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Claims  |
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The embodiments of the invention in which an exclusive property or
privilege is claimed are defined as follows:
1. An exhaust nozzle for containing and directing the flow of exhaust gases
generated by a gas turbine engine, comprising:
an annular nozzle housing mountable to the aft end of said gas turbine
engine so as to extend rearwardly therefrom;
an annular shroud coaxially mounted to the aft end of said nozzle housing
for axial sliding movement relative to said housing, said shroud being
movable along a translational path between a forwardmost position and a
rearmost position, said shroud having an inwardly facing surface for
defining a flow passage for receiving said exhaust gases generated by said
gas turbine, a first portion of said inwardly facing surface adjacent a
forward end of said shroud being configured to form a flow passage of
constant cross-sectional area, and a second portion of said inwardly
facing surface adjacent said first portion configured to form a flow
passage of increasing cross-sectional area in the aft, axial direction;
a support tube mountable to the aft end of said gas turbine to extend
rearwardly therefrom, said support tube being mounted coaxially within
said nozzle housing and said shroud; and
a variable circumference centerbody axially mounted on said support tube
within said flow passage of said shroud forming a throat passage between
said inner surface of said shroud and said centerbody, said centerbody
including a first shell and a second shell, said first and second shells
each having a forward end and an aft end, the edges of said first and said
second shells abutting one another along a plane that is parallel to the
central axis of the exhaust nozzle when said shells are in a retracted
position, the aft ends of said first and said second shells being
pivotally attached to said support tube for pivotal movement of the
forward ends of said shells away from one another into an extended
position, said first and said second shells being configured to vary the
cross-sectional flow are of said throat passage by cooperation between the
pivotal movement of said shells and the translational movement of said
shroud, said variable centerbody being positioned axially within said
shroud to be adjacent said first and said second portions of said inwardly
facing surface of said shroud when said shroud is moved axially, said
throat passage being at a minimum area when said shroud is translated to
its rearmost position and said centerbody is in retracted position, and
said throat passage being at a maximum area when said shroud is translated
to its forwardmost position and said centerbody is in an extended
position.
2. The exhaust nozzle of claim 1, wherein said centerbody has a teardrop
shape when viewed in longitudinal section, said centerbody having a first
end and a second end, said second end having a pointed configuration and
being oriented toward the rear of said exhaust nozzle, said centerbody
presenting a circular cross-sectional area to exhaust gases flowing
through said flow passage when said first and said second shells are in a
retracted position, said centerbody presenting an oval cross-sectional
area to exhaust gases flowing through said flow passage when said first
and said second shells are in an extended position.
3. The exhaust nozzle of claim 2, wherein said first and said second shells
are arranged so that said plane along which said shells abut is oriented
horizontally with respect to said exhaust nozzle.
4. The exhaust of claims 1, 2, or 3 further comprising:
a plurality of finger seals connected to said support tube, said finger
seals configured and arranged to simultaneously contact said first and
said second shells and seal said centerbody from said flow passage.
5. The exhaust nozzle of claim 4, wherein said shroud includes a thrust
reverser cascades, said thrust reverser cascades being spaced radially
from the central axis of said shroud, and said thrust reverser cascades
passing through said first portion of said inwardly facing surface of said
shroud to an outer surface of said shroud.
6. The exhaust nozzle of claim 5, further comprising:
a shroud cover mounted to said nozzle housing for axial sliding movement
relative to said housing, said shroud cover being movable between a
forwardmost position and a rearmost position, said shroud cover configured
and arranged for independent translational movement along a translational
path that is coextensive with the translational path followed by said
shroud, said shroud cover configured to overlay said thrust reverser
cascades when said shroud and said cover are both in the forwardmost axial
position and when said shroud and said shroud cover are both in the
rearmost position, said cover configured to expose said thrust reverser
slots when said shroud is in its rearmost axial position and said shroud
cover is in its forwardmost axial position.
7. The exhaust nozzle of claim 6, wherein said shroud and said shroud cover
fit within a rearwardly opening annular groove at the aft end of said
nozzle housing.
8. The exhaust nozzle of claim 7, further comprising:
linear actuator means for moving said shroud between said forwardmost and
said rearmost positions and for transferring tensile and compressive
forces generated by bending moments within said shroud from said shroud to
said nozzle housing.
