise as claimed in claim 1, wherein
said mechanism includes a device which adjusts a rate of the air forced
out through said at least one slot.
10. An aircraft flap which reduces noise as claimed in claim 1, wherein a
forward end of the at least one slot is located into the end of the
vortex formation region and the at least one slot extends into the region
of maximum noise generation.
11. An aircraft flap which reduces noise as claimed in claim 1, and
wherein said at least one slot is substantially rectangular.
12. A method for reducing noise radiating from a side of a deployed flap
of an aircraft wing comprising the steps of: locating a slot adjacent the
side of the flap; and forcing air out through the slot when the flap is
deployed.
13. A method for reducing noise as claimed in claim 12, wherein the slot
is located on a top surface of the flap.
14. A method for reducing noise as claimed in claim 12, wherein the slot
is located on a bottom surface of the flap.
15. A method for reducing noise as claimed in claim 12, wherein the slot
is located on a side surface of the flap.
16. A method for reducing noise as claimed in claim 12, wherein the slot
is located at an intersection of a side surface and a top surface of the
flap.
17. A method for reducing noise as claimed in claim 12, wherein the slot
is located at an intersection of a side surface and a bottom surface of
the flap.
18. A method for reducing noise as claimed in claim 12, wherein there are
at least two of the slots located respectively at at least two locations
of a group of locations comprising a top surface of the flap, a bottom
surface of the flap, an intersection of the top and side surface of the
flap, an intersection of the bottom and side surfaces of the flap, and a
side surface of the flap.
19. A method for reducing noise as claimed in claim 12, and further
including the step of adjusting a rate of the air forced out through the
slot.
20. A method for reducing noise as claimed in claim 12, wherein the
locating step locates a forward end of the slot at least about 0.27 of
chord.
Description
BACKGROUND OF THE INVENTION
[0002] During airport approach, when the engines of an aircraft are near
idle condition and when the high-lift systems and landing gears are
deployed, airframe noise is the dominant noise source. The noise that is
generated at the side edge of the flaps has been identified as an
important airframe noise component and is a target for noise control.
[0003] A number of numerical and experimental studies have been conducted
in order to identify and model the noise generation mechanisms at the
flap side edge. Flow field measurements in the flap side edge region of a
wing with a half-span flap have revealed the presence of a 2-vortex
system: a small vortex near the flap side edge on the top surface and a
stronger side vortex along the lower portion of the flap side edge. As it
travels downstream along the flap side edge, the side vortex strengthens
and expands. At about mid-chord, it begins to spill over the flap top
surface and merges with the small top vortex. The instabilities in this
vortex system and in the strong shear layer that originates on the bottom
edge of the flap create an unsteady pressure field at the flap side edge
causing sound to radiate. It has been determined in the known art
(Brooks, T. F. and Humphreys, W. M. Jr.: Flap Edge Aeroacoustic
Measurements and Predictions. AIAA 2000-1975), that the dominant flap
side edge noise emission region are located around mid-chord on the
pressure side of the flap edge and around 60-65% chord on the suction
side. These noise emission regions are aft of the front leading edge
region where the vortex initially forms--from the leading edge at 0%
chord to about 35% of the chord.
[0004] Some noise reduction concepts have been evaluated in the known art.
For example, in Koop et al., Reduction of Flap Side Edge Noise by Active
Flow Control, AIAA 2002-2469, some noise reduction was achieved by
blowing air into the flap side edge vortex. The air was blown through a
series of small round orifices located along the top and bottom side
edges of the flap between 13 and 35% chord--where the vortex forms.
BRIEF SUMMARY OF THE INVENTION
[0005] In accordance with the present invention, an aircraft flap and
method are disclosed which reduce noise radiating from the side of a flap
when the flap is deployed. The method targets the noise generation
regions of the flap side rather than the vortex formation region of the
flap. This reduction in noise is achieved by locating at least one slot
adjacent the side of the flap, and then forcing air out through the
slot(s) with a suitable mechanism when the flap is deployed.
[0006] One, two, or three or more slots are possible, where at least one
slot is located at one or more locations on the flap. Possible slot
locations can include a top surface of the flap, a bottom surface of the
flap, an intersection of the top and side surface of the flap, an
intersection of the bottom and side surfaces of the flap, and/or a side
surface of the flap.
