초록 ▼

A new dual-mode ramjet combustor used for operation over a wide flight Mach number range is described. Subsonic combustion mode is usable to lower flight Mach numbers than current dual-mode scramjets. High speed mode is characterized by supersonic combustion in a free-jet that traverses the subsonic

A new dual-mode ramjet combustor used for operation over a wide flight Mach number range is described. Subsonic combustion mode is usable to lower flight Mach numbers than current dual-mode scramjets. High speed mode is characterized by supersonic combustion in a free-jet that traverses the subsonic combustion chamber to a variable nozzle throat. Although a variable combustor exit aperture is required, the need for fuel staging to accommodate the combustion process is eliminated. Local heating from shock-boundary-layer interactions on combustor walls is also eliminated.

대표청구항 ▼

1. A dual-mode combustor, comprising: an inlet contraction section;an inlet section;said inlet contraction section interconnected with said inlet section;a plurality of dual-mode fuel injectors located in said inlet section;a subsonic diffusion section;a step interposed between said inlet section an

1. A dual-mode combustor, comprising: an inlet contraction section;an inlet section;said inlet contraction section interconnected with said inlet section;a plurality of dual-mode fuel injectors located in said inlet section;a subsonic diffusion section;a step interposed between said inlet section and said subsonic diffusion section, said step interconnecting said inlet section with said subsonic diffusion section;a subsonic combustion chamber; said subsonic diffusion section being interconnected with said subsonic combustion chamber;a ramjet-mode flame holder, said ramjet-mode flame holder in proximity with said subsonic diffusion section and said subsonic combustion chamber;a nozzle contraction section interconnected with said subsonic combustion chamber;a nozzle expansion section;an arc section, said arc section rotatably interconnected with said nozzle contraction section, said arc section rotatably interconnected with said nozzle expansion section, said arc section rotatably interposed between said nozzle contraction section and said nozzle expansion section, said arc section forming a nozzle throat having a diameter, said nozzle throat being adjustable to a relatively smaller diameter, and, said nozzle throat being adjustable to a relatively larger diameter; and,said dual-mode combustor being operable in a ramjet mode and a scramjet mode. 2. A dual-mode combustor as claimed in claim 1, wherein said inlet section is hinged to said subsonic diffusion section and has a variable diameter. 3. A dual-mode combustor as claimed in claim 1 wherein a nozzle positioner drives and moves said arc section forming said nozzle throat to a desired diametrical opening. 4. A dual-mode combustor as claimed in claim 3 wherein said ramjet mode includes subsonic operation from about flight Mach number 2.5 up to about flight Mach number 5.0 to 6.0, said scramjet mode includes supersonic operation from about flight Mach number 5.0 to 6.0 up to about flight Mach number 12.0 and greater, said nozzle positioner adjusting said nozzle throat to a relatively larger diameter between about flight Mach number 5.0 to 6.0 transitioning from said ramjet mode to said scramjet mode forming a free-jet from said inlet section, through said subsonic diffusion section, and said combustion chamber, said free-jet rejoins said nozzle throat and exits said combustor through said nozzle expansion section. 5. A dual-mode combustor as claimed in claim 4 wherein said nozzle positioner drives and moves said arc section forming said nozzle throat to a desired diametrical opening according to an algorithm which is a function of flight Mach number and combustor mode. 6. A dual-mode combustor as claimed in claim 4 wherein said ramjet-mode flame holder includes a circular aperture therein and being annularly located in proximity with said subsonic diffusion section and said subsonic combustion chamber, said free-jet passing through said circular aperture of said ramjet-mode flame holder but not engaging said ramjet-mode flame holder. 7. A dual-mode combustor as claimed in claim 1 wherein said inlet contraction section is frusto-conically shaped, said inlet section is cylindrically shaped, said subsonic diffusion section is generally frusto-conically shaped, said subsonic combustion chamber is cylindrically shaped, said nozzle contraction section is generally frusto-conically shaped and said nozzle expansion section is frusto-conically shaped. 8. A dual-mode combustor as claimed in claim 7 wherein said inlet section has a radius, said step interposed between said inlet section and said subsonic diffusion section is about one-tenth of said radius of said inlet section, and, said step extending radially outwardly from said inlet section. 9. A dual-mode combustor as claimed in claim 1 wherein said inlet contraction section, said inlet section, said subsonic diffusion section, said subsonic combustion chamber, said nozzle contraction section, and said nozzle expansion section are rectangularly shaped in cross-section. 10. A dual-mode-combustor as claimed in claim 1 wherein said arc section is rotatably and slidingly interconnected with said nozzle contraction section and said nozzle expansion section, said nozzle contraction section being substantially tangent with respect to said arc section and said nozzle expansion section being substantially tangent to said arc section. 