WO1998059162A1 - Multi-stage mixer/ejector for suppressing infrared radiation - Google Patents

Multi-stage mixer/ejector for suppressing infrared radiation Download PDF

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Publication number
WO1998059162A1
WO1998059162A1 PCT/US1998/011853 US9811853W WO9859162A1 WO 1998059162 A1 WO1998059162 A1 WO 1998059162A1 US 9811853 W US9811853 W US 9811853W WO 9859162 A1 WO9859162 A1 WO 9859162A1
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WO
WIPO (PCT)
Prior art keywords
lobes
exhaust
ejector
stage
flow
Prior art date
Application number
PCT/US1998/011853
Other languages
French (fr)
Inventor
Mark H. Hammond
Walter M. Presz, Jr.
Original Assignee
Sikorsky Aircraft Corporation
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sikorsky Aircraft Corporation filed Critical Sikorsky Aircraft Corporation
Priority to EP98931220A priority Critical patent/EP0991860B1/en
Priority to DE69802083T priority patent/DE69802083T2/en
Priority to AU81397/98A priority patent/AU8139798A/en
Priority to JP50453699A priority patent/JP2002511128A/en
Publication of WO1998059162A1 publication Critical patent/WO1998059162A1/en

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02KJET-PROPULSION PLANTS
    • F02K1/00Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto
    • F02K1/46Nozzles having means for adding air to the jet or for augmenting the mixing region between the jet and the ambient air, e.g. for silencing
    • F02K1/48Corrugated nozzles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64DEQUIPMENT FOR FITTING IN OR TO AIRCRAFT; FLIGHT SUITS; PARACHUTES; ARRANGEMENT OR MOUNTING OF POWER PLANTS OR PROPULSION TRANSMISSIONS IN AIRCRAFT
    • B64D33/00Arrangements in aircraft of power plant parts or auxiliaries not otherwise provided for
    • B64D33/04Arrangements in aircraft of power plant parts or auxiliaries not otherwise provided for of exhaust outlets or jet pipes
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02KJET-PROPULSION PLANTS
    • F02K1/00Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto
    • F02K1/36Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto having an ejector
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02KJET-PROPULSION PLANTS
    • F02K1/00Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto
    • F02K1/38Introducing air inside the jet
    • F02K1/386Introducing air inside the jet mixing devices in the jet pipe, e.g. for mixing primary and secondary flow
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02KJET-PROPULSION PLANTS
    • F02K1/00Plants characterised by the form or arrangement of the jet pipe or nozzle; Jet pipes or nozzles peculiar thereto
    • F02K1/78Other construction of jet pipes
    • F02K1/82Jet pipe walls, e.g. liners
    • F02K1/822Heat insulating structures or liners, cooling arrangements, e.g. post combustion liners; Infrared radiation suppressors
    • F02K1/825Infrared radiation suppressors
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y80/00Products made by additive manufacturing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64DEQUIPMENT FOR FITTING IN OR TO AIRCRAFT; FLIGHT SUITS; PARACHUTES; ARRANGEMENT OR MOUNTING OF POWER PLANTS OR PROPULSION TRANSMISSIONS IN AIRCRAFT
    • B64D33/00Arrangements in aircraft of power plant parts or auxiliaries not otherwise provided for
    • B64D33/04Arrangements in aircraft of power plant parts or auxiliaries not otherwise provided for of exhaust outlets or jet pipes
    • B64D2033/045Arrangements in aircraft of power plant parts or auxiliaries not otherwise provided for of exhaust outlets or jet pipes comprising infrared suppressors
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T50/00Aeronautics or air transport
    • Y02T50/60Efficient propulsion technologies, e.g. for aircraft

