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A long-duct mixed-flow nozzle system for a turbofan engine, the nozzle system may include an inner housing configured to enclose a core and form a core flow duct, the inner housing terminating in a core nozzle having a core exit aperture, an outer housing forming a fan flow duct and terminating in a

A long-duct mixed-flow nozzle system for a turbofan engine, the nozzle system may include an inner housing configured to enclose a core and form a core flow duct, the inner housing terminating in a core nozzle having a core exit aperture, an outer housing forming a fan flow duct and terminating in a fan exit aperture at a location downstream of the core exit aperture, the fan exit aperture having a plurality of chevrons, and the core exit aperture having a plurality of chutes separated by radially extending lobes configured to mix exhaust gas from the core flow duct with bypass gas flow in the fan flow duct, the radially extending lobes varying in profile from each other.

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1. A long-duct, mixed-flow nozzle system for a turbofan engine, the nozzle system comprising: an inner housing configured to enclose a core and form a core flow duct, the inner housing terminating in a core nozzle having a core exit aperture;an outer housing forming a fan flow duct and terminating i

1. A long-duct, mixed-flow nozzle system for a turbofan engine, the nozzle system comprising: an inner housing configured to enclose a core and form a core flow duct, the inner housing terminating in a core nozzle having a core exit aperture;an outer housing forming a fan flow duct and terminating in a fan exit aperture at a location downstream of the core exit aperture, the fan exit aperture defining a periphery and having a plurality of fan exit chevrons spaced around the periphery of the fan exit aperture; andthe core exit aperture having a plurality of chutes separated by a plurality of radially extending lobes spaced about a periphery of the core exit aperture, the chutes and the lobes configured to mix exhaust gas flow from the core flow duct with bypass gas flow in the fan flow duct, the radially extending lobes decreasing in width progressively from a first one of the plurality of lobes to a second one of the plurality of lobes on an opposite side of the core exit aperture, and wherein the plurality of exit fan chevrons and the plurality of radially extending lobes correspond in relative width so that progressively wider lobes are matched with progressively wider chevrons about the fan exit aperture and core exit aperture respectively. 2. The nozzle system of claim 1, wherein the fan flow duct is configured to convey a relatively cool bypass gas flow, the core flow duct is configured to convey a relatively hot gas flow, and the radially extending lobes are configured to mix the relatively cool bypass gas flow with the relatively hot gas flow. 3. The nozzle system of claim 1, wherein the plurality of radially extending lobes vary in profile from each other in a selected one or more of spacing, shape, exit plane shape, and radial length about the periphery of the core exit aperture. 4. The nozzle system of claim 1, wherein the fan exit chevrons are positioned such that the radially extending lobes line up in a radial direction with spaces between the fan exit chevrons. 5. The nozzle system of claim 4, wherein the fan exit chevrons vary in shape about the periphery of the fan exit aperture, selected from one or more of varying in a length, and varying in a spacing between adjacent ones of the fan exit chevrons. 6. The nozzle system of claim 4, wherein the fan exit chevrons are positioned such that a centerline of each exit chevron lines up in a radial direction with respect to one of the chutes. 7. The nozzle system of claim 1, wherein the chutes are adjacent the radially extending lobes, the plurality of chutes configured to mix the bypass gas flow in the fan flow duct with the exhaust gas flow from the core flow duct; and wherein the plurality of chutes vary in shape about the periphery of the core exit aperture, selected from one or more of varying in a length, varying in a width, and varying in a spacing of the fan exit chevrons. 8. The nozzle system of claim 1, wherein the radially extending lobes are matched with the fan exit chevrons to provide optimal sound reduction and operational efficiency. 9. The nozzle system of claim 8, wherein the radially extending lobes are matched with the fan exit chevrons selected from one or more of a shape of the radially extending lobes and a shape of the fan exit chevrons, and a number of the radially extending lobes equaling a number of the fan exit chevrons. 