초록 ▼

A ramjet powered device that utilizes a novel swirl generator for rapidly and efficiently atomizing, vaporizing, as necessary, and mixing a fuel into an oxidant. The swirl generator converts an oxidant flow into a turbulent, three-dimensional flowfield into which the fuel is introduced. The swirl ge

A ramjet powered device that utilizes a novel swirl generator for rapidly and efficiently atomizing, vaporizing, as necessary, and mixing a fuel into an oxidant. The swirl generator converts an oxidant flow into a turbulent, three-dimensional flowfield into which the fuel is introduced. The swirl generator effects a toroidal outer recirculation zone and an inner central recirculation zone, both of which are configured in a backward-flowing manner that carries heat and combustion byproducts upstream where they are employed to continuously ignite a combustible fuel/oxidizer mixture in adjacent shear layers and stabilizes flame propagation and accelerates combustion throughout the entire combustor. The swirl generator provides smooth combustion with no instabilities and minimum total pressure losses and enables significant reductions in the L/D ratio of the combustor. Other benefits include simplicity, reliability, wide flammability limits and high combustion efficiency and thrust performance.

대표청구항 ▼

What is claimed is: 1. An apparatus comprising: at least one core turbojet engine, each core turbojet engine having a low pressure compressor, a high pressure compressor, a combustor, and a turbine; at least one ramjet engine coupled to the at least one core turbojet engine, each ramjet engine havi