Definitions

  • This invention is directed to engine mixer/ejectors, and more particularly, to an multi-stage mixer/ejector operative to suppress the infrared signature radiated by the exhaust plume of an engine and/or the various hot metal components thereof.
  • the exhaust plume of gas turbine engines is a source of high infrared energy which may be used for targeting/tracking purposes by heat seeking missiles and/or various forms of infrared imaging systems, e.g., Night Vision Goggles (NVGs).
  • heat seeking missiles obtain directional cues from the infrared energy, which directional cues are more precise depending upon the intensity, e.g., temperature, and total energy emitted by the exhaust plume.
  • infrared imaging systems amplify the infrared energy by a factor of about 10.000 and may be used by hostile forces for early detection and/or targeting of surface-to-air/air-to-air missiles. Accordingly, it is highly desirable to reduce the infrared emissions (also referred to as the IR signature) of such engines to a practical minimum to avoid detection, acquisition and/or tracking by enemy threats/forces.
  • infrared suppression systems have been designed and fielded which effect mixing of low temperature ambient air with the high temperature engine exhaust to reduce the IR signature radiated therefrom.
  • Secondary objectives may include: (i) minimizing system or configuration complexity to reduce fabrication costs, (ii) minimizing the external aerodynamic drag produced by such IR suppressors, and/or (iii) suppressing the acoustic emissions emanating therefrom which may also be a source of detection.
  • Hurley U.S. Patent 4,018,046 discloses an InfraRed (IR) suppressor for reducing the infrared radiation emitted from the exhaust plume and/or hot metal parts of a gas turbine engine.
  • the IR suppressor includes an ejector vane assembly which is adapted for receiving a primary flow of engine exhaust and which is operative to entrain a first flow of cooling air into the primary exhaust flow.
  • the primary flow of gases diffused from and entrained by the ejector vane assembly are fed into an arcuate duct which, due to its spatial position relative to the ejector vane assembly, produces an annular space for entraining a second flow of cooling air.
  • the first and second flows are admixed with the primary exhaust flow to effect heat transfer therebetween and. consequently, to suppress the IR signature emitted from the exhaust plume.
  • the curved shape of the arcuate duct and/or the use of turning vanes disposed internally thereof serve to prevent direct line-of-sight viewing into the IR suppressor. That is. the shape prevents viewing of radiant energy emitted by hot internal components such as from the ejector vane assembly or from the turbine section of the engine.
  • the ejector vane assembly described therein includes a plurality of V-shaped ejector vanes which entrain cooling air at a plurality of angularly spaced positions while additionally serving to introduce air toward the center of the engine exhaust. More specifically, each of the ejector vanes forms a V-shaped channel which is open to ambient air at one end thereof and is oriented to direct flow radially toward the core of the primary exhaust flow.
  • the ejector vane assembly furthermore, clusters the ejector vanes as close as practicable to the core of the primary exhaust flow and, furthermore, includes a means for adjusting the flow area through the ejector vanes to ameliorate engine performance. That is, the adjustment means effects collapse of each ejector vane so as to increase the flow area and reduce the back-pressure on the engine.
  • the ejector vane assembly improves mixing, i.e.. reduces the IR signature, by directing cooling air into a core region of the engine exhaust
  • the ejector vane assembly requires a large number of individual components.
  • the multiplicity of components each being a potential source of repair and maintenance, reduces the overall reliability of the IR suppressor system.
  • the adjustment means attempts to reduce flow restriction, the anticipated power loss produced by the ejector vane assembly is on the order of between 3% to 6%.
  • the Presz '961 and '315 patents describe single and multi-stage mixer/ejector nozzles, respectively, each having a plurality of adjoined lobes formed at an outlet end thereof.
  • the adjoined lobes define a primary flow trough for channeling a primary flow of high velocity /energy fluid, such as the exhaust of a gas turbine engine, and a secondary flow trough for channeling a secondary flow of low velocity/energy fluid such as ambient air.
  • the primary and secondary flow troughs are alternately disposed about the periphery of the nozzle such that thin sheets of high energy fluid flow from the trough outlets, transfer kinetic energy to the low energy fluid, and entrain the secondary flow into the primary flow.
  • the adjoined lobes produce axial vortices which rapidly admix the primary and secondary flows.
  • the adjoined lobes described in the Presz '961 and '315 patents are known to have utility on aircraft engines to both increase thrust and for suppressing the thermal energy radiated from the engine.
  • the nozzle configurations disclosed therein fail to fully mix the flows, particularly in the core region of the primary exhaust flow. That is, in all of the embodiments described therein, the lobes entrain the secondary cooling flow into a perimeter region of the flow such that a central core or band of high temperature exhaust remains as the flow exits the nozzle. While the core of high temperature flow will eventually admix downstream, it will be appreciated that the degree of IR suppression is compromised until such energy is diffused.
  • IR InfraRed
  • a multi-stage mixer/ejector having at least one exhaust nozzle which includes inlet conduit adapted for receiving a primary flow PF of engine exhaust and a plurality of adjoined lobes integrally formed in combination with the inlet conduit.
  • the adjoined lobes of the exhaust nozzle are characterized by a first and second plurality of penetrating lobes which are axially staggered with respect to each other and which are adapted for admixing low-temperature gaseous fluid with the high-temperature exhaust.
  • at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle to effect thorough mixing of the low temperature gaseous fluid with the engine exhaust.
  • Fig. 1 is a profile view of a helicopter illustrating an exemplary installation of a multi-stage mixer/ejector according to the present invention
  • Fig. 2 is a partially broken-away perspective view of a multi-stage mixer/ejector disposed in combination with the aft end of a gas turbine engine, which multi-stage mixer/ejector includes tandemly-arranged first and second stage exhaust nozzles;
  • Fig. 3a is an isolated perspective view of the first stage exhaust nozzle having a plurality of adjoined lobes forming an outlet end of the exhaust nozzle, wherein the adjoined lobes further include a first and second plurality of penetrating lobes which are axially staggered relative to each other and wherein at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle;
  • Fig. 3b is an end view of the first stage exhaust nozzle wherein the first and second plurality of penetrating lobes alternate about the periphery of the first stage exhaust nozzle;
  • Fig. 3c is a cross-sectional view taken substantially along line 3c - 3c of Fig. 3b wherein the first and second plurality of penetrating lobes each terminate at a distinct exit plane;
  • Fig. 4a is an isolated perspective view of the second stage exhaust nozzle having a plurality of adjoined lobes forming an outlet end of the exhaust nozzle, wherein the adjoined lobes further include a first and second plurality of penetrating lobes which are axially staggered relative to each other, and wherein at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle;
  • Fig. 4b is an end view of the second stage exhaust nozzle wherein the first and second plurality of penetrating lobes are inset with respect to each other;
  • Fig. 4c is a side view taken along line 4c - 4c of Fig. 4b wherein the first and second plurality of penetrating lobes each terminate at a distinct exit plane;
  • Figs. 5a and 5b compare a baseline, non-staggered, inset nozzle to the staggered, inset, second stage exhaust nozzle according to the present invention for contrasting the flow areas defined by each nozzle;
  • Fig. 6a depicts an alternate embodiment of the multi-stage mixer/ejector wherein the first stage exhaust nozzle has an unequal number of perimeter and core penetrating lobes;
  • Fig. 6b depicts an alternate embodiment of the multi-stage mixer/ejector wherein the outlet end of the second stage exhaust nozzle defines a substantially elliptical geometric profile
  • Fig. 6c depicts an alternate embodiment of the multi-stage mixer/ejector wherein the outlet end of the second stage exhaust nozzle defines a substantially hour-glass shape
  • Fig. 6d depicts an alternate embodiment of the multi-stage mixer/ejector wherein the adjoined lobes of the first stage exhaust nozzle include a first, second and third plurality of penetrating lobes and wherein each plurality of penetrating lobes terminate at a distinct exit plane;
  • Fig. 6e depicts an alternate embodiment of the multi-stage mixer/ejector wherein an end face of the second stage exhaust nozzle is inclined to effect a gradual stagger of the penetrating lobes in an axial direction.
  • Fig. 1 shows a helicopter 10 having one or more gas turbine engines 12 for driving a main and tail rotor. 14 and 16, respectively.
  • a multi-stage mixer/ejector 20 according to the present invention is disposed in combination with the aft end of each gas turbine engine 12 and is operative to suppress the InfraRed (IR) signature radiated from the high-temperature exhaust of the respective engine 12.
  • IR InfraRed
  • to suppress means that the IR signature emanating from the gas turbine engine 12 is reduced below some predetermined threshold value which is indicative of the acquisition, tracking and/or targeting capability of a particular IR threat.
  • the multi-stage mixer/ejector 20 comprises tandemly-arranged first and second stage exhaust nozzles 24 and 28, respectively, each having a plurality of adjoined lobes 30, and a shroud means 32 for enveloping the adjoined lobes 30 of each exhaust nozzle.
  • Each of the first and second stage exhaust nozzles 24, 28 is adapted for receiving a primary flow PF of engine exhaust, for diffusing the primary flow PF though the respective adjoined lobes 30, and for entraining a secondary flow SF of low temperature gaseous fluid, e.g., ambient air, into the primary flow PF. More specifically, the effluent primary flow PF entrains the secondary flow SF through flow passages (discussed below) defined by the shroud means 32.
  • the multistage mixer/ejector 20 entrains two secondary flows SF, i.e., a first flow SF, directed toward the exit plane of the first stage exhaust nozzle 24, and a second flow SF 2 directed toward the exit plane of the second stage exhaust nozzle 28.
  • the fluid dynamics principle for entraining such secondary flows SF,, SF 2 is well-known in the art and is often referred to as a "venturi effect".
  • an inlet conduit 36 of the first stage exhaust nozzle 24 is disposed in combination with the exhaust casing 38 of the engine 12 for receiving the primary upstream flow PF of high temperature engine exhaust E HT .
  • the primary upstream flow PF of high temperature engine exhaust E m is diffused and admixed with the secondary flow SF, via the adjoined lobes 30.
  • the shroud means 32 includes a first stage shroud 42 which generally complements the shape of the first stage exhaust nozzle 24 and which defines a generally annular passage 44 for channeling the respective secondary flow SF,.
  • the adjoined lobes 30 of the first stage exhaust nozzle 24 incorporate several inventive features which serve to ameliorate the fluid dynamics/mixing of the primary and secondary flows PF. SF,.
  • An inlet conduit 46 of the second stage exhaust nozzle 28 is disposed proximal to the adjoined lobes 30 of the first stage nozzle 24 and is adapted to receive the primary midstream flow PF of partially-cooled exhaust E PC .
  • the inlet conduit 46 defines a substantially circular opening of sufficient size to envelope the first stage adjoined lobes 30 and, as such, functions in combination with the shroud means 32 to entrain the secondary flow SF,.
  • the resultant partially cooled exhaust E PC is diffused and admixed with the secondary flow SF 2 by the adjoined lobes 30 of the second stage nozzle 28.
  • the shroud means 32 includes a second stage shroud 48 which generally complements the shape of the second stage adjoined lobes 30 and which defines a generally tubular passage 52 for channeling the respective secondary flow SF 2 . Furthermore, in the described embodiment, the second stage shroud 48 envelopes the outlet end 42 0 of the first stage shroud 42 such that the shrouds 42, 48, in combination, provide a continuum of structure for occluding the underlying exhaust nozzles 24. 28.
  • the adjoined lobes 30 of the second stage exhaust nozzle 28 incorporate various inventive teachings which ameliorate the fluid dynamics/mixing of the primary and secondary flows PF, SF 2 and produce a primary downstream flow of cooled/suppressed engine exhaust E c . Furthermore, the second stage exhaust nozzle 28 and the adjoined lobes 30 thereof redirect the primary flow PF to prevent impingement thereof on other fuselage structure. Lastly, the second stage exhaust nozzle 28 and the configuration of the adjoined lobes 30 thereof prevent direct line-of-sight viewing into the gas turbine section of the engine 12.
  • each lobe 30 is defined as extending from peak-to-peak, i.e., between reference points P ⁇ , and is substantially radial with respect to a line 56 projecting from a longitudinal axis 24 A of the exhaust nozzle 24.
  • substantially radial means that the centerline 30 CL of each lobe 30 is within about 5 degrees of the angular orientation of such radial line 56. Moreover, each of the adjoined lobes 30 forms an external flow trough 30 EFT adapted for channeling the secondary flow SF of low temperature gaseous fluid, while adjacent lobes 30 form an internal flow trough 30 ⁇ adapted for channeling and diffusing the primary flow PF of high temperature exhaust.
  • the adjoined lobes 30 comprise a first and second plurality of penetrating lobes, 60 and 62, respectively, wherein the first and second plurality of penetrating ' lobes 60, 62 are axially staggered with respect to each other and wherein at least one of the plurality, 60 or 62, is adapted to extend into a "core region" of the exhaust nozzle 24.
  • the core region Before discussing the functional significance of such lobe configuration it is useful to spatially define the core region as well as to define certain structural and geometric features of the penetrating lobes 60, 62.