10. A vehicle including a turbofan engine having a long-duct, mixed-flow nozzle system, the turbofan engine comprising: a fan;a core having a low-pressure compressor, a high-pressure compressor, a combustion chamber, a high-pressure turbine and a low-pressure turbine connected to drive the fan;a core housing enclosing the core and forming a core flow duct configured to direct exhaust from the core aft of the turbofan engine, the core housing having an inlet downstream of the fan, and an outlet terminating in a core nozzle having a core exit aperture;an outer housing having an inlet enclosing the fan and forming a fan flow duct with the core housing configured to direct airflow from the fan aft of the turbofan engine, the outer housing terminating in a fan exit aperture downstream of the core exit aperture, the fan exit aperture defining a periphery and shaped to have a plurality of fan exit chevrons spaced around the periphery of the fan exit aperture; andthe core exit aperture shaped to form a plurality of chutes separated by a plurality of radially extending lobes spaced about a periphery of the core exit aperture, the chutes and the lobes configured to mix exhaust gas flow from the core flow duct with bypass gas flow in the fan flow duct, the radially extending lobes decreasing in width progressively from a first one of the plurality of lobes to a second one of the plurality of lobes on an opposite side of the core exit aperture, and wherein the plurality of exit fan chevrons and the plurality of radially extending lobes correspond in relative width so that progressively wider are lobes matched with progressively wider chevrons about the fan exit aperture and core exit aperture respectively. 11. The vehicle of claim 10, wherein the radially extending lobes vary in profile from each other in a selected one or more of spacing, shape, exit plane shape, and radial length about the periphery of the core nozzle. 12. The vehicle of claim 11, wherein the fan exit chevrons vary in shape about the periphery of the fan exit aperture, selected from one or more of varying in a length, and varying in a spacing of the fan exit chevrons. 13. The vehicle of claim 10, wherein the fan exit chevrons are spaced about the periphery of the fan exit aperture and are positioned such that the radially extending lobes line up in a radial direction with spaces between the fan exit chevrons. 14. The vehicle of claim 13, wherein radially extending lobes are matched with the fan exit chevrons to provide optimal sound reduction and operational efficiency. 15. The vehicle of claim 14, wherein the radially extending lobes are matched with the fan exit chevrons in a selected one or more of a shape of the radially extending lobes and a shape of the fan exit chevrons, and a number of the radially extending lobes equaling a number of the fan exit chevrons. 16. A method of constructing a long-duct, mixed-flow nozzle system for a turbofan engine, the method comprising: forming an inner housing configured to enclose a core and form a core flow duct, the inner housing terminating in a core nozzle having a core exit aperture;forming an outer housing defining a fan flow duct and terminating in a fan exit aperture at a location downstream of the core exit aperture, the fan exit aperture defining a periphery and having a plurality of chevrons spaced around the periphery of the fan exit aperture; andforming the core exit aperture with a plurality of chutes separated by a plurality of radially extending lobes spaced about a periphery of the core exit aperture, the chutes and the lobes shaped to mix bypass gas flow from the fan flow duct with exhaust from the core exit aperture, the radially extending lobes decreasing in width progressively from a first one of the plurality of lobes to a second one of the plurality of lobes on an opposite side of the core exit aperture, and wherein the plurality of exit fan chevrons and the plurality of radially extending lobes correspond in relative width so that progressively wider lobes are matched with progressively wider chevrons about the fan exit aperture and core exit aperture respectively. 17. The method of claim 16, wherein providing the core nozzle with a plurality of radially extending lobes includes providing a plurality of radially extending lobes spaced about the periphery of the core exit aperture that vary in profile from each other in a selected one or more of a spacing between the lobes, a shape of the lobes, an exit plane shape of the lobes, and a radial length of the lobes. 18. The method of claim 16, wherein forming the outer housing includes one or both of varying a shape of the fan exit chevrons about the periphery of the fan exit aperture and positioning the radially extending lobes to line up in a radial direction with spaces between the fan exit chevrons. 19. The method of claim 18, wherein varying the shape of the fan exit chevrons is selected from one or more of varying a length of the fan exit chevrons, and varying a spacing of the fan exit chevrons. 20. The method of claim 16, further comprising matching the radially extending lobes with the fan exit chevrons to provide optimal sound reduction and operational efficiency. 21. The method of claim 20, wherein matching the radially extending lobes with the fan exit chevrons includes selecting one or more of a shape of the radially extending lobes and a shape of the fan exit chevrons, and a number of the radially extending lobes equaling a number of the fan exit chevrons.