[0007] In at least one embodiment, a device is provided which adjusts a
rate of the air forced out through the slot(s). In addition, in at least
one embodiment, a forward end of the slot is located into the end of the
vortex formation region and the slot extends into the region of maximum
noise generation
[0008] In at least one embodiment, the slot is substantially rectangular.
[0009] In at least one embodiment a slot may be comprised of a plurality
of sub-slots, or smaller openings, adjacent and aligned with one another,
so as to in effect together form an elongated slot, or opening.
[0010] It is an object of the present invention to reduce the noise
radiating from the side edge of a deployed flap.
[0011] It is also an object of the present invention to reduce flap side
edge noise by weakening the vortex/shear layer system and/or moving it
away from the flap side edge.
[0012] Other features and advantages of the present invention are stated
in, or apparent from, detailed descriptions of embodiments of the
invention found hereinbelow.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
[0013] FIG. 1 is a schematic right side elevation view of a first
embodiment of an aircraft flap including a cap, or side portion, in
accordance with the present invention.
[0014] FIG. 2 is a schematic top plan view of the cap depicted in FIG. 1.
[0015] FIG. 3 is a schematic cross sectional right side elevation view of
the cap depicted in FIG. 1 taken along the line 3-3.
[0016] FIG. 4 is schematic top plan view of a second embodiment of a cap
for an aircraft flap in accordance with the present invention.
[0017] FIG. 5 is a schematic cross sectional right side elevation view of
the second embodiment of the cap depicted in FIG. 4 taken along the line
5-5.
[0018] FIG. 6 is schematic bottom plan view of a third embodiment of a cap
in accordance with the present invention.
[0019] FIG. 7 is a schematic right side elevation view of a fourth
embodiment of a cap in accordance with the present invention.
[0020] FIG. 8 is a schematic right side elevation view of a fifth
embodiment of a cap in accordance with the present invention.
[0021] FIG. 9 is a schematic right side elevation view of a sixth
embodiment of a cap in accordance with the present invention.
[0022] FIG. 10 is a schematic right side elevation view of an embodiment
of a flap in accordance with the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0023] With reference now to the drawings in which like numerals represent
like elements throughout the views, depicted in FIGS. 1-3 is a first
experimental embodiment of a deployed aircraft flap 10 in accordance with
the present invention. It will be appreciated that an outer side 12 of
flap 10 is formed by a cap 14 and is attached by screws 15 to a remainder
of flap 10. The use of cap 14 attached to a flap 10 was for convenience
in constructing flaps for testing. Thus, it will also be appreciated that
in any actual aircraft flap incorporating the present invention, cap 14
would be omitted and the features of the present invention would be
integrally incorporated into the outer side or end of the actual flap.
[0024] Cap 14 used in the experiments for the present invention has a top
surface 16 and a bottom surface 18 which are coextensive with the top and
bottom surfaces of flap 10, and a side surface 20 (as if cap 14 were
integral). As typical in the art, flap 10 has a chord center line 22
defining a flap chord (length) c along which any dimension x is measured
to locate a point therealong, which measurement is expressed as a ratio
x/c and which is then referred to as some decimal part of chord or as a
percent. Hereafter, the flap dimensions related to c will be so
designated.
[0025] In order to reduce noise in accordance with the present invention,
air is blown or forced out of at least one slot provided in one or more
of surfaces 16, 18 and/or 20 of cap 14, as broadly shown by arrows 24 in
FIG. 1 directed up from top surface 16. In order to transmit this air to
the slot(s), flap 10 is suitably provided with a hollowed out portion 26
or other suitable conduit for the air. A source 28 of the air is provided
by a suitable system at a suitable location. A variety of systems are
suitable for air source 28 as known in the art, such as a pressurized air
bottle, an air bleed from the aircraft engine, a separate air intake from
the surrounding moving (relative to the aircraft) air, or the like. As
shown, a suitable throttle 30 can be used to control the rate of flow of
air to and hence out through the slot, with the initiation and adjustment
of throttle 30 being directed by a control 31 which may be part of the
aircraft overall control system or dedicated just to the control of air
source 28. A suitable location for the air source would, depending upon
the source being utilized, be easily determined by one with ordinary
skill in the art.