9. The exhaust nozzle of claim 8 further comprising:
means for moving said shroud cover between said forwardmost and said
rearmost positions.
10. The exhaust nozzle of claim 9, further comprising:
a guide track mounted on said support tube; and
a guide member mounted on each of said first and said second shells of said
centerbody, said guide members cooperating with said guide track to permit
movement of said first and said second shells in an aligned manner.
11. An exhaust nozzle for containing and directing the flow of exhaust
gases generated by a gas turbine engine comprising:
a nozzle housing mountable to the aft end of said gas turbine engine so as
to extend rearwardly therefrom, said nozzle housing having an inwardly
facing annular surface for defining a flow passage for receiving said
exhaust gases generated by said gas turbine engine;
a support tube mountable to the aft end of said gas turbine to extend
rearwardly therefrom, said support tube being mounted coaxially within
said nozzle housing; and
a variable circumference centerbody axially mounted on said support tube
within said flow passage of said nozzle housing forming a throat passage
between said inner surface of said nozzle housing and said centerbody,
said centerbody including a first shell and a second shell, said first and
said second shells each having a forward end and an aft end, the edge of
said first and said second shells abutting one another along a plane that
is parallel to the central axis of the exhaust nozzle when said shells are
in a retracted position, the aft ends of said first and said second shells
being pivotally connected to said support tube for pivotal movement of the
forward ends of said shells away from one another into an extended
position, said first and said second shells being configured to vary the
cross-sectional flow area of said throat passage by pivoting said first
and said second shells between said retracted and said extended positions,
said throat passage having a minimum cross-sectional flow area when said
centerbody is in an extended position and said throat passage having a
maximum cross-sectional flow area when said centerbody is in a retracted
position.
12. The exhaust nozzle of claim 11, wherein said centerbody has a teardrop
shape when viewed in longitudinal section, said centerbody having a first
end and a second end, said second end having a pointed configuration and
being oriented toward the rear of said exhaust nozzle, said centerbody
presenting a circular cross-sectional area to exhaust gases flowing
through said flow passage when said first and said second shells are in a
retracted position, said centerbody presenting an oval cross-sectional
area to exhaust gases flowing through said flow passage when said first
and said second shells are in an extended position.
13. The exhaust nozzle of claim 12, wherein said first and said second
shells are arranged so that said plane along which said shells abut is
oriented horizontally with respect to said exhaust nozzle.
14. The exhaust nozzle of claim 13, further comprising:
a plurality of finger seals connected to said support tube, said finger
seals configured and arranged to simultaneously contact said first and
said second shells and seal said centerbody from said throat passage.
15. The exhaust nozzle of claim 14, further comprising:
a guide track mounted on said support tube; and
a guide member mounted on each of said first and said second shells of said
centerbody, said guide members cooperating with said guide track to permit
movement of said first and said second shells in an aligned manner.
16. An exhaust nozzle for containing and directing the flow of exhaust
gases generated by a gas turbine engine, comprising:
an annular nozzle housing mountable to the aft end of said gas turbine
engine so as to extend rearwardly therefrom;
an annular shroud coaxially mounted to the aft end of said nozzle housing
for axial sliding movement relative to said housing, said shroud being
movable along a translational path between a forwardmost position and a
rearmost position, said shroud having an inwardly facing surface for
defining a flow passage for receiving said exhaust gases generated by said
gas turbine, a first portion of said inwardly facing surface adjacent a
forward end of said shroud being configured to form a flow passage of
substantially constant cross-sectional area, and a second portion of said
inwardly facing surface adjacent said first portion configured to form a
flow passage of increasing cross-sectional area in the aft, axial
direction;
linear actuator means for moving said shroud between said forwardmost and
said rearmost positions and for transferring tensile and compressive
forces caused by bending moments within said shroud from said shroud to
said nozzle housing; and,
centerbody means for forming a throat passage within said flow passage of
said shroud, said throat passage having a cross-sectional flow area;
means for moving a circumference of said centerbody to vary said
cross-sectional flow area;
said shroud coacting with said centerbody means so that said
cross-sectional flow area varies as a result of combined movements of said
shroud between said forwardmost and said rearmost positions and said
centerbody circumference.
17. The exhaust nozzle of claim 16, wherein said shroud includes a thrust
reverser cascade passing through said first portion of said inwardly
facing surface of said shroud to an outer surface of said shroud, said
shroud including blocker door means for obstructing said flow passage
formed by said shroud.
