An aircraft control structure for drag management includes a nozzle structure configured to exhaust a swirling fluid stream. A plurality of swirl vanes are positioned within the nozzle structure, and an actuation subsystem is configured to cause the plurality of swirl vanes to move from a deployed s
An aircraft control structure for drag management includes a nozzle structure configured to exhaust a swirling fluid stream. A plurality of swirl vanes are positioned within the nozzle structure, and an actuation subsystem is configured to cause the plurality of swirl vanes to move from a deployed state to a non-deployed state. In the non-deployed state, the plurality of swirl vanes are substantially flush with the inner surface of the nozzle structure. In the deployed state, the plurality of swirl vanes produce the swirling fluid stream.
대표청구항▼
1. An aircraft control structure comprising: an engine nacelle comprising a downstream end, the engine nacelle comprising a nozzle structure defining a flow path and configured to exhaust a swirling fluid stream at a nozzle exit, the nozzle structure having an inner surface;a plurality of swirl vane
1. An aircraft control structure comprising: an engine nacelle comprising a downstream end, the engine nacelle comprising a nozzle structure defining a flow path and configured to exhaust a swirling fluid stream at a nozzle exit, the nozzle structure having an inner surface;a plurality of swirl vanes coupled to the nozzle structure, each having a generally airfoil shape, the plurality of swirl vanes movable relative to the nozzle structure between a deployed state and a non-deployed state, the plurality of swirl vanes cerate with a portion of the nozzle structure to define an outer surface of the nozzle structure in the non-deployed state; andan actuation subsystem configured to cause the plurality of swirl vanes to move from the deployed state to the non-deployed state;wherein, in the non-deployed state, the plurality of swirl vanes are substantially flush with the inner surface of the nozzle structure;wherein, in the deployed state, the plurality of swirl vanes extend radially substantially across the flow path, produce the swirling fluid stream and define a plurality of cut-outs through the nozzle structure; andwherein the plurality of swirl vanes are deployed to assist in drag management of the aircraft and an exit area of the nozzle exit is greater in the deployed state than in the non-deployed state. 2. The aircraft control structure of claim 1, wherein the nozzle structure is part of a bypass nozzle of a turbofan engine. 3. The aircraft control structure of claim 1, wherein the plurality of swirl vanes are hingedly coupled to the nozzle structure at a non-zero angle with respect to a centerline of the nozzle structure. 4. The aircraft control structure of claim 1, wherein the swirl vanes are incorporated into the nozzle structure such that at least a portion of each swirl vane has a thickness substantially equal to the nozzle structure. 5. A drag management system for an aircraft having a turbofan engine comprising an engine nacelle comprising a downstream end, the engine nacelle comprising a nozzle structure defining a flow path, the system comprising: a plurality of swirl vanes coupled to the nozzle structure configured to exhaust a swirling fluid stream at a nozzle exit, the plurality of swirl vanes being generally airfoil shaped and movable between a deployed state and a non-deployed state, the plurality of swirl vanes cooperate with a portion of the nozzle structure to define an outer surface of the nozzle structure in the non-deployed state, the plurality of swirl vanes define a plurality of cut-outs through the nozzle structure in the deployed state, and in the deployed state, the plurality of swirl vanes extend radially substantially across the flow path; andan actuation subsystem mechanically coupled to the plurality of swirl vanes and that moves the plurality of swirl vanes from the non-deployed state and the deployed state such that the plurality of swirl vanes assist in drag management of the aircraft;wherein the plurality of swirl vanes are configured to seat substantially flush with an inner surface of the nozzle structure when in the non-deployed state and at least a portion of each swirl vane has a thickness substantially equal to the nozzle structure and an exit area of the nozzle exit is greater in the deployed state Man in the non-deployed state. 6. The drag management system of claim 5, wherein the nozzle structure is part of a bypass nozzle of the turbofan engine. 7. The drag management system of claim 5, further including an inner nozzle structure, and wherein, while in the deployed state, the plurality of swirl vanes make contact with the inner nozzle structure. 8. The drag management system of claim 5, wherein the plurality of swirl vanes are hingedly coupled to the nozzle structure at a non-zero angle with respect to a centerline of the nozzle structure. 9. The drag management system of claim 5, wherein the swirl vanes are incorporated into an aft edge of the nozzle structure such that the aft edge has a tabbed structure when in the deployed state. 10. A method of providing drag management for an aircraft having a turbofan engine comprising an engine nacelle comprising a downstream end, the engine nacelle comprising a nozzle structure defining a flow path, the method comprising: providing a plurality of swirl vanes coupled to nozzle structure such that, in a non-deployed state, the plurality of swirl vanes are substantially flush with an inner surface of the nozzle structure and have a generally airfoil shape, the plurality of swirl vanes cooperating with a portion of the nozzle structure to define an outer surface of the nozzle structure in the non-deployed state; andmoving the plurality of swirl vanes from the non-deployed state to a deployed state, the plurality of swirl vanes extending radially substantially across the flow path and defining a plurality of cut-outs through the nozzle structure in the deployed state such that the plurality of swirl vanes produce a swirling fluid stream at a nozzle exit to assist in drag management of the aircraft and an exit area of the nozzle exit is greater in the deployed state than in the non-deployed state. 11. The method of claim 10, wherein the plurality of swirl vanes move to the deployed state such that the plurality of swirl vanes make contact with an inner nozzle structure that is provided within the nozzle structure.
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이 특허에 인용된 특허 (33)
Harrison, Richard George; Prendergast, Terry; Salkeld, Geoffrey; Holdcroft, Darren, Aircraft.
Kroll William B. (Roscoe IL) Curran Patrick D. (Rockford IL), Deployable vortex turbine for dissipating or extracting energy from a lift induced vortex emanating from an aircraft.
Dunbar Donald K. (Sharonville OH) Hess Paul J. (Cincinnati OH) Delaney Bobby R. (Loveland OH), Method of operating an aircraft bypass turbofan engine having variable fan outlet guide vanes.
Hanloser Kurt J. (North Palm Beach FL) Bruchez Raymond J. (Lake Park FL) Gill ; Jr. James T. (North Palm Beach FL), Partial swirl augmentor for a turbofan engine.
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