  • the core region of the first stage exhaust nozzle 24 may be spatially defined by a three-dimensional reference boundary which is, in turn, defined by the external flow troughs 30 EFT of the first plurality of penetrating lobes 60. More specifically, the locus of end points 60 E thereof (see Figs. 3b and 3c) define a two-dimensional reference circle or boundary R B2D . By extending the two-dimensional boundary R B2D axially in three- dimensional space, a three dimensional reference boundary R B3D (Fig. 3c) is defined which spatially defines the core region CR of the exhaust nozzle 24.
  • the core region CR of the exhaust nozzle 24 shall also mean the core region of the primary flow PF of engine exhaust.
  • the second plurality of penetrating lobes 62 extends into the core region CR so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of engine exhaust (see Fig. 3c).
  • the end points 62 E of the second plurality of penetrating lobes 62 are proximal to the longitudinal axis 24 A of the exhaust nozzle 24.
  • the first and second plurality of penetrating lobes 60, 62 are alternately disposed about the periphery of the exhaust nozzle 24 and are equiangularly spaced relative to the longitudinal axis 24 A .
  • each external flow trough 30 EFT of the penetrating lobes 60, 62 defines a smooth curve 66 along its axial length, which curve 66 is directed inwardly toward the longitudinal axis 24 A of the exhaust nozzle 24.
  • each of the second plurality of penetrating lobes 62 is tapered in radial height and width along its length.
  • the adjoined lobes 30 of the first stage exhaust nozzle 24 produce axial vortices V which admix the primary and secondary flows PF, SF to effect rapid convective heat transfer therebetween.
  • This mixing principle is generally known in the art and more fully described in Presz, Jr. Et al. U.S. Patent 4,835,961. Improvements thereto, which are the subject of the present invention, relate to modifying the adjoined lobes 30 to axially stagger the penetrating lobes 60, 62, and to cause at least one plurality of lobes 60 or 62 to penetrate into the core region of the primary flow PF.
  • the first plurality of penetrating lobes 60 channel the secondary flow SF into a perimeter region PR of the exhaust nozzle 24 (Figs. 3b and 3c) while the second plurality of penetrating lobes 62 channel the secondary flow SF deeply into the core region CR of the exhaust nozzle 24.
  • the secondary flow SF of low temperature gaseous fluid is channeled into substantially all of the primary flow PF to improve the efficacy of the heat transfer and the degree of IR suppression.
  • the second plurality or "core" penetrating lobes 62 project axially downstream of the first plurality or "perimeter” penetrating lobes 60 and curve inwardly toward the longitudinal axis 24 A .
  • the penetrating lobes 60, 62 are axially staggered so as to avoid convergence thereof at the same axial station.
  • Such staggering has the effect of reducing back-pressure by geometrically increasing the flow area at a particular axial station. That is, at the exit plane P 60 of the perimeter penetrating lobes 60, the entire core region CR is open for unrestricted flow of engine exhaust, while at exit plane P 62 of the core penetrating lobes 62, the perimeter region PR is essentially open for the flow of engine exhaust.
  • the ejector vane assembly of the prior art is configured such that each ejector vane directs flow into a core region of the engine exhaust and all the ejector vanes converge at the same axial station.
  • the backpressure produced by the clustered arrangement of ejector vanes results in significant engine power loss.
  • the penetrating lobes 60, 62, of the present invention direct flow into the core region while staggering the exit planes P 60 , P 62 to facilitate unrestricted flow of engine exhaust.
  • each lobe 30 is defined as extending from peak-to-peak, i.e., between reference points P ⁇ , and is substantially perpendicular with respect to a line 68 projecting from a midplane P M . of the exhaust nozzle 28.
  • substantially perpendicular means that the centerline 30 CL of each lobe 30 is within about 5 degrees of the angular orientation of such perpendicular line 76.
  • each of the adjoined lobes 30 forms an external flow trough 30 EFT adapted for channeling the secondary flow SF of low temperature gaseous fluid (best seen in Fig. 4a), while two adjacent lobes 30 form an internal flow trough 30 ⁇ adapted for channeling and diffusing the primary flow PF of partially-cooled exhaust.
  • the adjoined lobes 30 comprise a first and second plurality of penetrating lobes.
  • the core region of the second stage exhaust nozzle 28 may be spatially defined by a three-dimensional reference boundary which is, in turn, defined by the external flow troughs 30 EFT of the first plurality of penetrating lobes 70. More specifically, the locus of end points 70 E thereof (see Fig.
  • a first two-dimensional reference curve R which, in combination with a second two dimensional reference curve R 2 reflectively disposed about the midplane P M , defines a two-dimensional reference boundary R B2D .
  • a three-dimensional reference boundary R B3D is defined (see Fig. 4c) which spatially defines the core region CR of the exhaust nozzle 28.
  • the core region CR of the exhaust nozzle 28 shall also mean the core region of the primary flow of engine exhaust.
  • the second plurality of penetrating lobes 72 extend into the core region CR so as to direct the secondary flow SF of low temperature gaseous fluid into the primary flow PF of engine exhaust.
  • the second plurality of penetrating lobes 72 fully penetrate or traverse the core region CR so as to divide the primary exhaust flow PF into a plurality of discrete flow segments.
  • first and second plurality of penetrating lobes 70, 72 are axially staggered with respect to each other (see Fig. 3c) so as to define at least two exit planes P 70 , P 72 for diffusing the secondary flow SF.
  • the second plurality of penetrating lobes 72 are "inset" with respect to the first plurality of penetrating lobes 70 at an axial location corresponding to the exit plane P 70 and, more preferably, are inset at an axial location 74 inboard of the exit plane P 70 .
  • the penetrating lobes 70, 72 define a substantially 90 degree bend, which in combination with the inset configuration thereof, define a plurality of turning vanes 80 (see Fig. 4a) for redirecting the primary flow PF.
  • the adjoined lobes 30 of the second stage exhaust nozzle 28 produce axial vortices V (Figs.
  • the inset configuration of the adjoined lobes 30 causes each plurality of penetrating lobes 70, 72 to cross the midplane P M , thereby channeling the secondary flow SF into the core region CR of the exhaust nozzle 28.
  • the secondary flow SF of low temperature gaseous fluid is channeled into substantially all of the primary flow PF to improve the efficacy of the heat transfer and the degree of IR suppression.
  • the inset configuration of the penetrating lobes 70, 72 facilitates the formation of turning vanes 80 (Fig. 4a) for directing/redirecting the primary exhaust flow PF. That is, the upper and lower nozzle walls collapse inwardly to form the external flow troughs 30 EFT while, concomitantly, forming an integral turning duct or vane 80. While the turning vanes 80 serve to direct flow outwardly of the fuselage 22, an equally important function relates to the occlusion of internal components and/or upstream flow from direct-line-of-sight view.
  • the inset configuration of the penetrating lobes 70, 72 in combination with the 90 degree bend of the exhaust nozzle prevents direct line-of-sight viewing into the interior of the second stage exhaust nozzle 28.
  • "hot spots" disposed internally of the exhaust nozzle 28, such as from the gas turbine section of the engine cannot radiate outwardly so as to become viewable by a heat seeking threat.
  • the second plurality of penetrating lobes 72 project axially downstream of the first plurality of penetrating lobes 70 for providing both engine performance and IR suppression benefits.
  • such staggering has the effect of reducing back-pressure by (i) producing two in-line ejector pumps in series, and (ii) geometrically increasing the flow area at a particular axial station.
  • the first plurality of penetrating lobes 70 are adapted to entrain the secondary flow SF at exit plane P 70 and the second plurality of penetrating lobes 72 are adapted to entrain the secondary flow SF at exit plane P 72 .
  • the staggered arrangement produces an additive or compounding effect with respect to pumping efficacy. Accordingly, more cooling air is entrained for suppressing the IR signature of the primary exhaust flow PF, and engine back-pressure is reduced by gains in fluid dynamic pumping.
  • Figs. 5a and 5b wherein the flow area of the second stage exhaust nozzle 28 is compared to a Non-Staggered Inset (NSI) lobed nozzle 86.
  • NSI lobed nozzle 86 is not known in the art but is used herein as a baseline for comparison.
  • the exit plane of the NSI lobed nozzle 86 is overlaid in combination with a section view of the second stage exhaust nozzle 28 at exit plane P 70 .
  • the profile of the NSI nozzle 86 is shown in dashed lines in areas where the NSI nozzle 86 structurally differs from the second stage exhaust nozzle 28 and in solid lines in areas where the nozzles are essentially identical.
  • areas A 70 represent additional flow area for engine exhaust at the exit plane P 70 of the second stage exhaust nozzle 28.
  • the NSI lobed nozzle 86 is again overlaid in combination with a section view of the second stage exhaust nozzle at exit plane P 72 .
  • the profile of the NSI nozzle is shown in dashed lines in areas where the nozzle 86 structurally differs from the second stage nozzle 28 and a dotted line 88 establishes a minimum upper flow boundary for the second stage nozzle 28.
  • areas A 72 represent additional flow area for engine exhaust at the exit plane P 72 of the second stage exhaust nozzle 28. Accordingly, the total flow area at each of the exit planes P 70 , P 72 is larger when compared to the baseline NSI lobed nozzle 86, and, as such, the second stage nozzle 28 is less restrictive with respect to the flow of engine exhaust.
  • the multi-stage mixer/ejector 20 employs various mechanisms, some known in the art and others which are the subject of this invention, to effect significant IR signature reduction while maintaining and/or improving engine performance.
  • each stage of the mixer/ejector 20 introduces cooling air SF,, SF 2 into the primary exhaust flow PF for reducing engine exhaust temperature. Fluid mixing/pumping is achieved by a venturi effect which relies on the high velocity primary exhaust flow PF to entrain the secondary flows SF,, SF 2 of cooling air. As such, the need for additional apparatus to force or pump fluid is eliminated.
  • the shroud means 32 substantially envelops the first and second stage nozzles 24, 28 and, accordingly, serves to occlude the exterior surfaces thereof. Inasmuch as the temperature of such surfaces may be elevated, the shroud means 32 prevents direct viewing of the nozzles 24, 28 and, accordingly, diminishes or eliminates the IR signature radiated from such surfaces.
  • each nozzle 24 or 28 produces two ejector pumps in series, i.e.. a first ejector pump at the exit plane P 60 or P 70 of the first plurality of penetrating lobes 60 or 70, and a second ejector pump at the exit plane P 62 , P 72 of the second plurality of penetrating lobes 62. or 72.
  • the fluid dynamic pumping is augmented to (i) entrain more cooling fluid for suppressing the IR signature of the exhaust plume and (ii) reduce back-pressure for improving engine performance.
  • the penetrating lobes 60, 62 or 70, 72 it is possible to situate individual lobes in the core region of the primary flow without creating a restrictive "choke point" at any one axial station or plane. As such, further IR suppression is achievable without degrading performance.
  • each nozzle, 24 or 28, in combination with its respective shroud, 42 or 48 maintains engine performance, collectively, the multi-stage mixer/ejector 20 improves engine performance by about 1 - 6%.
  • each exhaust nozzle, 24 or 28, in combination with its respective shroud, 42 or 48 is capable of effecting a 30 - 40% diffusion of IR energy within about two (2) diameters downstream of the nozzle, wherein the diameter is the measured relative to the diameter of the engine exhaust cowling 38.
  • the multi-stage mixer/ejector 20 effects an energy reduction on the order of about 60 - 80% from the high temperature exhaust E HT to the cooled exhaust E c .
  • the multi-stage mixer/ejector 20 may be formed from conventional low-cost fabrication techniques such as casting or press molding.
  • a highly accurate mold may be fabricated by forming a stereolithography model of the exhaust nozzle, and subsequently, casting a wear and temperature resistance material over the stereolithography model to form a filled casting. The polymer used in the stereolithography process is then removed in a high temperature furnace to form an accurate casting of the exhaust nozzle.
  • Yet another example includes the use of a hydro-forming process wherein a sheet-metal workpiece is fabricated which approximates the size and shape of the nozzle.
  • first stage exhaust nozzle 24 of the mixer/ejector 20 includes an equal number of alternating perimeter and core penetrating lobes 60, 62, it will be understood that the number of lobes need not be equal nor be alternating with respect to each other.
  • Such configuration is shown in Fig. 6a wherein a core penetrating lobe 62' is disposed between pairs of perimeter penetrating lobes 60'.
  • the penetrating lobes 60, 62 of the first stage exhaust nozzle 24 are shown to be substantially radial, it should be appreciated that the penetrating lobes could be swirled to effect axial rotation of the exhaust flow.
  • the outlet end of the second stage exhaust nozzle 28 defines a substantially rectangular geometric profile, it will be appreciated that other shapes will accommodate the inset configuration of the penetrating lobes 70, 72.
  • the outlet end may define an elliptical geometric profile as shown in Fig. 6b, or an hour-glass shape as depicted in Fig. 6c.
  • the adjoined lobes may include additional penetrating lobes to define a third, fourth or higher plurality of penetrating lobes.
  • the adjoined lobes 30 include a first, second and third plurality of penetrating lobes 60', 62', and 64', respectively, and wherein each plurality of penetrating lobes 60', 62', 64' terminate at a distinct exit plane P'.
  • each of the penetrating lobes 70, 72 of the second stage nozzle 28 terminate along a substantially vertical plane, it will be appreciated that the end face 70 EF may be stepped or inclined so as to effect a gradual stagger of the penetrating lobes in an axial direction.