18. The exhaust nozzle of claim 17 further comprising:
a shroud cover mounted to said nozzle housing for axial sliding movement
relative to said housing, said shroud cover being movable between a
forwardmost position and a rearmost position, said shroud cover arranged
for independent translational movement along a translational path that is
coextensive with the translational path followed by said shroud, said
shroud cover being configured to overlay said thrust reverser cascade when
said shroud and said shroud cover are both in the forwardmost position and
when said shroud and said shroud cover are both in the rearmost position,
said shroud cover being configured to expose said thrust reverser cascade
when said shroud is in the rearmost position and said shroud cover is in
the forwardmost position; and,
means for moving said shroud cover between said forwardmost and said
rearmost positions. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to exhaust nozzles for directing gas turbine exhaust
gas into the atmosphere to propel an airplane or other vehicle. More
particularly, this invention relates to a variable centerbody plug-type
exhaust nozzle and translating shroud assembly for providing optimum
thrust over a wide range of flight conditions, including operation of an
aircraft at subsonic, transonic, and supersonic speeds.
It is known that maximum thrust and operating efficiency of a gas turbine
engine that supplies propulsive thrust is obtained when the engine exhaust
effluent is directed through an exhaust nozzle that controls the expansion
of the exhaust gases. Controlled expansion of the high temperature, high
pressure gases supplied by the gas turbine engine increases the particle
velocity of the exhaust effluent and thereby increases the momentum of the
thrust exhaust producing stream. In this respect, maximum operating
efficiency is generally achieved when the nozzle is configured to exit the
exhaust stream at substantially the same pressure as that of the
surrounding atmosphere.
When an aircraft operates at subsonic, transonic, and supersonic speeds,
the exhaust nozzle pressure ratio, i.e., the ratio of the total fluid
pressure upstream of the nozzle to the ambient atmospheric pressure,
varies over a substantial range. In particular, under subsonic flight
conditions, the nozzle pressure ratio is sufficiently low that full
expansion is not required, while under supersonic flight conditions, the
nozzle pressure ratio is quite high and proper expansion of the exhaust
effluent must be effected. Moreover, fairly substantial variations in
pressure ratio results from various engine throttle settings, and in some
cases, also results from "ram effect" when an increased amount of air is
effectively forced through the engine as the aircraft moves through the
atmosphere at high speeds.
One way of achieving good performance under the various flight modes is by
using an exhaust nozzle having a variable throat area to allow the
expansion ratio of the exhaust nozzle to vary as the pressure ratio
varies, thereby maximizing engine performance. As known to those skilled
in the art, the expansion ratio of an exhaust nozzle is the ratio of the
final area of exhaust gas when the exhaust gas is at ambient atmospheric
pressure to the area of the throat or smallest cross-sectional flow area
in the exhaust nozzle. Accordingly, many attempts have been made to design
variable geometry exhaust nozzles that are operable to vary the throat
area of the exhaust nozzle and the final area of exhaust gas exiting the
nozzle. Variation of the throat area can be achieved by changing the
geometry of the inner, central center portion of an exhaust nozzle, while
the final area of exhaust gas exiting the exhaust nozzle can be adjusted
by varying the geometry of the outer housing of the exhaust nozzle.
Although various nozzle configurations have been proposed to accommodate
the requirement for both a variable throat area and the capability of
varying the final area of exhaust gas, such prior art nozzles have not
simultaneously met all of the necessary design criteria. Nozzles such as
convergent-divergent nozzles and variable cross section plug-type nozzles
have been proposed. The fixed geometry convergent-divergent nozzle
performs well at design conditions, but has a drawback of severe thrust
losses at less than the design pressure ratio. On the other hand, variable
cross section plug-type nozzles, such as the multiple-leaf plug-type
nozzle, have been proposed due to their good flight performance and
favorable reduced jet noise. However, a major problem with prior art
multiple-leaf plug-type nozzles has been the mechanical complexity
involved with variation of throat area. Additionally, while the
multiple-leaf plug-type nozzle provides very good area control, the leaves
tend to leak when the centerbody is pressurized internally with cooling
air. Making the leaves stiff enough so that they will seal under load
imposes too large of a weight penalty.