[0026] In accordance with a first embodiment of the present invention as
shown best in FIGS. 2 and 3, a slot 32 is provided in top surface 16.
Slot 32 is rectangular in shape and located a distance d from the side of
about 0. The forward edge f of slot 32 is about 0.27 c from the flap
leading edge and the rear edge r about 0.60 c from the flap leading edge.
The dimensions of slot 32 are about 0.167 c wide by about 0.33 c long,
for an open area of about 0. These dimensions are typical of what would
be provided for such a flap 10 with tip jet Mach numbers in the range of
zero to twice the free stream Mach number (which, as known, during
aircraft take off and landing the free stream Mach number is around 0.2).
Depicted in FIG. 3 is a cross sectional view through slot 32, showing the
flow 24 of air out of slot 32.
[0027] Besides the specific slot 32 depicted, other top surface slots can
be provided with different locations, numbers, shapes and sizes as
desired or determined to be needed for the particular flap or for a
particular noise reduction. By way of example, besides the location of
slot 32 described above, a similar shaped top surface slot could be
provided at other suitable locations, such as at f=0.43 c to r=0.6 c or
f=0.5 c to r=0.75 c (or even more) for higher Mach ranges of 0.34 and
0.30 respectively.
[0028] In accordance with a second exemplary embodiment of the present
invention, a slot 34 is provided in a second experimental cap 14A at an
intersection of top surface 16 and side surface 20 as shown in FIGS. 4
and 5. Slot 34 for the previously described flap 10 has a chord location
which can be the same as slot 32 (as well as other alternate locations as
noted); and dimensions y=0.0146 c and z=0.0083 c, for a diagonal opening
size s=0.0167 c.
[0029] In accordance with a third embodiment of the present invention, a
slot 36 in a third experimental cap 14B is provided in bottom surface 18
as shown in FIG. 6. Slot 36 has a location which can be the same as slot
32 (as well as other alternate locations as noted); and dimensions which
likewise can be the same as slot 32 (and hence slot 36 as depicted on cap
14B appears substantially identical to the depiction of top surface slot
32 of cap 14 in FIG. 2). And in another embodiment (whose depiction would
be substantially identical to that of FIG. 4), a slot can be provided at
an intersection of bottom surface 18 and side surface 20, with dimensions
and locations similar to slot 34 as noted above for the flap 10.
[0030] In accordance with a fourth depicted embodiment, a slot 38 in a
fourth experimental cap 14C is provided in side surface 20 as shown in
FIG. 7. Slot 38 has a location which can be the same as slot 32 (as well
as other alternate locations as noted, or even further forward such as
0.2-0.43 of chord); and a width and length dimensions which likewise can
be the same as slot 32. The position of slot 38 on side surface 20 is
about 0.31 c above chord centerline 22.
[0031] In accordance with additional embodiments as schematically depicted
in FIG. 8, a fifth experimental cap 14D can be provided with a slot 32 in
top surface 16 (indirectly identified by the associated air flow arrows),
a slot 36 in bottom surface 18 (indirectly identified by the associated
air flow arrows) and/or a slot 38 provided in side surface 20. Thus, any
combinations of two or three (or more) such slots can be provided as
desired in the flap. Similarly, as depicted in FIG. 9, a sixth
experimental cap 14E can be provided with a slot 34 at the intersection
of top surface 16 and side surface 20, a slot 40 at the intersection of
bottom surface 18 and side surface 20, and/or a slot 38 provided in side
surface 20; and with combinations of two or three such slots as desired
in the flap. Likewise, combinations of comer slots and surface slots
could also be provided, with or without a side slot. FIG. 10 depicts an
aircraft flap 10a in accordance with the present invention. FIG. 10
depicts the same embodiment as shown in FIG. 9, but without a cap. As
explained above, in an actual aircraft flap incorporating the present
invention, the present invention could be integrally incorporated into
the outer side and/or end of the flap.