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Abstract

A multi-stage mixer-ejector (20) having at least one exhaust nozzle (24 or 28) which includes inlet conduit adapted for receiving a primary flow PF of engine exhaust and a plurality of adjoined lobes (30) integrally formed in combination with the inlet conduit. The adjoined lobes (30) of the exhaust nozzle (24 or 28) are characterized by a first and second plurality of penetrating lobes (60, 62 or 70, 72) which are axially staggered with respect to each other and which are adapted for admixing low-temperature gaseous fluid with the high-temperature exhaust. In the preferred embodiment, at least one of the plurality of penetrating lobes (60 or 62, 70 or 72) extends into a core region (CR) of the exhaust nozzle (24 or 28) to effect thorough mixing of the low temperature gaseous fluid with the engine exhaust.

Description

Multi-Stage Mixer/Ejector for Suppressing Infrared Radiation
Related Applications
This invention is related to co-pending, commonly-owned. U.S. Patent application entitled "Exhaust Nozzle for Suppressing Infrared Radiation" (Docket No. S-5299). Technical Field
This invention is directed to engine mixer/ejectors, and more particularly, to an multi-stage mixer/ejector operative to suppress the infrared signature radiated by the exhaust plume of an engine and/or the various hot metal components thereof.
Background Of The Invention
The exhaust plume of gas turbine engines, e.g., military aircraft engines, is a source of high infrared energy which may be used for targeting/tracking purposes by heat seeking missiles and/or various forms of infrared imaging systems, e.g., Night Vision Goggles (NVGs). With respect to the former, heat seeking missiles obtain directional cues from the infrared energy, which directional cues are more precise depending upon the intensity, e.g., temperature, and total energy emitted by the exhaust plume. Regarding the latter, infrared imaging systems amplify the infrared energy by a factor of about 10.000 and may be used by hostile forces for early detection and/or targeting of surface-to-air/air-to-air missiles. Accordingly, it is highly desirable to reduce the infrared emissions (also referred to as the IR signature) of such engines to a practical minimum to avoid detection, acquisition and/or tracking by enemy threats/forces.
Various infrared suppression systems have been designed and fielded which effect mixing of low temperature ambient air with the high temperature engine exhaust to reduce the IR signature radiated therefrom. Generally, it is the principle objectives of such systems to: (a) reduce the infrared energy below a threshold level (e.g., a level capable of being sensed by the perceived threat), (b) maintain engine performance, and. (c) minimize the weight penalties associated therewith. Secondary objectives may include: (i) minimizing system or configuration complexity to reduce fabrication costs, (ii) minimizing the external aerodynamic drag produced by such IR suppressors, and/or (iii) suppressing the acoustic emissions emanating therefrom which may also be a source of detection.
Hurley U.S. Patent 4,018,046 discloses an InfraRed (IR) suppressor for reducing the infrared radiation emitted from the exhaust plume and/or hot metal parts of a gas turbine engine. The IR suppressor includes an ejector vane assembly which is adapted for receiving a primary flow of engine exhaust and which is operative to entrain a first flow of cooling air into the primary exhaust flow. The primary flow of gases diffused from and entrained by the ejector vane assembly are fed into an arcuate duct which, due to its spatial position relative to the ejector vane assembly, produces an annular space for entraining a second flow of cooling air. The first and second flows are admixed with the primary exhaust flow to effect heat transfer therebetween and. consequently, to suppress the IR signature emitted from the exhaust plume. Additionally, the curved shape of the arcuate duct and/or the use of turning vanes disposed internally thereof, serve to prevent direct line-of-sight viewing into the IR suppressor. That is. the shape prevents viewing of radiant energy emitted by hot internal components such as from the ejector vane assembly or from the turbine section of the engine.
The ejector vane assembly described therein includes a plurality of V-shaped ejector vanes which entrain cooling air at a plurality of angularly spaced positions while additionally serving to introduce air toward the center of the engine exhaust. More specifically, each of the ejector vanes forms a V-shaped channel which is open to ambient air at one end thereof and is oriented to direct flow radially toward the core of the primary exhaust flow. The ejector vane assembly, furthermore, clusters the ejector vanes as close as practicable to the core of the primary exhaust flow and, furthermore, includes a means for adjusting the flow area through the ejector vanes to ameliorate engine performance. That is, the adjustment means effects collapse of each ejector vane so as to increase the flow area and reduce the back-pressure on the engine.
While the ejector vane assembly improves mixing, i.e.. reduces the IR signature, by directing cooling air into a core region of the engine exhaust, it will be appreciated that the ejector vane assembly requires a large number of individual components. As such, the multiplicity of components, each being a potential source of repair and maintenance, reduces the overall reliability of the IR suppressor system. Furthermore, while the adjustment means attempts to reduce flow restriction, the anticipated power loss produced by the ejector vane assembly is on the order of between 3% to 6%. In view of the fact that even small variations in efficiency, i.e., on the order of '/2% to 1%, have significant impact on engine performance, such power loss may be viewed as intolerable for certain aircraft and/or aircraft missions wherein maximum gross weight, flight speed, and range are critical design parameters. Moreover, while the IR suppressor employs a simple ejector principle to suppress infrared radiation, it will be appreciated that the manufacture of such IR suppressor, particularly the ejector vane assembly, is highly complex and requires multiple forming, machining, welding, and assembly operations. Presz et al. U.S. Patents 4,835,961 and 4,830,315 describe nozzle configurations for mixing/pumping fluid. More specifically, the Presz '961 and '315 patents describe single and multi-stage mixer/ejector nozzles, respectively, each having a plurality of adjoined lobes formed at an outlet end thereof. The adjoined lobes define a primary flow trough for channeling a primary flow of high velocity /energy fluid, such as the exhaust of a gas turbine engine, and a secondary flow trough for channeling a secondary flow of low velocity/energy fluid such as ambient air. The primary and secondary flow troughs are alternately disposed about the periphery of the nozzle such that thin sheets of high energy fluid flow from the trough outlets, transfer kinetic energy to the low energy fluid, and entrain the secondary flow into the primary flow. Aside from simple viscous or shear mixing, the adjoined lobes produce axial vortices which rapidly admix the primary and secondary flows. As such, the adjoined lobes described in the Presz '961 and '315 patents are known to have utility on aircraft engines to both increase thrust and for suppressing the thermal energy radiated from the engine.
While the adjoined lobes serve to rapidly admix the primary and secondary flows to reduce the IR signature, the nozzle configurations disclosed therein fail to fully mix the flows, particularly in the core region of the primary exhaust flow. That is, in all of the embodiments described therein, the lobes entrain the secondary cooling flow into a perimeter region of the flow such that a central core or band of high temperature exhaust remains as the flow exits the nozzle. While the core of high temperature flow will eventually admix downstream, it will be appreciated that the degree of IR suppression is compromised until such energy is diffused. A need, therefore exits, for providing a multi-stage mixer/ejector which maintains or improves engine performance, rapidly and thoroughly diffuses the IR energy emitted/radiated from a gas turbine engine, and facilitates fabrication via conventional, low-cost, manufacturing methods. Summary of the Invention
It is an object of the present invention to provide a multi-stage mixer/ejector for suppressing the InfraRed (IR) radiation emitted by the exhaust plume and/or the hot metal components of an engine while maintaining or improving engine performance.
It is another object of the present invention to provide such a multi-stage mixer/ejector which, at each stage of the mixer/ejector, is adapted for entraining a secondary flow of low temperature gaseous fluid into a core region of the primary engine exhaust.
It is yet another object of the present invention to provide such a multi-stage mixer/ejector which is readily fabricated by conventional, low-cost, manufacturing methods.
It is yet a further object of the present invention to provide such a multi-stage mixer/ejector wherein the geometry thereof prevents direct line-of-sight viewing into the mixer/ejector.
These and other objects of the present invention are achieved by a multi-stage mixer/ejector having at least one exhaust nozzle which includes inlet conduit adapted for receiving a primary flow PF of engine exhaust and a plurality of adjoined lobes integrally formed in combination with the inlet conduit. The adjoined lobes of the exhaust nozzle are characterized by a first and second plurality of penetrating lobes which are axially staggered with respect to each other and which are adapted for admixing low-temperature gaseous fluid with the high-temperature exhaust. In the preferred embodiment, at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle to effect thorough mixing of the low temperature gaseous fluid with the engine exhaust. Brief Description Of The Drawings
A more complete understanding of the present invention and the attendant features and advantages thereof may be had by reference to the following detailed description of the invention when considered in conjunction with the following drawings wherein:
Fig. 1 is a profile view of a helicopter illustrating an exemplary installation of a multi-stage mixer/ejector according to the present invention;
Fig. 2 is a partially broken-away perspective view of a multi-stage mixer/ejector disposed in combination with the aft end of a gas turbine engine, which multi-stage mixer/ejector includes tandemly-arranged first and second stage exhaust nozzles;
Fig. 3a is an isolated perspective view of the first stage exhaust nozzle having a plurality of adjoined lobes forming an outlet end of the exhaust nozzle, wherein the adjoined lobes further include a first and second plurality of penetrating lobes which are axially staggered relative to each other and wherein at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle;
Fig. 3b is an end view of the first stage exhaust nozzle wherein the first and second plurality of penetrating lobes alternate about the periphery of the first stage exhaust nozzle; Fig. 3c is a cross-sectional view taken substantially along line 3c - 3c of Fig. 3b wherein the first and second plurality of penetrating lobes each terminate at a distinct exit plane;
Fig. 4a is an isolated perspective view of the second stage exhaust nozzle having a plurality of adjoined lobes forming an outlet end of the exhaust nozzle, wherein the adjoined lobes further include a first and second plurality of penetrating lobes which are axially staggered relative to each other, and wherein at least one of the plurality of penetrating lobes extends into a core region of the exhaust nozzle;
Fig. 4b is an end view of the second stage exhaust nozzle wherein the first and second plurality of penetrating lobes are inset with respect to each other; Fig. 4c is a side view taken along line 4c - 4c of Fig. 4b wherein the first and second plurality of penetrating lobes each terminate at a distinct exit plane; Figs. 5a and 5b compare a baseline, non-staggered, inset nozzle to the staggered, inset, second stage exhaust nozzle according to the present invention for contrasting the flow areas defined by each nozzle;
Fig. 6a depicts an alternate embodiment of the multi-stage mixer/ejector wherein the first stage exhaust nozzle has an unequal number of perimeter and core penetrating lobes;
Fig. 6b depicts an alternate embodiment of the multi-stage mixer/ejector wherein the outlet end of the second stage exhaust nozzle defines a substantially elliptical geometric profile: Fig. 6c depicts an alternate embodiment of the multi-stage mixer/ejector wherein the outlet end of the second stage exhaust nozzle defines a substantially hour-glass shape;
Fig. 6d depicts an alternate embodiment of the multi-stage mixer/ejector wherein the adjoined lobes of the first stage exhaust nozzle include a first, second and third plurality of penetrating lobes and wherein each plurality of penetrating lobes terminate at a distinct exit plane;
Fig. 6e depicts an alternate embodiment of the multi-stage mixer/ejector wherein an end face of the second stage exhaust nozzle is inclined to effect a gradual stagger of the penetrating lobes in an axial direction.