Another factor to be considered in the design of an exhaust nozzle for use
on a supersonic aircraft is that some supersonic gas turbine engine
applications restrict the amount of engine shroud perimeter available for
placement of thrust reverser cascades. In such a situation, reverser
cascade length must generally be increased to maintain adequate thrust
reverser flow area. Such an increase in length is usually accompanied by
an undesirable increase in weight.
Accordingly, it is an object of this invention to provide a variable
centerbody plug-type exhaust nozzle and translating shroud assembly for
use on a gas turbine engine, such exhaust nozzle being operable over the
normal flight regime of a supersonic airplane.
It is another object of this invention to provide a variable geometry
exhaust nozzle of the above-described type wherein the geometry of the
rearwardly extending centerbody and the position of the translating shroud
can be continuously varied, either independently or simultaneously, to
provide a wide range of nozzle throat areas and final expansion areas.
It is still another object of this invention to provide a variable geometry
exhaust nozzle of the above-described type wherein adequate thrust
reverser flow area can be maintained without increasing the exhaust nozzle
length, and while using a limited amount of engine shroud perimeter for
targeting the exhaust gas to preferred locations.
It is yet another object of this invention to provide an exhaust nozzle of
the above-described type that is relatively light in weight, containable
within a region of relatively low volume, and has a relatively uncomplex
structure to reduce weight, facilitate manufacture, and enhance
reliability.
SUMMARY OF THE INVENTION
These and other objects are achieved in accordance with this invention by
an exhaust nozzle wherein an annular nozzle housing is mountable to the
aft end of a gas turbine engine and extends rearwardly therefrom. A shroud
is slidably connected to the aft end of the nozzle housing so as to be
slidable in an axial direction between a forwardmost position and a
rearmost position. An inwardly facing surface of the shroud defines a flow
passage for receiving the exhaust gases generated by the gas turbine
engine and such surface includes a first portion adjacent the shroud's
forward end configured to form a flow passage of substantially constant
cross-sectional area. A second shroud surface portion axially extending
from the rear of the first portion is configured to form a flow passage of
increasing cross-sectional area in the aft, axial direction. A support
tube is mounted to the aft end of the gas turbine engine and extends
rearwardly therefrom, coaxially within the nozzle housing and the shroud.
A variable circumference centerbody is axially mounted on the support tube
within the flow passage of the shroud, forming a throat passage between
the inner surface of the shroud and the centerbody.
The centerbody includes first and second shells that abut one another along
a plane that is parallel to the nozzle axis when the centerbody is in the
retracted position. The aft ends of the shells are pivotally attached to
the support tube for pivotal movement of the forward ends of the shells
away from one another into an extended position so as to vary the the
cross-sectional area of the throat passage in cooperation with the
translational movement of the shroud. The throat passage is configured to
be at a minimum cross-sectional area when the shroud is translated to its
aftmost position and the centerbody shells are in a retracted position,
and the throat passage is at a maximum cross-sectional area when the
shroud is translated to its forwardmost position and the centerbody shells
are in the extended position. The centerbody may be extended in either
shroud position to change throat area, independently of the final area of
the exhaust gas.
In a preferred embodiment, the variable circumference centerbody has a
teardrop shape when viewed in longitudinal section with an upper and a
lower shell, and the pointed end of the centerbody directed rearwardly.
The rearmost end of the centerbody has a pointed configuration to reduce
aerodynamic drag. Additionally, the centerbody is configured to present a
preferred circular cross section to the exhaust gases passing through the
flow passage when the centerbody is in the retracted position. A
nonannular throat area is produced when the centerbody is opened. The
shroud thickness is such that the shroud can be adjusted to achieve the
desired throat areas at subsonic and supersonic cruise with the centerbody
in its retracted position. A gap formed between the shells when the
centerbody is in the extended position is sealed by vertically oriented
finger seals that press outwardly against the inner surface of the
centerbody shells due to the higher internal pressure of cooling air
within the centerbody. The finger seals are attached to the support tube
by means of horizontal support brackets that extend radially outward from
the support tube.
The centerbody shells are extended and retracted by means of a rotating
screw shaft and associated nut collar that is mounted coaxially within the
support tube. One end of each of a first and a second extension member is
pivotally connected to the first and second shells, respectively. The
other end of each of the extension members is pivotally connected to the
nut collar. The extension members are configured so that as the nut collar
moves back and forth along the screw shaft, the centerbody shells are
pivotally extended and retracted.