11. A supersonic combustion ramjet engine, comprising: an inlet contraction section;an inlet section;said inlet contraction section interconnected with said inlet section;a plurality of dual-mode fuel injectors located in said inlet section;a subsonic diffusion section and a step;said step interposed between said inlet section and said subsonic diffusion section, said step interconnecting said inlet section and said subsonic diffusion section;a subsonic combustion chamber; said subsonic diffusion section being interconnected with said subsonic combustion chamber;a ramjet-mode flame holder, said ramjet-mode flame holder in proximity with said subsonic diffusion section and said subsonic combustion chamber;a nozzle contraction section interconnected with said subsonic combustion chamber;a nozzle expansion section;an arc section, said arc section slidingly interconnected with said nozzle contraction section, said arc section slidingly interconnected with said nozzle expansion section, said arc section slidingly interposed between said nozzle contraction section and said nozzle expansion section, said arc section forming a nozzle throat having a diameter, said nozzle throat being adjustable to a relatively smaller diameter, and, said nozzle throat being adjustable to a relatively larger diameter;a nozzle positioner drives and moves said arc section forming said nozzle throat to a desired position, said desired position of said nozzle throat being a function of the mode of the combustor and the flight Mach number;said supersonic combustion ramjet engine being operable in a ramjet mode and a scramjet mode, said ramjet mode includes subsonic operation from about flight Mach number 2.5 up to about flight Mach number 5.0 to 6.0, said scramjet mode includes supersonic operation from about flight Mach number 5.0 to 6.0 up to about flight Mach number 12.0 and greater, said nozzle positioner adjusting said nozzle throat to a relatively larger diameter between about flight Mach number 5.0 to 6.0 transitioning from said ramjet mode to said scramjet mode forming a free jet from said inlet section, through said subsonic combustion chamber, said free-jet rejoins said nozzle throat, and said free jet exits through said nozzle expansion section;said nozzle positioner drives and moves said arc section forming said nozzle throat to a desired diametrical opening according to an algorithm which is a function of flight Mach number and combustor mode;said ramjet-mode flame holder includes a circular aperture therein and being annularly located in proximity with said subsonic diffusion section and said subsonic combustion chamber, and, said free jet passing through said circular aperture of said ramjet-mode flame holder but not engaging said ramjet-mode flame holder. 12. A supersonic combustion ramjet engine, comprising: said supersonic combustion ramjet engine being operable in a ramjet mode and a scramjet mode;an inlet passageway receiving combustion air;said inlet passageway includes a fuel injector;a diffusion section and a combustion chamber; said diffusion section includes an inner periphery;a radial step interposed between and linking said inlet passageway and said diffusion section;said inlet passageway in communication with said diffusion section and said diffusion section in communication with said combustion chamber;a ramjet-mode flame holder, said ramjet-mode flame holder includes an array of igniters, said array of igniters includes a central circular aperture therethrough, said ramjet-mode flame holder residing in said diffusion section and affixed to said inner periphery thereof;a nozzle contraction section, a variable nozzle throat, and a nozzle expansion section;said combustion chamber in communication with said nozzle contraction section;said nozzle contraction section in communication with said variable nozzle throat; and,said variable nozzle throat in communication with said nozzle expansion section. 13. A supersonic combustion ramjet engine as claimed in claim 12 further comprising a nozzle positioner and wherein said nozzle throat includes an arc section, said nozzle positioner drives and moves said arc section forming said nozzle throat to a desired diametrical opening according to an algorithm which is a function of flight Mach number and combustor mode. 14. A supersonic combustion ramjet engine as claimed in claim 13 wherein said algorithm has a discontinuity at a given flight Mach number transitioning from said ramjet mode to said scramjet mode forming a free jet from said inlet section, through said subsonic combustion chamber, said free-jet rejoining said nozzle throat, and said free jet exiting through said nozzle expansion section. 15. A supersonic combustion ramjet engine as claimed in claim 14 wherein said ramjet mode includes subsonic operation from about flight Mach number 2.5 up to about flight Mach number 5.0 to 6.0, said scramjet mode includes supersonic operation from about flight Mach number 5.0 to 6.0 up to about flight Mach number 12.0 and greater, said nozzle positioner adjusting said nozzle throat to a relatively larger diameter between about flight Mach number 5.0 to 6.0 transitioning from said ramjet mode to said scramjet mode forming a free-jet extending from said inlet section at the location of said step to said nozzle throat, said free-jet not engaging said subsonic diffuser, said free-jet not engaging said combustion chamber, and, said free jet rejoining said nozzle throat.