Best Mode For Carrying Out The Invention The exemplary embodiments of the present invention will be described in the context of a helicopter gas turbine engine, though, it will be appreciated that the teachings described herein are applicable to any turbo-shaft engine wherein the maximization of shaft horsepower is a principle design objective. This application is to be distinguished from other engine designs, such as turbo-jet or turbo-fan engines, wherein the maximization of thrust, rather than shaft horsepower, is a key design objective.. Furthermore, while the present invention describes such a multi-stage mixer/ejector wherein one such exhaust nozzle employs a bend therein for preventing direct line-of-sight viewing into the gas turbine section of the engine, the teachings are also applicable to in-line ejector configurations. Referring now to the drawings wherein like reference characters identify corresponding or similar elements throughout the several views, Fig. 1 shows a helicopter 10 having one or more gas turbine engines 12 for driving a main and tail rotor. 14 and 16, respectively. A multi-stage mixer/ejector 20 according to the present invention is disposed in combination with the aft end of each gas turbine engine 12 and is operative to suppress the InfraRed (IR) signature radiated from the high-temperature exhaust of the respective engine 12. In the context used herein, "to suppress" means that the IR signature emanating from the gas turbine engine 12 is reduced below some predetermined threshold value which is indicative of the acquisition, tracking and/or targeting capability of a particular IR threat.
In Fig. 2, a perspective view of the multi-stage mixer/ejector 20 is shown in combination with the engine 12 and in position relative to the helicopter fuselage 22. Before discussing each element and/or feature of the multi-stage mixer/ejector 20 in detail, a brief overview of the major components and the operation of each will be provided. The multi-stage mixer/ejector 20 comprises tandemly-arranged first and second stage exhaust nozzles 24 and 28, respectively, each having a plurality of adjoined lobes 30, and a shroud means 32 for enveloping the adjoined lobes 30 of each exhaust nozzle. Each of the first and second stage exhaust nozzles 24, 28 is adapted for receiving a primary flow PF of engine exhaust, for diffusing the primary flow PF though the respective adjoined lobes 30, and for entraining a secondary flow SF of low temperature gaseous fluid, e.g., ambient air, into the primary flow PF. More specifically, the effluent primary flow PF entrains the secondary flow SF through flow passages (discussed below) defined by the shroud means 32. Accordingly, in the described embodiment, the multistage mixer/ejector 20 entrains two secondary flows SF, i.e., a first flow SF, directed toward the exit plane of the first stage exhaust nozzle 24, and a second flow SF2 directed toward the exit plane of the second stage exhaust nozzle 28. The fluid dynamics principle for entraining such secondary flows SF,, SF2 is well-known in the art and is often referred to as a "venturi effect".
In the described embodiment, an inlet conduit 36 of the first stage exhaust nozzle 24 is disposed in combination with the exhaust casing 38 of the engine 12 for receiving the primary upstream flow PF of high temperature engine exhaust EHT. The primary upstream flow PF of high temperature engine exhaust Em is diffused and admixed with the secondary flow SF, via the adjoined lobes 30. The shroud means 32 includes a first stage shroud 42 which generally complements the shape of the first stage exhaust nozzle 24 and which defines a generally annular passage 44 for channeling the respective secondary flow SF,. The adjoined lobes 30 of the first stage exhaust nozzle 24 incorporate several inventive features which serve to ameliorate the fluid dynamics/mixing of the primary and secondary flows PF. SF,. While these and other features of the first stage exhaust nozzle 24 will be discussed in greater detail below, suffice it to say at this point in the description, that the primary and secondary flows PF, SF, admix to produce a primary midstream flow PF of partially-cooled exhaust EPC.
An inlet conduit 46 of the second stage exhaust nozzle 28 is disposed proximal to the adjoined lobes 30 of the first stage nozzle 24 and is adapted to receive the primary midstream flow PF of partially-cooled exhaust EPC. In the described embodiment, the inlet conduit 46 defines a substantially circular opening of sufficient size to envelope the first stage adjoined lobes 30 and, as such, functions in combination with the shroud means 32 to entrain the secondary flow SF,. The resultant partially cooled exhaust EPC is diffused and admixed with the secondary flow SF2 by the adjoined lobes 30 of the second stage nozzle 28. The shroud means 32 includes a second stage shroud 48 which generally complements the shape of the second stage adjoined lobes 30 and which defines a generally tubular passage 52 for channeling the respective secondary flow SF2. Furthermore, in the described embodiment, the second stage shroud 48 envelopes the outlet end 420 of the first stage shroud 42 such that the shrouds 42, 48, in combination, provide a continuum of structure for occluding the underlying exhaust nozzles 24. 28.
The adjoined lobes 30 of the second stage exhaust nozzle 28 incorporate various inventive teachings which ameliorate the fluid dynamics/mixing of the primary and secondary flows PF, SF2 and produce a primary downstream flow of cooled/suppressed engine exhaust Ec. Furthermore, the second stage exhaust nozzle 28 and the adjoined lobes 30 thereof redirect the primary flow PF to prevent impingement thereof on other fuselage structure. Lastly, the second stage exhaust nozzle 28 and the configuration of the adjoined lobes 30 thereof prevent direct line-of-sight viewing into the gas turbine section of the engine 12. These and other features of the second stage exhaust nozzle 28 will be discussed in subsequent paragraphs. First Stage Exhaust Nozzle
In Figs. 3a - 3c, various views of the first stage exhaust nozzle 24 are depicted to illustrate the inventive features of the adjoined lobes 30. As shown, the adjoined lobes 30 are integrally formed in combination with the inlet conduit 36 and define an outlet end of the first stage exhaust nozzle 24. In the two-dimensional plane of Fig. 3b, each lobe 30 is defined as extending from peak-to-peak, i.e., between reference points Pκ, and is substantially radial with respect to a line 56 projecting from a longitudinal axis 24A of the exhaust nozzle 24. In the context used herein, "substantially radial" means that the centerline 30CL of each lobe 30 is within about 5 degrees of the angular orientation of such radial line 56. Moreover, each of the adjoined lobes 30 forms an external flow trough 30EFT adapted for channeling the secondary flow SF of low temperature gaseous fluid, while adjacent lobes 30 form an internal flow trough 30στ adapted for channeling and diffusing the primary flow PF of high temperature exhaust.
In the exemplary embodiment, the adjoined lobes 30 comprise a first and second plurality of penetrating lobes, 60 and 62, respectively, wherein the first and second plurality of penetrating' lobes 60, 62 are axially staggered with respect to each other and wherein at least one of the plurality, 60 or 62, is adapted to extend into a "core region" of the exhaust nozzle 24. Before discussing the functional significance of such lobe configuration it is useful to spatially define the core region as well as to define certain structural and geometric features of the penetrating lobes 60, 62.
The core region of the first stage exhaust nozzle 24 may be spatially defined by a three-dimensional reference boundary which is, in turn, defined by the external flow troughs 30EFT of the first plurality of penetrating lobes 60. More specifically, the locus of end points 60E thereof (see Figs. 3b and 3c) define a two-dimensional reference circle or boundary RB2D. By extending the two-dimensional boundary RB2D axially in three- dimensional space, a three dimensional reference boundary RB3D (Fig. 3c) is defined which spatially defines the core region CR of the exhaust nozzle 24. Hereinafter, the core region CR of the exhaust nozzle 24 shall also mean the core region of the primary flow PF of engine exhaust. In the described embodiment, the second plurality of penetrating lobes 62 extends into the core region CR so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of engine exhaust (see Fig. 3c). In the preferred embodiment, the end points 62E of the second plurality of penetrating lobes 62 are proximal to the longitudinal axis 24A of the exhaust nozzle 24. Furthermore, the first and second plurality of penetrating lobes 60, 62 are alternately disposed about the periphery of the exhaust nozzle 24 and are equiangularly spaced relative to the longitudinal axis 24A.
Additionally, the first and second plurality of penetrating lobes 60, 62 are axially staggered with respect to each other (see Fig. 3c) so as to define at least two exit planes P60, P62 for diffusing the secondary flow SF. Furthermore, each external flow trough 30EFT of the penetrating lobes 60, 62. defines a smooth curve 66 along its axial length, which curve 66 is directed inwardly toward the longitudinal axis 24A of the exhaust nozzle 24. Preferably, the slope of the curve 66 is less than about 30 degrees relative to the longitudinal axis 24A to avoid flow separation, i.e., separation of the secondary flow SF from the surface of the respective external flow trough 30EFT Finally, each of the second plurality of penetrating lobes 62 is tapered in radial height and width along its length.
The adjoined lobes 30 of the first stage exhaust nozzle 24 produce axial vortices V which admix the primary and secondary flows PF, SF to effect rapid convective heat transfer therebetween. This mixing principle is generally known in the art and more fully described in Presz, Jr. Et al. U.S. Patent 4,835,961. Improvements thereto, which are the subject of the present invention, relate to modifying the adjoined lobes 30 to axially stagger the penetrating lobes 60, 62, and to cause at least one plurality of lobes 60 or 62 to penetrate into the core region of the primary flow PF. More specifically, the first plurality of penetrating lobes 60 channel the secondary flow SF into a perimeter region PR of the exhaust nozzle 24 (Figs. 3b and 3c) while the second plurality of penetrating lobes 62 channel the secondary flow SF deeply into the core region CR of the exhaust nozzle 24. As such, the secondary flow SF of low temperature gaseous fluid is channeled into substantially all of the primary flow PF to improve the efficacy of the heat transfer and the degree of IR suppression. Furthermore, the second plurality or "core" penetrating lobes 62 project axially downstream of the first plurality or "perimeter" penetrating lobes 60 and curve inwardly toward the longitudinal axis 24A. As such, the penetrating lobes 60, 62 are axially staggered so as to avoid convergence thereof at the same axial station. Such staggering has the effect of reducing back-pressure by geometrically increasing the flow area at a particular axial station. That is, at the exit plane P60 of the perimeter penetrating lobes 60, the entire core region CR is open for unrestricted flow of engine exhaust, while at exit plane P62 of the core penetrating lobes 62, the perimeter region PR is essentially open for the flow of engine exhaust.
This may be more fully appreciated by comparing the ejector vane assembly discussed in the Background of the Invention with the penetrating lobes 60, 62 of the present invention. With respect thereto, the ejector vane assembly of the prior art is configured such that each ejector vane directs flow into a core region of the engine exhaust and all the ejector vanes converge at the same axial station. As such, the backpressure produced by the clustered arrangement of ejector vanes results in significant engine power loss. In contrast, the penetrating lobes 60, 62, of the present invention direct flow into the core region while staggering the exit planes P60, P62 to facilitate unrestricted flow of engine exhaust.
Second Stage Exhaust Nozzle