To prevent horizontal, lateral movement of the centerbody shells, their
forward ends are formed with two vertically extending guide bars that are
spaced apart horizontally on either side of the support tube. Each of the
guide bars on the first shell is vertically aligned with a guide bar on
the second shell, and each pair of vertically aligned guide bars is
contained within a vertically oriented guide track secured to the support
tube.
In the preferred embodiment, the shroud has an annular shape, and thus,
when the centerbody is in the retracted position for use at supersonic
speeds, the throat passage formed between the inner surface of the shroud
and the centerbody has an annular configuration. However, when the
centerbody is in the extended position, the throat passage has a
nonannular shape.
The shroud is also configured so that thrust reverser cascades are located
within designated circumferential sections of the first surface portion of
the shroud. To prevent the thrust reverser cascades from being exposed
when the shroud is translated to its rearmost position an elongated shroud
cover, of "C" shape in longitudinal section, is used to extend over the
forward end of the shroud and cover both the inner and outer openings of
the thrust reverser cascades. The shroud and shroud cover are configured
to nest so that they can be jointly retracted into an annular groove that
is located on the rear edge of the nozzle housing. The shroud and shroud
cover can be moved independently so that when the thrust reverser cascades
are to be used, the shroud can be translated rearwardly out of the annular
groove while the shroud cover is kept in its retracted position, thereby
exposing the thrust reverser cascades.
BRIEF DESCRIPTION OF THE DRAWINGS
A better understanding of the present invention can be obtained from the
following specification which is to be read in conjunction with the
accompanying drawings wherein:
FIG. 1 is a cut-away perspective view of the exhaust nozzle with the
centerbody in the retracted position and the shroud moved into its
rearmost position;
FIG. 2 is a cross-sectional side elevation view of the exhaust nozzle with
the upper and lower shells of the variable centerbody in the extended
position and the shroud in its forwardmost position as the exhaust nozzle
would be configured for takeoff;
FIG. 3 is a cross-sectional side elevation view of the exhaust nozzle with
the upper and lower shells of the variable centerbody in the retracted
position and the shroud moved into its rearmost position for use during
supersonic flight conditions;
FIG. 4 is a cross-sectional view of the variable centerbody of FIG. 3 taken
along section line 4--4 showing the pivoting mechanism of the upper and
lower shells of the centerbody;
FIG. 5 is a cross-sectional view of the exhaust nozzle of FIG. 3 taken
along section line 5--5 showing the actuation mechanism used to extend and
retract the upper and lower shells of the centerbody with the centerbody
and shroud positioned for use at supersonic cruise;
FIG. 6 is a cross-sectional view of the exhaust nozzle of FIG. 2 taken
along section line 6--6 showing the actuation mechanism used to extend and
retract the upper and lower shells of the centerbody and the centerbody
and shroud positioned for use at takeoff;
FIG. 7 is an enlarged, partial cross-sectional view of the exhaust nozzle
with both the shroud and shroud cover in the rearmost position;
FIG. 8 is an enlarged, partial cross-sectional view of the exhaust nozzle
with the shroud in the rearmost position and the shroud cover in the
forwardmost position to deploy the thrust reverser cascades and the
blocker door actuated.
DETAILED DESCRIPTION
FIG. 1 depicts a variable throat area exhaust nozzle 10 for cooperating
with a gas turbine engine, the nozzle receiving end of which is indicated
at 11. The exhaust nozzle includes an annular nozzle housing 12 that is
mounted to the end 11 of the turbine engine and an annular, axially
translatable shroud 14 that is slidably mounted at the rear of the nozzle
housing for coaxial movement relative to housing 12 between a forwardmost
position and a rearmost position. Also attached to the aft end of the
turbine engine is a support tube 16 that is positioned coaxially within
the nozzle housing 12. The support tube 16 carries a teardrop shaped,
variable cross section centerbody 20 adjacent the rear portion of the
nozzle housing 12 that together with shroud 14 channels the exhaust gas
flowing through the nozzle housing 12. The cross-sectional area of the
centerbody 20 can be varied in cooperation with the axial position of the
shroud 14 to achieve the proper expansion ratio for the exhaust gas for a
given pressure ratio. Additionally, the centerbody 20 and shroud 14 are
both configured to cooperatively provide a circular expansion zone at
supersonic cruise speeds. Referring to FIGS. 2 and 3, the gas turbine
engine terminates at an exhaust flange 21. The axial centerline 22 of
exhaust nozzle 10 is shown skewed from centerline 23 of gas turbine engine
11 following conventional practice for the mounting of exhaust nozzles.
