An aerofoil member is described which provides for a ‘smart Core’and flexible skin. The core comprises sheet material elements forming adjoining cells. The length of the elements can be changed, for example, using the piezo-electric effect, to alter the cross-sectional shape of the aerofoil without
An aerofoil member is described which provides for a ‘smart Core’and flexible skin. The core comprises sheet material elements forming adjoining cells. The length of the elements can be changed, for example, using the piezo-electric effect, to alter the cross-sectional shape of the aerofoil without changing the peripheral length. Thus, the shape of the aerofoil may be changed to suit different flight conditions, or to mimic the effect of control surfaces.
대표청구항▼
1. An aerofoil member, comprising a flexible outer skin supported by an inner structural core, the core comprising a plurality of sheet material elements joined together to form a matrix of adjoining cells, at least one of the elements comprising an actuator actuable to adjust at least one of a size
1. An aerofoil member, comprising a flexible outer skin supported by an inner structural core, the core comprising a plurality of sheet material elements joined together to form a matrix of adjoining cells, at least one of the elements comprising an actuator actuable to adjust at least one of a size or shape of at least one of the elements and adjust a cross-sectional shape of the aerofoil member, at least one of the elements at a periphery of the core joined to the skin. 2. The aerofoil member of claim 1, at least one of the elements formed of piezo-electric material, the actuator comprising electrodes. 3. The aerofoil member of claim 1, the flexible skin comprising a composite material. 4. The aerofoil member of claim 1, the flexible skin comprising a polyurethane material reinforced with at least one of glass or carbon fibers. 5. The aerofoil member of claim 1, the skin arranged such that at least one predetermined aerofoil shape corresponds to a default shape of the skin. 6. The aerofoil member of claim 1, at least one of the elements joined to the skin by a polypropylene material. 7. The aerofoil member of claim 1, at least one of the elements comprising one or more layers of laminated piezo-ceramic material. 8. A method of changing the cross-sectional shape of the aerofoil member of claim 1, comprising applying an actuator signal to the actuator to alter the cross-sectional shape without substantially changing a peripheral length of the aerofoil member. 9. The aerofoil member of claim 1, the matrix of adjoining cells comprising a three dimensional honeycomb structure. 10. The aerofoil member of claim 1, the actuator actuable based at least in part on a change in temperature. 11. The aerofoil member of claim 1, the matrix of adjoining cells comprising one or more dodecahedron structures. 12. A method for changing a cross-sectional shape of an aerofoil member, comprising: applying an electric current to one or more electrodes of an aerofoil member, the aerofoil member comprising an outer skin, and an inner core comprising a three dimensional honeycomb structure, the honeycomb structure comprising one or more sheet material elements joined together to form a matrix of adjoining cells, at least one of the sheet material elements comprising an actuator, the actuator comprising at least one of the electrodes, the applied electric current changing the cross-sectional shape such that a peripheral length of the aerofoil member is substantially unchanged. 13. The method of claim 12, comprising applying an electric current to electrodes corresponding to at least one of a top or bottom portion of the aerofoil member such that a shape of the aerofoil member changes to mimic an aileron. 14. The method of claim 12, comprising utilizing a control system to monitor the electric current applied. 15. The method of claim 12, comprising utilizing a control system to regulate the electric current applied. 16. The method of claim 12, at least one of the sheet material elements formed of piezo-electric materials.
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이 특허에 인용된 특허 (17)
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