What is claimed is: 1. An apparatus comprising: at least one core turbojet engine, each core turbojet engine having a low pressure compressor, a high pressure compressor, a combustor, and a turbine; at least one ramjet engine coupled to the at least one core turbojet engine, each ramjet engine having an air inlet, a swirl generator, a ramjet combustor and a nozzle, the swirl generator being coupled to the air inlet and being operable for converting an oxidizer flow into a three-dimensional flowfield that includes a tangential velocity component, the swirl generator including a flow defining means and a fueling means, the flow defining means being operable for effecting both an outer recirculation zone and a central recirculation zone in the ramjet combustor, the outer recirculation zone being toroidal in shape, the central recirculation zone being disposed inwardly of the outer recirculation zone, the fueling means being operable for fueling the outer and central recirculation zones, wherein heat and combustion by-products produced during combustion in the ramjet combustor are carried upstream by the outer and central recirculation zones where the heat and combustion by-products are employed to continuously ignite a combustible fuel/oxidizer mixture in a shear layer adjacent each of the outer and central recirculation zones, which accelerate propagation of the flame into and throughout the core flowfield; and a flow controller coupled to the at least one core turbojet engine and the at least one ramjet engine, the flow controller having at least one forward moveable element and at least one aft moveable element, the at least one forward moveable element being movable between a first position, in which the air intake of the at least one ramjet engine is closed and atmospheric air is permitted to flow into the low pressure compressor of the at least one core turbojet engine, and a second position in which atmospheric air is not permitted to flow into the lower pressure compressor of the at least one core turbojet engine and the air intake of the at least one ramjet engine is open, the at least one aft moveable element being movable between a first position, in which an exit of the nozzle is closed and an exit of the at least one core turbojet engine is open to permit exhaust gas to flow therethrough, and a second position in which the exit of the nozzle is open and the exit of the at least one core turbojet engine is closed. 2. The apparatus of claim 1, wherein the at least one core turbojet engine includes an air bypass that is selectively operable to input a flow of air into the at least one ramjet engine at a location aft of the air intake. 3. The apparatus of claim 2, wherein a first end of the air bypass is located between the high pressure compressor and the combustor. 4. The apparatus of claim 1, wherein the flow defining means includes a swirl vane pack having a plurality of vanes and wherein the vanes are configured to provide the swirl vane pack with a swirl number that is less than about 2.0. 5. The apparatus of claim 4, wherein the swirl number of the swirl vane pack is about 0.4 to about 1.2. 6. The apparatus of claim 4, wherein the swirl vanes are mounted to a centerbody assembly. 7. The apparatus of claim 6, wherein the fueling means includes a plurality of fuel injectors that are coupled to at least one of the air inlet, the centerbody assembly and the swirl vanes. 8. The apparatus of claim 7, wherein at least a portion of the fuel injectors are positioned to inject the fuel downstream of the swirl vane pack. 9. The apparatus of claim 7, wherein each swirl vane includes a trailing edge and a lateral surface and wherein the fuel injection sites on a given swirl vane are formed into at least one of the trailing edge and the lateral surface. 10. The apparatus of claim 6, wherein the centerbody assembly terminates at an aft bluff boat-tail body, the aft bluff boat-tail body being configured to augment flow separation of the exhaust flow. 11. The apparatus of claim 1, wherein the fueling means includes a plurality of groups of fuel injectors for injecting the fuel directly into the oxidizer flow for at least partially mixing the fuel and oxidizer prior to entering the ramjet combustor. 12. A method comprising: providing a device having a core turbojet engine, a ramjet engine and a flow controller, the flow controller having a forward moveable element and an aft moveable element the forward moveable element being movable between a first position, in which an air intake of the ramjet engine is closed and atmospheric air is permitted to flow into the core turbojet engine, and a second position in which atmospheric air is permitted to flow only into the ramjet engine, the aft moveable element being movable between a first position, in which an exit of the ramjet is closed and an exit of the core turbojet engine is open to permit exhaust gas to flow therethrough, and a second position in which the exit of the nozzle is open and the exit of the core turbojet engine is closed; positioning each of the forward and aft moveable elements in their respective first positions if a velocity of the device is less than a first transition velocity and operating only the core turbojet engine; and operating both the core turbojet engine and the ramjet engine if the velocity of the device is not less than the first transition velocity and is less than a second transition velocity. 13. The method of claim 12, wherein the forward and aft moveable elements are positioned between their respective first and second positions when both the core turbojet engine and the ramjet engine are operating. 14. The method of claim 12, wherein the core turbojet engine includes a high pressure compressor, a combustor and an air bypass, the air bypass including a first end, which is disposed between the high pressure compressor and the combustor, and a second end, which is coupled to the ramjet engine between an air intake and a swirl generator, and wherein a portion of an airflow exiting the high pressure compressor is diverted through the air bypass to the ramjet engine when both the core turbojet engine and the ramjet engine are operating. 15. The method of claim 12, further comprising operating only the ramjet engine if the velocity of the device is not less than a second transition velocity. 16. The method of claim 15, wherein the forward and aft moveable elements are positioned in their respective second positions when only the ramjet engine is operating. 17. The method of claim 15, wherein the second transition velocity is about Mach 3 to about Mach 4. 18. The method of claim 12, wherein the first transition velocity is about Mach 2. 19. An apparatus for producing propulsive thrust comprising: a core turbojet engine having a low pressure compressor, a high pressure compressor, a combustor, and a turbine; a ramjet engine having a swirl generator and a ramjet combustor, the ramjet combustor having a combustor inlet, the swirl generator having an inlet housing, a swirl vane pack, a centerbody assembly, and a plurality of fuel injectors, the inlet housing being coupled to the combustor inlet and defining a hollow interior volume therein, the inlet housing serving as a conduit through which an oxidizer flow is conducted, the hollow interior volume intersecting the combustor inlet at a dump step wherein the inlet housing has an inner dimension that is smaller than that of the ramjet combustor, the swirl vane pack being disposed within the hollow interior volume and having a plurality of vanes, the vanes cooperating to change the velocity of the oxidizer flow so that the velocity includes a substantial tangential velocity component, the centerbody assembly being disposed in the hollow interior volume and being coupled to the swirl vane pack so as to extend rearwardly therefrom, and the plurality of fuel injectors being coupled to at least one of the inlet housing, the swirl vane pack and the centerbody assembly and dispensing a fuel therefrom directly into the oxidizer flow for at least partially mixing the fuel and oxidizer prior to entering the ramjet combustor, wherein the swirl generator converts the oxidizer flow received therein into a swirling, three-dimensional flowfield, wherein a first portion of the flowfield flows over the dump step to form an outer recirculation zone, wherein a second portion of the flowfield forms a central recirculation zone that is anchored by an aft end of the centerbody assembly, wherein a first portion of the fuel mixes with the first portion of the flowfield to fuel the outer recirculation zone, wherein a second portion of the fuel mixes with the second portion of the flowfield to fuel the central recirculation zone, and wherein a remaining portion of the fuel enters and fuels a core flow; and a flow controller coupled to the turbojet engine and the ramjet engine, the flow controller having at least one forward moveable element and at least one aft moveable element, the at least one forward moveable element being movable between a first position, in which the air intake of the ramjet engine is closed and atmospheric air is permitted to flow into the low pressure compressor of the core turbojet engine, and a second position in which atmospheric air is not permitted to flow into the lower pressure compressor of the core turbojet engine and the air intake of the ramjet engine is open, the at least one aft moveable element being movable between a first position, in which an exit of the nozzle is closed and an exit of the core turbojet engine is open to permit exhaust gas to flow therethrough, and a second position in which the exit of the nozzle is open and the exit of the core turbojet engine is closed; wherein when a velocity of the apparatus is less than a predetermined first transition velocity, the forward and aft moveable elements are positioned in their respective first positions and the core turbojet engine is operable for producing all of the propulsive thrust, and when the apparatus has a velocity that is not less than the predetermined transition velocity the ramjet engine is operable for producing at least a portion of the propulsive thrust. 20. The apparatus of claim 19, wherein when a velocity of the apparatus is greater than a second transition velocity, the forward and aft moveable elements are positioned in their respective second positions and the ramjet engine is operable for producing all of the propulsive thrust.