Looking at the exhaust nozzle 10 in more detail, it can be seen in FIGS. 1,
2, and 3 that the inner surface 24 of nozzle housing 12 and the inner
surface 25 of shroud 14 form a flow passage 26 for receiving exhaust gases
generated by the turbine engine. As most clearly shown in FIG. 3, a
rearwardly opening annular groove 28 is located in the rear portion of
nozzle housing 12 to receive annular shroud 14 and an annular shroud cover
30, which will be described in more detail later.
Also shown in FIGS. 2 and 3 are conventional linear actuators 32 that are
mounted forward of annular groove 28 and oriented parallel to axial
centerline 22 for moving the shroud 14 between the forwardmost and
rearmost positions. As shown in the Figures, the actuators 32 are located
between the inner and outer surfaces of the nozzle housing 12, so they are
not directly exposed to hot exhaust gases. However, since actuators 32
must operate in a high temperature environment, they are preferably
pneumatically operated. The interconnection between the actuator 32 and
the shroud 14 is by an actuator rod 34 that is attached to the forward end
of shroud 14 by means of a clevis 36 or some other conventional method of
connection.
In a preferred embodiment, the shroud 14 is a single unit so that the
shroud translates as a whole when the actuators 32 are energized. In this
embodiment, synchronous actuators 32 used to move the shroud 14 are spaced
circumferentially around the nozzle housing 12 so that the force imparted
to the shroud for translational movement is applied evenly to the shroud.
Bending moments produced in shroud 14 due to the shroud overhang and
impact loads, e.g., landings, are retracted to by actuators 32, which
transfer tensile and compressive loads to the nozzle housing. Nozzle
housing 12 reacts directly to radial loads imposed by the shroud.
Still referring to FIGS. 2 and 3 a transverse, cross-sectional view of
shroud 14 discloses that the shroud has a forward portion 14a and a rear
portion 14b. The forward portion 14a of the shroud 14 includes thrust
reverser cascades 40 at selected circumferential locations. The thrust
reverser cascades will be described in more detail later. The inside
diameter of the forward portion of the shroud is substantially constant
for the length of the forward portion. The rear portion 14b of the shroud
14 is contiguous with the forward portion and has a continuously
increasing inside diameter from adjacent the forward portion 14a rearward
to the rear edge of the shroud 14. When viewed in a transverse
cross-section, the inner surface of rear portion 14b has a concave form to
provide an increasing inside diameter rearwardly, while the transition
area between forward portion 14a and rear portion 14b has a slightly
convex configuration to minimize flow separation of exhaust gases flowing
from the forward portion to the rear portion. The varying inside diameter
of the shroud, together with its translational capability, cooperates with
the variable cross-sectional area of centerbody 20 to vary the throat area
of the exhaust nozzle.
As mentioned previously, incorporated within designated circumferential
portions of shroud 14 are the thrust reverser cascades 40. The thrust
reverser cascades utilize approximately 50 percent of the shroud perimeter
in the preferred embodiment, since, as known to those skilled in the art,
not all of the shroud perimeter is available for thrust reverser use due
to problems of reingestion by the turbine engine and creation of unwanted
lift when the thrust reversers are actuated. In the present embodiment,
the thrust reverser cascades 40 are conventionally constructed with curved
divertors 42 arranged in longitudinally oriented rows or cascades. The
thrust reverser cascades 40 are positioned within shroud 14 so that when
the shroud is in the forwardmost position, the thrust reverser cascades 40
are positioned within the annular groove 28. When the thrust reverser
cascades 40 are to be used, e.g., during landings, shroud 14 is moved to
the rearmost position.