In Figs. 4a - 4c, various views of the second stage exhaust nozzle 28 are depicted to illustrate the inventive features of the adjoined lobes 30. As shown, the adjoined lobes 30 are integrally formed in combination with the inlet conduit 46 and define an outlet end of the second stage exhaust nozzle 28. In the two-dimensional plane of Fig. 4b, each lobe 30 is defined as extending from peak-to-peak, i.e., between reference points Pκ, and is substantially perpendicular with respect to a line 68 projecting from a midplane PM. of the exhaust nozzle 28. In the context used herein "substantially perpendicular" means that the centerline 30CL of each lobe 30 is within about 5 degrees of the angular orientation of such perpendicular line 76. Moreover, each of the adjoined lobes 30 forms an external flow trough 30EFT adapted for channeling the secondary flow SF of low temperature gaseous fluid (best seen in Fig. 4a), while two adjacent lobes 30 form an internal flow trough 30^ adapted for channeling and diffusing the primary flow PF of partially-cooled exhaust. In the exemplary embodiment, the adjoined lobes 30 comprise a first and second plurality of penetrating lobes. 70 and 72, respectively, wherein the first and second plurality of penetrating lobes 70, 72 are axially staggered with respect to each other, and wherein at least one of the plurality, 70 or 72, are adapted to extend into a "core region" of the exhaust nozzle 28. In the described embodiment, the core region of the second stage exhaust nozzle 28 may be spatially defined by a three-dimensional reference boundary which is, in turn, defined by the external flow troughs 30EFT of the first plurality of penetrating lobes 70. More specifically, the locus of end points 70E thereof (see Fig. 4b) define a first two-dimensional reference curve R, which, in combination with a second two dimensional reference curve R2 reflectively disposed about the midplane PM, defines a two-dimensional reference boundary RB2D. By extending the two-dimensional boundary RB2D axially in three-dimensional space, a three-dimensional reference boundary RB3D is defined (see Fig. 4c) which spatially defines the core region CR of the exhaust nozzle 28. Hereinafter the core region CR of the exhaust nozzle 28 shall also mean the core region of the primary flow of engine exhaust.
Before discussing the functional significance of the lobe configuration and/or the lobe configuration as it relates to the core region of the engine exhaust, it is useful to define certain structural and geometric features of the penetrating lobes 70, 72. More specifically, in the described embodiment, the second plurality of penetrating lobes 72 extend into the core region CR so as to direct the secondary flow SF of low temperature gaseous fluid into the primary flow PF of engine exhaust. In the preferred embodiment, the second plurality of penetrating lobes 72 fully penetrate or traverse the core region CR so as to divide the primary exhaust flow PF into a plurality of discrete flow segments. Furthermore, the first and second plurality of penetrating lobes 70, 72 are axially staggered with respect to each other (see Fig. 3c) so as to define at least two exit planes P70, P72 for diffusing the secondary flow SF. Moreover, in the preferred embodiment, the second plurality of penetrating lobes 72 are "inset" with respect to the first plurality of penetrating lobes 70 at an axial location corresponding to the exit plane P70 and, more preferably, are inset at an axial location 74 inboard of the exit plane P70. In the context used herein "inset" means that each external flow trough 30EFT of the second plurality of penetrating lobes 72 is aligned with an internal flow trough 30^ of the first plurality of penetrating lobes 70, and crosses the midplane PM of the exhaust nozzle 28. Also, in the preferred embodiment, the penetrating lobes 70, 72 define a substantially 90 degree bend, which in combination with the inset configuration thereof, define a plurality of turning vanes 80 (see Fig. 4a) for redirecting the primary flow PF. The adjoined lobes 30 of the second stage exhaust nozzle 28 produce axial vortices V (Figs. 4a and 4c) which admix the primary and secondary flows PF, SF to effect rapid convective heat transfer therebetween. In addition to this known mixing principle, the inset configuration of the adjoined lobes 30 causes each plurality of penetrating lobes 70, 72 to cross the midplane PM, thereby channeling the secondary flow SF into the core region CR of the exhaust nozzle 28. As such, the secondary flow SF of low temperature gaseous fluid is channeled into substantially all of the primary flow PF to improve the efficacy of the heat transfer and the degree of IR suppression.
In addition, the inset configuration of the penetrating lobes 70, 72 facilitates the formation of turning vanes 80 (Fig. 4a) for directing/redirecting the primary exhaust flow PF. That is, the upper and lower nozzle walls collapse inwardly to form the external flow troughs 30EFT while, concomitantly, forming an integral turning duct or vane 80. While the turning vanes 80 serve to direct flow outwardly of the fuselage 22, an equally important function relates to the occlusion of internal components and/or upstream flow from direct-line-of-sight view. That is, the inset configuration of the penetrating lobes 70, 72 in combination with the 90 degree bend of the exhaust nozzle prevents direct line-of-sight viewing into the interior of the second stage exhaust nozzle 28. As such, "hot spots" disposed internally of the exhaust nozzle 28, such as from the gas turbine section of the engine, cannot radiate outwardly so as to become viewable by a heat seeking threat. Furthermore, the second plurality of penetrating lobes 72 project axially downstream of the first plurality of penetrating lobes 70 for providing both engine performance and IR suppression benefits. More specifically, such staggering has the effect of reducing back-pressure by (i) producing two in-line ejector pumps in series, and (ii) geometrically increasing the flow area at a particular axial station. With regard to the former, the first plurality of penetrating lobes 70 are adapted to entrain the secondary flow SF at exit plane P70 and the second plurality of penetrating lobes 72 are adapted to entrain the secondary flow SF at exit plane P72. As such, the staggered arrangement produces an additive or compounding effect with respect to pumping efficacy. Accordingly, more cooling air is entrained for suppressing the IR signature of the primary exhaust flow PF, and engine back-pressure is reduced by gains in fluid dynamic pumping. With respect to the latter, the geometrical effect on engine performance may be more fully understood by referring to Figs. 5a and 5b wherein the flow area of the second stage exhaust nozzle 28 is compared to a Non-Staggered Inset (NSI) lobed nozzle 86. It should be appreciated that such NSI lobed nozzle 86 is not known in the art but is used herein as a baseline for comparison. In Fig. 5a. the exit plane of the NSI lobed nozzle 86 is overlaid in combination with a section view of the second stage exhaust nozzle 28 at exit plane P70. The profile of the NSI nozzle 86 is shown in dashed lines in areas where the NSI nozzle 86 structurally differs from the second stage exhaust nozzle 28 and in solid lines in areas where the nozzles are essentially identical. By examination of the profiles, it will be appreciated that areas A70 represent additional flow area for engine exhaust at the exit plane P70 of the second stage exhaust nozzle 28.
In Fig. 5b, the NSI lobed nozzle 86 is again overlaid in combination with a section view of the second stage exhaust nozzle at exit plane P72. The profile of the NSI nozzle is shown in dashed lines in areas where the nozzle 86 structurally differs from the second stage nozzle 28 and a dotted line 88 establishes a minimum upper flow boundary for the second stage nozzle 28. By examination thereof, it will be appreciated, that areas A72 represent additional flow area for engine exhaust at the exit plane P72 of the second stage exhaust nozzle 28. Accordingly, the total flow area at each of the exit planes P70, P72 is larger when compared to the baseline NSI lobed nozzle 86, and, as such, the second stage nozzle 28 is less restrictive with respect to the flow of engine exhaust.
Summary and Alternate Embodiments of the Invention
Returning to Fig. 2, the multi-stage mixer/ejector 20 employs various mechanisms, some known in the art and others which are the subject of this invention, to effect significant IR signature reduction while maintaining and/or improving engine performance. Firstly, as is known in the art, each stage of the mixer/ejector 20 introduces cooling air SF,, SF2 into the primary exhaust flow PF for reducing engine exhaust temperature. Fluid mixing/pumping is achieved by a venturi effect which relies on the high velocity primary exhaust flow PF to entrain the secondary flows SF,, SF2 of cooling air. As such, the need for additional apparatus to force or pump fluid is eliminated. Furthermore, the shroud means 32 substantially envelops the first and second stage nozzles 24, 28 and, accordingly, serves to occlude the exterior surfaces thereof. Inasmuch as the temperature of such surfaces may be elevated, the shroud means 32 prevents direct viewing of the nozzles 24, 28 and, accordingly, diminishes or eliminates the IR signature radiated from such surfaces.
The staggered configuration of the penetrating lobes 60, 62 or 70, 72 facilitates entrainment of cooling air into the primary exhaust flow PF without degrading engine performance. Firstly, by staggering the lobes 60, 62 or 70, 72, each nozzle 24 or 28 produces two ejector pumps in series, i.e.. a first ejector pump at the exit plane P60 or P70 of the first plurality of penetrating lobes 60 or 70, and a second ejector pump at the exit plane P62, P72 of the second plurality of penetrating lobes 62. or 72. As such, the fluid dynamic pumping is augmented to (i) entrain more cooling fluid for suppressing the IR signature of the exhaust plume and (ii) reduce back-pressure for improving engine performance. Secondly, by staggering the penetrating lobes 60, 62 or 70, 72, it is possible to situate individual lobes in the core region of the primary flow without creating a restrictive "choke point" at any one axial station or plane. As such, further IR suppression is achievable without degrading performance.
In the described embodiment, each nozzle, 24 or 28, in combination with its respective shroud, 42 or 48, maintains engine performance, collectively, the multi-stage mixer/ejector 20 improves engine performance by about 1 - 6%. Furthermore, each exhaust nozzle, 24 or 28, in combination with its respective shroud, 42 or 48, is capable of effecting a 30 - 40% diffusion of IR energy within about two (2) diameters downstream of the nozzle, wherein the diameter is the measured relative to the diameter of the engine exhaust cowling 38. Collectively, the multi-stage mixer/ejector 20 effects an energy reduction on the order of about 60 - 80% from the high temperature exhaust EHT to the cooled exhaust Ec. While the IR suppressors of the prior art and the exhaust nozzles used therein typically require multiple forming and assembly steps, the multi-stage mixer/ejector 20 may be formed from conventional low-cost fabrication techniques such as casting or press molding. For example, a highly accurate mold may be fabricated by forming a stereolithography model of the exhaust nozzle, and subsequently, casting a wear and temperature resistance material over the stereolithography model to form a filled casting. The polymer used in the stereolithography process is then removed in a high temperature furnace to form an accurate casting of the exhaust nozzle. Yet another example includes the use of a hydro-forming process wherein a sheet-metal workpiece is fabricated which approximates the size and shape of the nozzle. Hydrostatic pressure is then applied to press-mold the workpiece against an accurate three-dimensional solid model of the nozzle to form the final nozzle configuration. While exhaust nozzles and/or ducts of the prior art typically include individually fabricated and assembled turning vanes for directing exhaust flow, the inset lobe configuration of the second stage exhaust nozzle 28 produces turning vanes 80 as an integral part of the nozzle wall.
Although the invention has been shown and described with respect to exemplary embodiments thereof, it should be understood by those skilled in the art that other changes, omissions and additions may be made therein and thereto, without departing from the spirit and scope of the present invention. For example, while the first stage exhaust nozzle 24 of the mixer/ejector 20 includes an equal number of alternating perimeter and core penetrating lobes 60, 62, it will be understood that the number of lobes need not be equal nor be alternating with respect to each other. Such configuration is shown in Fig. 6a wherein a core penetrating lobe 62' is disposed between pairs of perimeter penetrating lobes 60'. Furthermore, while the penetrating lobes 60, 62 of the first stage exhaust nozzle 24 are shown to be substantially radial, it should be appreciated that the penetrating lobes could be swirled to effect axial rotation of the exhaust flow. Moreover, while the outlet end of the second stage exhaust nozzle 28 defines a substantially rectangular geometric profile, it will be appreciated that other shapes will accommodate the inset configuration of the penetrating lobes 70, 72. For example, in Figs. 6b and 6c, the outlet end may define an elliptical geometric profile as shown in Fig. 6b, or an hour-glass shape as depicted in Fig. 6c. In other embodiments of the invention, the adjoined lobes may include additional penetrating lobes to define a third, fourth or higher plurality of penetrating lobes. Such example is depicted in Fig. 6d wherein the adjoined lobes 30 include a first, second and third plurality of penetrating lobes 60', 62', and 64', respectively, and wherein each plurality of penetrating lobes 60', 62', 64' terminate at a distinct exit plane P'. While in the described embodiment, each of the penetrating lobes 70, 72 of the second stage nozzle 28 terminate along a substantially vertical plane, it will be appreciated that the end face 70EF may be stepped or inclined so as to effect a gradual stagger of the penetrating lobes in an axial direction.
What is claimed is:

Claims

1. A multi-stage mixer/ejector (20) including at least one exhaust nozzle (24 or 28), the exhaust nozzle (24 or 28) having an inlet conduit adapted for receiving a primary flow PF of engine exhaust and a plurality of adjoined lobes (30) integrally formed in combination with the inlet conduit and defining an outlet end of the exhaust nozzle (24 or 28), the adjoined lobes (30), furthermore, being adapted for admixing a secondary flow SF of low-temperature gaseous fluid with the primary flow PF. the multi-stage mixer/ejector (20) being characterized by: said adjoined lobes (30) of said exhaust nozzle (24 or 28) defining a first and second plurality of penetrating lobes (60, 62 or 70, 72), said penetrating lobes (60, 62 or 70, 72) being axially staggered with respect to each other.
2. The multi-stage mixer/ejector (20) according to claim 1 wherein at least one of said plurality of penetrating lobes (60 or 62, 70 or 72) extends into a core region of the exhaust nozzle (24 or 28).
3. A multi-stage mixer/ejector (20) operative to suppress the infrared signature radiated from a primary flow PF of high-temperature exhaust of an engine (12), the multi-stage mixer ejector (20) having tandemly arranged first and second stage exhaust nozzles (24, 28), and a shroud means (32) enveloping the exhaust nozzles (24, 28), said exhaust nozzles (24, 28) in combination with said shroud means (32), operative to entrain a secondary flow SF of low-temperature gaseous fluid into the primary flow; the' first stage exhaust nozzle (24) including: an inlet conduit (36) adapted for receiving the primary flow PF of engine exhaust; a plurality of adjoined lobes (30) integrally formed in combination with said inlet conduit (36) and defining an outlet end of the exhaust nozzle (24), each of said adjoined lobes (30) being substantially radially oriented with respect to a longitudinal axis (24 defined by said outlet end, said adjoined lobes (30), in combination with said shroud means (32), being adapted for admixing the secondary flow SF of low-temperature gaseous fluid with said primary flow PF of engine exhaust; said multi-stage ejector (20) being characterized by: said adjoined lobes (30) of said first stage exhaust nozzle (24) defining a first and second plurality of penetrating lobes (60, 62), said penetrating lobes (60, 62) each defining an external flow trough (30EFT), said external flow troughs (30EFT) of said first plurality (60) defining a core region (CR); said second plurality of penetrating lobes (62) projecting axially downstream of said first plurality of penetrating lobes (60) and extending into said core region (CR) so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of engine exhaust.
1 4. The multi-stage mixer/ejector (20) according to claim 3 wherein the end points (62E) of said second plurality of penetrating lobes (62) are proximal to said
3 longitudinal axis (24A).
1 5. The multi-stage mixer/ejector (20) according to claim 3 wherein said first
2 and second plurality of penetrating lobes (60, 62) are alternately disposed about the
3 periphery of the first stage exhaust nozzle (24).
6. The multi-stage mixer/ejector (20) according to claim 3 wherein said second
~> plurality of penetrating lobes (62) are equiangularly spaced about said longitudinal 3 axis (24A).
1 7. The multi-stage mixer/ejector (20) according to claim 3 wherein each of said
2 external flow troughs (30EFT) of said second plurality of penetrating lobes (62) define
3 a smooth curve (66) along its length, said smooth curve (66) having a slope less than
4 about 30 degrees relative to said longitudinal axis (24A).
8. The multi-stage mixer/ejector (20) according to claim 7 wherein said second plurality of penetrating lobes (62) taper in radial height and width dimension along its length.
9. The multi-stage mixer/ejector (20) according to claim 3 wherein said first and second plurality of penetrating lobes (60, 62) are alternately disposed about the periphery of the first stage exhaust nozzle (24), and wherein said second plurality of penetrating lobes (62) are equiangularly spaced about said longitudinal axis (24A).
10. The multi-stage mixer/ejector (20) according to claim 9 wherein each of said external flow troughs (30EFT) of said second plurality of penetrating lobes (62) define a smooth curve (66) along its length, said smooth curve (66) having a slope less than about 30 degrees relative to said longitudinal axis (24A).
11. The multi-stage mixer/ejector (20) according to claim 10 wherein said second plurality of penetrating lobes (62) taper in radial height and width dimension along its length.
12. A multi-stage mixer/ejector (20) operative to suppress the infrared signature radiated from a primary flow PF of high-temperature exhaust of an engine (12), the multi-stage mixer ejector (20) having tandemly arranged first and second stage exhaust nozzles (24, 28), and a shroud means (32) enveloping the exhaust nozzles (24, 28), said exhaust nozzles (24, 28), in combination with said shroud means (32), operative to entrain a secondary flow SF of low-temperature gaseous fluid into the primary flow, the second stage exhaust nozzle (28) including: an inlet conduit (46) adapted for receiving the primary flow PF of engine exhaust; a plurality of adjoined lobes (30) integrally formed in combination with said inlet conduit (46) and defining an outlet end of the exhaust nozzle (28), each of said adjoined lobes (30) being substantially perpendicular with respect midplane PM defined by said outlet end, said adjoined lobes (30), in combination with said shroud means (32), being adapted for admixing the secondary flow SF of low-temperature gaseous fluid with the primary flow PF of partially cooled exhaust to produce a primary flow of cooled/suppressed engine exhaust; said multi-stage mixer/ejector (20) being characterized by: said adjoined lobes (30) defining a first and second plurality of penetrating lobes (70, 72), said penetrating lobes (70, 72) each defining an external flow trough (30EFT), said external flow troughs (30EFT) of said first plurality (70) defining a core region (CR); said penetrating lobes (70, 72) furthermore being inset with respect to each other: and said second plurality of penetrating lobes (72) projecting axially downstream of said first plurality of penetrating lobes (70) and extending into said core region (CR) so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of engine exhaust.
13. The multi-stage mixer/ejector (20) according to claim 12 wherein the exhaust nozzle (28) is also operative to suppress the infrared signature radiated from the hot metal components of the engine (12), and wherein said penetrating lobes (70,72) define a plurality of turning vanes (80) adapted for redirecting the primary exhaust flow PF.
14. The multi-stage mixer/ejector (20) according to claim 12 wherein first plurality of penetrating lobes (70) define an exit plane P70, and wherein said first and second plurality of penetrating lobes (70, 72) are inset at an axial location (74) inboard of said exit plane (P70) for preventing direct line-of-sight viewing into said exhaust nozzle (28).
15. The multi-stage mixer/ejector (20) according to claim 12 wherein said inlet conduit (46) defines a substantially circular geometric profile and said penetrating lobes (70, 72) define a substantially rectangular geometric profile.
16. The multi-stage mixer/ejector (20) according to claim 12 wherein said second plurality of penetrating lobes (72) define an exit plane P72, and wherein said second plurality of penetrating lobes (72) fully traverse said core region (CR) so as to divide the primary flow into a plurality of discrete flow segments.
17. A multi-stage mixer/ejector (20) operative to suppress the infrared signature radiated from a primary flow PF of high-temperature exhaust of an engine (12), the multi-stage mixer ejector (20) having tandemly arranged first and second stage exhaust nozzles (24, 28), and a shroud means (32) enveloping the exhaust nozzles (24, 28), the first stage exhaust nozzle (24) including: an inlet conduit (36) adapted for receiving the primary flow PF of high- temperature engine exhaust; a plurality of adjoined lobes (30) integrally formed in combination with said inlet conduit (36) and defining an outlet end of the exhaust nozzle (24), each of said adjoined lobes (30) being substantially radially oriented with respect to a longitudinal axis (2 A) defined by said outlet end, said adjoined lobes (30), in combination with said shroud means (32), being adapted for admixing the secondary flow SF of low-temperature gaseous fluid with said primary flow PF of high- temperature exhaust to produce a primary flow PF of partially-cooled engine exhaust; said second stage exhaust nozzle (28) including: an inlet conduit (46) adapted for receiving the primary flow PF of partially cooled engine exhaust; a plurality of adjoined lobes (30) integrally formed in combination with said inlet conduit (46) and defining an outlet end of the exhaust nozzle (28), each of said adjoined lobes (30) being substantially perpendicular with respect midplane PM defined by said outlet end, said adjoined lobes (30), in combination with said shroud means (32), being adapted for admixing the secondary flow SF of low-temperature gaseous fluid with the primary flow PF of partially cooled exhaust to produce a primary flow of cooled/suppressed engine exhaust; said multi-stage ejector (20) being characterized by: said adjoined lobes (30) of said first stage exhaust nozzle (24) defining a first and second plurality of penetrating lobes (60, 62), said penetrating lobes (60, 62) each defining an external flow trough (30EFT), said external flow troughs (30EFT) of said first plurality (60) defining a core region (CR); said second plurality of penetrating lobes (62) projecting axially downstream of said first plurality of penetrating lobes (60) and extending into said core region (CR) so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of high temperature engine exhaust; and said adjoined lobes (30) of said second stage exhaust nozzle (28) defining a first and second plurality of penetrating lobes (70, 72), said penetrating lobes (70, 72) each defining an external flow trough (30EFT), said external flow troughs (30EFT) of said first plurality (70) defining a core region (CR); said penetrating lobes (70, 72) furthermore being inset with respect to each other; and said second plurality of penetrating lobes (72) projecting axially downstream of said first plurality of penetrating lobes (70) and extending into said core region (CR) so as to direct the secondary flow SF of low temperature gaseous fluid deeply into the primary flow PF of high temperature engine exhaust.
18. The multi-stage mixer/ejector (20) according to claim 17 wherein said shroud means (32) includes first and second shrouds (42, 48) enveloping said first and second exhaust nozzles (24, 28), respectively, said second shroud enveloping an outlet end (420) of said first shroud (42).
PCT/US1998/011853 1997-06-24 1998-06-19 Multi-stage mixer/ejector for suppressing infrared radiation WO1998059162A1 (en)

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EP98931220A EP0991860B1 (en) 1997-06-24 1998-06-19 Multi-stage mixer/ejector for suppressing infrared radiation
DE69802083T DE69802083T2 (en) 1997-06-24 1998-06-19 MULTI-STAGE EJECTOR MIXER NOZZLE TO AVOID INFRARED RADIATION
AU81397/98A AU8139798A (en) 1997-06-24 1998-06-19 Multi-stage mixer/ejector for suppressing infrared radiation
JP50453699A JP2002511128A (en) 1997-06-24 1998-06-19 Multi-stage mixer / emitter to suppress infrared radiation

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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2350649A (en) * 1999-06-04 2000-12-06 Rolls Royce Plc Nozzle shroud
US6381950B1 (en) 1999-07-07 2002-05-07 Bae Systems Plc Engine nozzle arrangement for an aircraft
JP2002317698A (en) * 2001-04-19 2002-10-31 Ishikawajima Harima Heavy Ind Co Ltd Lobe mixer for jet engine
EP1943419A2 (en) * 2005-08-01 2008-07-16 Sikorsky Aircraft Corporation Infrared suppression system
EP1752649A3 (en) * 2005-08-10 2010-03-24 United Technologies Corporation Serrated nozzle trailing edge of a gas turbine
EP2719620A3 (en) * 2012-10-10 2017-10-18 Sikorsky Aircraft Corporation Upturned exhaust system for rotary wing aircraft
CN111997779A (en) * 2020-09-02 2020-11-27 南昌航空大学 Continuous deep trough alternating lobe spray pipe