[0032] Some tests have been performed to check the effectiveness of the
present invention at selected air flow speeds. The model used for these
tests incorporated a partially hollowed flap of 4.8 inch chord, with a
removable 0.25 inch wide, side edge cap such as discussed above. The air
blown into the flap exited through small slots as discussed above in the
side edge. Particle Image Velocimetry (PIV) measurements were performed
for four flap side edge configurations. In the first configuration, a
solid side edge was used, representing a baseline flap. For the other
three configurations, air was respectively blown through a thin
rectangular slot located on the top surface 16, the side surface 20, or
the bottom surface 18 of the flap side edge. For the top surface slot,
the slot extended from 50% chord to 75% chord (as measured from the flap
leading edge), was 2 mm wide and was located 1 mm from the flap side
edge. For the side surface slot, the slot extended from 27% chord to 60%
chord, was 2 mm wide and lay 3.8 mm above the chordline. Finally, for the
bottom surface slot, the slot extended along the bottom surface of the
flap between 27 and 60% chord, was also 2 mm wide, and lay 1 mm from the
flap bottom side edge.
[0033] The PIV measurements obtained for the top surface slot were with
tip jet Mach numbers of 0.075, 0.11 and 0.17, respectively. It was seen
that at 59% and 67% chord where the highest levels of the noise radiation
takes place (as previously determined), the vortex was greatly weakened,
as the vortex was pushed further off the top surface and its structure
was deteriorated. These positive effects are accentuated as the tip jet
Mach number increases. At 83% and 110% chord (i.e., downstream of where
the blowing takes place), the effect of the tip jet on the vortex
strength and location was still seen. The vortex was much weaker than in
the baseline case and centered approximately 4 mm further above the flap.
This flap configuration hence leads to a weaker shear flow coming off the
flap top side edge. This should result in a reduced level of noise
radiating from that edge. While the r dimension was limited to 0.75 c in
the tests, it is believed that larger r dimensions extending the top
surface slot closer to the flap trailing edge will result in even more
noise reduction.
[0034] The PIV measurements obtained for the bottom slot were with a tip
jet Mach number of 0.075, 0.11 and 0.17, respectively. The intent of
blowing from the bottom surface was to deflect the shear flow that is
coming off the bottom edge, i.e., forcing it to go around the edge
instead of coming straight off of it. This should reduce the noise
radiating from the bottom edge. For the tip jet Mach numbers of 0.11 and
0.17, it was seen at different locations that the shear layer wrapping
around the flap side edge was indeed farther away from the side surface
than in the baseline case. The vortex was also not able to move inboard
as with the baseline configuration. It was seen, however, that although
the blowing seems to displace the shear layer, it also strengthened it.
The resulting expected effect on the radiated noise was not as dramatic
as with the top surface slot and warrants further investigation. Blowing
with a tip jet Mach number of 0.075 does not appear to have any
significant effects on the flow.
[0035] The PIV measurements obtained for the side surface slot were with a
tip jet Mach number of 0.075, 0.11 and 0.17, respectively. The intent of
blowing from the side surface was to "build a retaining wall" to slow
down the travel of the strong side vortex to the top edge, and hence to
delay its merger onto the top surface and shorten the portion of the flap
top surface over which the vortex strong shear layer "rubs" against the
top edge (causing noise to radiate). The PIV results seemed to indicate
that the opposite effect was achieved. For the three tip jet Mach numbers
tested, the merging of the side vortex to the top surface was
accelerated. The blowing only contributed to "feed" the shear layer and
strengthen the vortex system. Nonetheless, it is expected that higher air
flow rates through the slot than those tested would provide the desired
noise reduction.
[0036] From the above experiments, it was shown that reduction of noise
radiating from the flap side was greater by blowing air from a slot
located along the top surface of the flap. This blown air greatly
weakened the top vortex system and pushed it further off the top surface.
These beneficial effects occurred with the lowest tip jet Mach number
tested and were accentuated at the higher tip jet speeds. Blowing from
the bottom surface was found to strengthen but also to deflect and push
the shear layer away from the flap edge, keeping the strong side edge
vortex further outboard. Because this was only observed for the two
highest tip jet Mach numbers, this means that the beneficial effects are
more likely to be achieved only with high enough tip jet speeds.
[0037] While the present invention has been described with respect to
exemplary embodiments thereof, it will be understood by those of ordinary
skill in the art that variations and modifications can be effected within
the scope and spirit of the invention.
* * * * *