Looking at FIGS. 3 and 7, it can be seen that the shroud cover 30,
mentioned previously, has an elongated "C"-shape in longitudinal section
and is configured to cover the reverser cascades 40 when shroud 14 is in
the rearmost position and the thrust reverser is not being used. The
shroud cover 30 is preferably an annularly shaped, one-piece member that
translates between a forwardmost and a rearmost position independently of
shroud 14. The shroud cover is moved translationally by means of linear
actuators 43 that are spaced circumferentially from and mounted parallel
to the actuators 32 used to extend and retract the shroud 14. The ends of
rods 45 of linear actuators 43 are connected to the forwardmost end of
shroud cover 30 by clevises 46. When the shroud cover 30 and shroud 14 are
both in the forwardmost position, the shroud is nested within the shroud
cover, and both members are positioned within groove 28. The length of
thrust reverser cascades 40 is shorter than the distance of translational
movement necessary to position the shroud in its rearmost position due to
the combination of the translation of shroud 14 and thrust reverser
cascades 40 with the translation of shroud cover 30. By using a
translating shroud cover, the distance of translation of the shroud to
expose sufficient thrust reverser flow area is less than if a translating
shroud cover were not used. Thus, the thrust reverser cascade length adds
no additional length to the exhaust nozzle.
As shown in FIGS. 7 and 8, a plurality of thrust reverser blocker doors 44
are pivotally mounted on the shroud 14 in a circumferential row that is
aligned with the rearmost end of each thrust reverser cascade 40. In its
retracted position as in FIG. 7, i.e., when the thrust reverser is not
being used, blocker doors 44 lay flush with the inner surface of shroud 14
beneath shroud cover 30. When actuated as in FIG. 8, the blocker doors
pivot inwardly about their rearmost ends so that the forward ends of the
blocker doors travel through an arcuate path until they contact the
surface of centerbody 20. With the blocker doors 44 in the extended
position in contact with the centerbody 20, exhaust gases that are flowing
rearwardly through the flow passage 26 are diverted by the blocker doors
to flow outwardly through thrust reverser cascades 40 as indicated by the
arrows marked with the letter A.
The blocker doors 44 may be actuated by any conventional means. For
example, as shown in FIG. 8, the rod of an actuator 48 is connected to one
end of a lever arm 50 that is pivotally mounted to an inner portion of
shroud 14. The other end of the lever arm is slidably attached to a slide
bar 52 mounted on the lower surface of blocker door 44. When the blocker
door 44 is to be raised, the rod of actuator 48 is extended, urging the
lever arm 50 to pivot and force the blocker door to pivot upwardly.
As mentioned before, and shown in FIG. 1, the forward end of the support
tube 16 is attached to the nozzle receiving end 11 of the turbine engine
with the support tube mounted concentrically about the exhaust nozzle
axial centerline 22. The rearmost end of the support tube 16 extends
axially beyond the rear edge of the shroud 14 when the shroud is in its
rearmost position. Support tube 16 is a hollow, cylindrically shaped tube
that carries cooling air to the centerbody 20 in addition to containing a
portion of the mechanism used to vary the cross-sectional area of the
centerbody 20, which will be described in more detail later. The support
tube 16 is also used to support and position the centerbody 20
concentrically about axial centerline 22.
As shown in FIGS. 1, 2, and 3, centerbody 20 is mounted on the aft portion
of the support tube 16, with the forward end of the centerbody 20
approximately aligned with the rear edge of the nozzle housing 12. The
centerbody 20 generally has a teardrop shape with the larger diameter end
of the centerbody oriented toward the front of the exhaust nozzle 10. The
rearmost end of the centerbody 20 converges to form a pointed end. In the
preferred embodiment, the centerbody 20 is configured from an upper shell
20a, a lower shell 20b, and a rear, cone-shaped section 20c. The crown 58
or line of largest circumference of the upper and lower shells 20a and 20b
of centerbody 20 is axially positioned so that it is approximately aligned
with the rearmost edge of shroud 14 when the shroud is in its forwardmost
position. The upper and lower shells 20a and 20b pivot away from one
another in a vertical direction from a retracted position into an extended
position. As shown in FIG. 5, when in the retracted position, the
centerbody 20 presents a circular cross section to the exhaust gases in
the flow passage 26, thus, an annularly shaped throat passage 60 is formed
between the crown of the centerbody 20 and the inner surface 25 of the
shroud 14. As shown in FIG. 6, when the upper and lower sections pivot
away from one another into the extended position, the centerbody 20
presents an oval cross section in the flow passage 26 that is symmetric
about a longitudinal, vertical plane through the exhaust nozzle 10 with
the throat passage being nonannualar.