Families Citing this family (36)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7284364B2 (en) 2003-09-08 2007-10-23 Northrop Grumman Ship Systems, Inc. Passive exhaust suppressor and method
US6971240B2 (en) * 2004-03-30 2005-12-06 General Electric Company Methods and apparatus for exhausting gases from gas turbine engines
US7434384B2 (en) * 2004-10-25 2008-10-14 United Technologies Corporation Fluid mixer with an integral fluid capture ducts forming auxiliary secondary chutes at the discharge end of said ducts
US7418813B2 (en) * 2004-12-27 2008-09-02 General Electric Company Gas turbine engine exhaust nozzle including an infrared suppression system having a plurality of U-shaped blocking fins and method of assembling said exhaut nozzle
EP1989513B1 (en) * 2006-02-27 2013-12-11 Sikorsky Aircraft Corporation Aircraft load management system for interior loads
US20100028132A2 (en) * 2007-03-23 2010-02-04 Flodesign Wind Turbine Corporation Wind turbine with mixers and ejectors
US8622688B2 (en) * 2007-03-23 2014-01-07 Flodesign Wind Turbine Corp. Fluid turbine
CN101680422B (en) * 2007-03-23 2013-05-15 弗洛设计风力涡轮机公司 Wind turbine with mixers and ejectors
US20110014038A1 (en) * 2007-03-23 2011-01-20 Flodesign Wind Turbine Corporation Wind turbine with skeleton-and-skin structure
US8021100B2 (en) * 2007-03-23 2011-09-20 Flodesign Wind Turbine Corporation Wind turbine with mixers and ejectors
US8657572B2 (en) 2007-03-23 2014-02-25 Flodesign Wind Turbine Corp. Nacelle configurations for a shrouded wind turbine
US20100316493A1 (en) * 2007-03-23 2010-12-16 Flodesign Wind Turbine Corporation Turbine with mixers and ejectors
US20110008164A1 (en) * 2007-03-23 2011-01-13 Flodesign Wind Turbine Corporation Wind turbine
US20110020107A1 (en) * 2007-03-23 2011-01-27 Flodesign Wind Turbine Corporation Molded wind turbine shroud segments and constructions for shrouds
US20110027067A1 (en) * 2007-03-23 2011-02-03 Flodesign Wind Turbine Corporation Coated shrouded wind turbine
US20100314885A1 (en) * 2007-03-23 2010-12-16 Flodesign Wind Turbine Corporation Shrouded wind turbine with rim generator and halbach array
US20090230691A1 (en) * 2007-03-23 2009-09-17 Presz Jr Walter M Wind turbine with mixers and ejectors
DE102007063018A1 (en) * 2007-12-21 2009-06-25 Rolls-Royce Deutschland Ltd & Co Kg Nozzle with guide elements
US20090217643A1 (en) * 2008-02-29 2009-09-03 Sokhey Jagdish S Gas discharge device for a vehicle engine
US20100199626A1 (en) * 2008-12-31 2010-08-12 Benjamin Roland Harding Turbine engine exhaust gas tube mixer
CA2755135A1 (en) * 2009-03-30 2010-10-07 Flodesign Wind Turbine Corporation Segmented wind turbine
US8905335B1 (en) * 2009-06-10 2014-12-09 The United States Of America, As Represented By The Secretary Of The Navy Casting nozzle with dimensional repeatability for viscous liquid dispensing
US20120145268A1 (en) * 2010-12-08 2012-06-14 Caterpillar Inc. Exhaust Ejector For An Internal Combustion Engine
US9051047B2 (en) * 2012-11-12 2015-06-09 Sikorsky Aircraft Corporation Flexbeam rotor attachment to rotor blade
US20160258358A1 (en) * 2015-03-02 2016-09-08 Sikorsky Aircraft Corporation High turning angle ejector cooled turbine engine exhaust duct
US10086332B2 (en) 2015-05-07 2018-10-02 Ford Global Technologies, Llc Exhaust flow device
US9822688B2 (en) 2015-06-24 2017-11-21 Ford Global Technologies, Llc Exhaust flow device
US10066530B2 (en) 2015-11-17 2018-09-04 Ford Global Technologies, Llc Exhaust gas mixer
US10119449B2 (en) * 2016-08-02 2018-11-06 The Boeing Company Systems and methods for restraining exhaust gas ducts
US20180100468A1 (en) * 2016-10-07 2018-04-12 Rolls-Royce North American Technologies Inc. System and method for reduction of turbine exhaust gas impingement on adjacent aircraft structure
US10829228B2 (en) * 2017-01-17 2020-11-10 Itt Manufacturing Enterprises, Llc Fluid straightening connection unit
DE102018203159B4 (en) * 2018-03-02 2021-05-06 MTU Aero Engines AG Reduction of contrails when operating aircraft
FR3079211B1 (en) * 2018-03-23 2020-11-20 Airbus Operations Sas AIRCRAFT PROPULSION ASSEMBLY COMPRISING TWO ADJACENT ENGINES, OF WHICH THE OUTLET PIPES PRESENT A RIGHT PORTION NEAR A MEDIAN PLANE OF THE PROPULSION ASSEMBLY
CN110748436B (en) * 2019-10-16 2021-06-15 南京航空航天大学 Double-layer cooling mixing pipe injection type infrared suppressor
US11608189B2 (en) * 2020-08-11 2023-03-21 Textron Innovations Inc Multistage infrared suppression exhaust system
CN115614177B (en) * 2022-08-29 2024-04-16 中国航发四川燃气涡轮研究院 Full shielding blending integrated casing

Citations (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3048376A (en) * 1958-04-09 1962-08-07 Curtiss Wright Corp Fluid mixing apparatus
US3084505A (en) * 1960-05-03 1963-04-09 Robert A Cherchi Exhaust duct for turbo-jet engine
FR2087076A5 (en) * 1970-05-04 1971-12-31 Bertin & Cie
US4018046A (en) 1975-07-17 1977-04-19 Avco Corporation Infrared radiation suppressor for gas turbine engine
GB2085088A (en) * 1980-09-26 1982-04-21 United Technologies Corp Lobe mixer for gas turbine engine
FR2515735A1 (en) * 1981-11-03 1983-05-06 Rolls Royce INFRARED RADIATION SUPPRESSION DEVICE FOR GAS TURBINE ENGINE
GB2119859A (en) * 1982-05-06 1983-11-23 Rolls Royce Exhaust mixer for bypass gas turbine aeroengine
GB2160265A (en) * 1984-06-12 1985-12-18 Rolls Royce Turbofan exhaust mixers
US4830315A (en) 1986-04-30 1989-05-16 United Technologies Corporation Airfoil-shaped body
US4835961A (en) 1986-04-30 1989-06-06 United Technologies Corporation Fluid dynamic pump
EP0635632A1 (en) * 1993-06-25 1995-01-25 Nordam Fixed geometry mixer/ejector noise suppression system for turbofan aircraft engines
EP0761956A2 (en) * 1995-09-08 1997-03-12 United Technologies Corporation Double lobed mixer for turbofan engine

Family Cites Families (14)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR1318785A (en) * 1962-01-12 1963-02-22 Bertin & Cie Improvements to the tubes with thin inducing jets, usable, in particular, to the levitation
US3981448A (en) * 1970-04-23 1976-09-21 The Garrett Corporation Cooled infrared suppressor
US3926373A (en) * 1974-07-26 1975-12-16 Us Air Force Thrust augmentation system with oscillating jet nozzles
US3921906A (en) * 1974-12-02 1975-11-25 Gen Electric Infrared suppression system for a gas turbine engine
US4007587A (en) * 1975-11-19 1977-02-15 Avco Corporation Apparatus for and method of suppressing infrared radiation emitted from gas turbine engine
US4095417A (en) * 1976-08-23 1978-06-20 Avco Corporation Apparatus for and method of suppressing infrared radiation emitted from gas turbine engine
JPS5813734B2 (en) * 1977-12-13 1983-03-15 トヨタ自動車株式会社 engine exhaust diffuser
US4215537A (en) * 1978-07-27 1980-08-05 Avco Corporation Apparatus for and method of suppressing infrared radiation emitted from gas turbine engine
US4312480A (en) * 1979-11-26 1982-01-26 Hughes Helicopters, Inc. Radiation shielding and gas diffusion apparatus
DE3129305A1 (en) * 1981-07-24 1983-02-10 MTU Motoren- und Turbinen-Union München GmbH, 8000 München Device for infrared suppression for aircraft, especially helicopters
US4800715A (en) * 1981-08-10 1989-01-31 The United States Of America As Represented By The Secretary Of The Army Apparatus for suppressing infrared radiation emitted from gas turbine engines
US5265807A (en) * 1992-06-01 1993-11-30 Rohr, Inc. Aerodynamic stiffening ring for an aircraft turbine engine mixer
US5758488A (en) * 1993-05-11 1998-06-02 Roderick Thomson Core flow expansion chamber device system for reduction of jet turbine engine noise
US5761900A (en) * 1995-10-11 1998-06-09 Stage Iii Technologies, L.C. Two-stage mixer ejector suppressor

Patent Citations (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3048376A (en) * 1958-04-09 1962-08-07 Curtiss Wright Corp Fluid mixing apparatus
US3084505A (en) * 1960-05-03 1963-04-09 Robert A Cherchi Exhaust duct for turbo-jet engine
FR2087076A5 (en) * 1970-05-04 1971-12-31 Bertin & Cie
US4018046A (en) 1975-07-17 1977-04-19 Avco Corporation Infrared radiation suppressor for gas turbine engine
GB2085088A (en) * 1980-09-26 1982-04-21 United Technologies Corp Lobe mixer for gas turbine engine
FR2515735A1 (en) * 1981-11-03 1983-05-06 Rolls Royce INFRARED RADIATION SUPPRESSION DEVICE FOR GAS TURBINE ENGINE
GB2119859A (en) * 1982-05-06 1983-11-23 Rolls Royce Exhaust mixer for bypass gas turbine aeroengine
GB2160265A (en) * 1984-06-12 1985-12-18 Rolls Royce Turbofan exhaust mixers
US4830315A (en) 1986-04-30 1989-05-16 United Technologies Corporation Airfoil-shaped body
US4835961A (en) 1986-04-30 1989-06-06 United Technologies Corporation Fluid dynamic pump
EP0635632A1 (en) * 1993-06-25 1995-01-25 Nordam Fixed geometry mixer/ejector noise suppression system for turbofan aircraft engines
EP0761956A2 (en) * 1995-09-08 1997-03-12 United Technologies Corporation Double lobed mixer for turbofan engine

Cited By (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2350649A (en) * 1999-06-04 2000-12-06 Rolls Royce Plc Nozzle shroud
GB2350649B (en) * 1999-06-04 2003-10-29 Rolls Royce Plc Nozzle shroud
US6381950B1 (en) 1999-07-07 2002-05-07 Bae Systems Plc Engine nozzle arrangement for an aircraft
JP2002317698A (en) * 2001-04-19 2002-10-31 Ishikawajima Harima Heavy Ind Co Ltd Lobe mixer for jet engine
JP4743465B2 (en) * 2001-04-19 2011-08-10 株式会社Ihi Lobe mixer for jet engines
EP1943419A2 (en) * 2005-08-01 2008-07-16 Sikorsky Aircraft Corporation Infrared suppression system
EP1943419B1 (en) * 2005-08-01 2015-01-07 Sikorsky Aircraft Corporation Infrared suppression system
EP1752649A3 (en) * 2005-08-10 2010-03-24 United Technologies Corporation Serrated nozzle trailing edge of a gas turbine
EP2568151A3 (en) * 2005-08-10 2013-11-06 United Technologies Corporation Serrated nozzle trailing edge for exhaust noise suppression
EP2719620A3 (en) * 2012-10-10 2017-10-18 Sikorsky Aircraft Corporation Upturned exhaust system for rotary wing aircraft
CN111997779A (en) * 2020-09-02 2020-11-27 南昌航空大学 Continuous deep trough alternating lobe spray pipe
CN111997779B (en) * 2020-09-02 2022-07-12 南昌航空大学 Continuous deep trough alternating lobe spray pipe

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DE69802083T2 (en) 2002-09-12
JP2002511128A (en) 2002-04-09
EP0991860A1 (en) 2000-04-12
AU8139798A (en) 1999-01-04
US6016651A (en) 2000-01-25
EP0991860B1 (en) 2001-10-17

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