Referring now to FIG. 4, the aft ends of the centerbody upper and lower
shells 20a and 20b pivot about a horizontal axis through the aft end of
the support tube 16. Pivot arms 62 are formed on the inner surface of the
upper and lower shells of the centerbody, and are pivotally attached to a
crossbar 64 that extends horizontally from the support tube 16 adjacent
its aft end. The aft ends of the upper and lower shells of the centerbody
20 abut the forward end of the cone-shaped section 20c, which is rigidly
mounted to the aft end of the support tube 16.
Pivotal movement of the centerbody upper and lower shells 20a and 20b is
achieved by means of a rotating screw shaft 68 and a nut collar 70 that is
mounted on the screw shaft. The screw shaft is mounted coaxially within
the support tube 16, and is preferably rotated by a pneumatic motor (not
shown) because of the high temperature of the working environment, though
other conventional means may be used. As the shaft rotates, the nut collar
moves axially along the screw shaft. A first extension member 72 has its
inner end pivotally connected to the upper side of the nut collar 70 and
its outer end pivotally connected to the upper shell 20a. A second
extension member 74 is likewise pivotally connected to the lower side of
the nut collar 70 and the centerbody lower shell 20b. The extension
members 72 and 74 are configured so that when nut collar 70 is at the
forward end of screw shaft 68, the centerbody upper and lower shells 20a
and 20b are in the abutting or retracted position with the first extension
member 72 angled upwardly and rearwardly and the second extension member
74 angled downwardly and rearwardly. When the nut collar 70 is moved to
the aft end of the screw shaft 68, the upper and lower shells are
separated into the extended position with both extension members 72 and 74
positioned vertically.
As shown in FIGS. 2 and 3, two vertically oriented guide bars 80 are formed
in the forward end of each of the centerbody upper and lower shells 20a
and 20b, respectively. The two guide bars 80 on each of the shells are
horizontally spaced from one another so that they are positioned on each
side of the support tube 16. Each of the guide bars on the centerbody
lower shell 20b are positioned in vertical alignment with a guide bar on
the upper shell 20a so that a pair of vertically aligned guide bars can be
contained within guide tracks 82 that are attached to opposing, lateral
sides of the support tube 16 as shown in FIG. 1. The guide bars 80 and
guide tracks 82 cooperate to prevent horizontal movement of the centerbody
upper and lower shells 20a and 20b as the shells move with respect to one
another.
When the centerbody upper and lower shells 20a and 20b pivot away from one
another, a gap is created between the edges of the sidewalls of the
shells. As illustrated in FIG. 6, the gap is closed by two rows of
vertically oriented, flexible finger seals 84 on each side of the support
tube 16 that prevents leakage of the higher pressure cooling air within
the centerbody 20. The finger seals 84 are mounted at the outer end of
horizontally oriented support plates 86 that extend from diametrically
opposed sides of the portion of the support tube 16 within the centerbody
20. As shown in FIG. 5, when the centerbody shells abut in the retracted
position, the finger seals 84 flex inwardly and rest against the inner
surface of the centerbody 20. In the preferred embodiment, the seals 84
are formed from thin sections of high temperature steel.
As shown in FIGS. 2 and 3, a tubularly shaped fairing 90 covers the forward
portion of the support tube 16 and extends coaxially over the support tube
16 between the rear of the turbine engine and the forward end of
centerbody 20. The fairing 90 is outwardly flared at its aft end to cover
the guide tracks 82 and form an aerodynamically smooth transition area at
the forward end of centerbody 20. In the preferred embodiment, the fairing
90 is a fixed structure, though in an alternate embodiment, the aft end of
the fairing 90 could be made to have a flexible flared area to allow the
fairing to follow the movement of the centerbody shells and thereby
further improve the aerodynamic characteristics of the transition area at
the forward end of the centerbody 20.
Operation
During operation of the aircraft at speeds below mach 1.0, the expansion
ratio of the exhaust nozzle 10 is kept at approximately 1.0 due to the
pressure ratio experienced by the turbine engine at subsonic speeds. This
is accomplished by keeping the shroud in the forwardmost position. In the
preferred embodiment, the proper throat area is obtained at takeoff by
opening the centerbody 20 into its fully extended position as shown in
FIGS. 2 and 6, thus | | |
