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A tethered model gyroglider having a fuselage, a rotor support extending upwardly from the fuselage, and a unitary two-bladed rotor rotatably mounted onto the rotor support. A teetering mechanism permits the rotor to pivot about an axis proximate the center of the rotor. When the gyroglider is subjected to a relative wind generally from a forward direction, the forward moving blade of the rotor is raised and the rearward moving blade is lowered. This equalizes the aerodynamic forces about the longitudinal axis of the fuselage, thereby eliminating the tendency of the gyroglider to roll in the direction of the rearward moving blade.

InventorAlex P. Kattas
Current U.S. Classification244/153.00A; 416/148; 446/36; D12/327
International Classification: B64C 3106

View patent at USPTO
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Citations

Cited PatentFiling dateIssue dateOriginal AssigneeTitle
US2035629Dec 5, 1934Mar 31, 1936BOOMERANG
US2168653Dec 8, 1937Aug 8, 1939TOY AIRPLANE
US2429502Aug 21, 1943Oct 21, 1947CAPTEVE HEEICOPTER-KFTE MEANS
US3194521Oct 19, 1962Jul 13, 1965RIDER ETAL KITE
US3233679Nov 19, 1963Feb 8, 1966ROTATING WING AIRCRAFT
US3669564Mar 26, 1970Jun 13, 1972COAXIAL HELICOPTER ROTOR SYSTEM AND TRANSMISSION THEREFOR
US4092084Jul 22, 1976May 30, 1978The South African Inventions Development Corporation of ScientiaRotor for an autogiro
US4131391Oct 4, 1976Dec 26, 1978Robinson Helicopter Co.Rotor hub and oil seal
US5149020Sep 26, 1991Sep 22, 1992Tethered rotary kite

Referenced by

Citing PatentFiling dateIssue dateOriginal AssigneeTitle
US5609312Aug 18, 1994Mar 11, 1997Model helicopter
US5836545Oct 11, 1996Nov 17, 1998Paul E. ArltonRotary wing model aircraft
US5996934Nov 24, 1997Dec 7, 1999Tethered autogyro
US6142419Mar 10, 1997Nov 7, 2000Landing gear assembly for a model helicopter
US6659395Jul 8, 2002Dec 9, 2003Rehco, LLCPropellers and propeller related vehicles
US6824093Dec 18, 2003Nov 30, 2004Rotary Air Force Management Inc.Method of controlling pitch on a gyroplane and a gyroplane
US7048232Nov 3, 2004May 23, 2006Plottner rotor kite
US7119665Nov 9, 2004Oct 10, 2006Sound generator for a kite
US7168657May 11, 2006Jan 30, 2007Toy helicopter landing skid structure
US7748486May 10, 2006Jul 6, 2010Honeywell International, Inc.Landing gear for a hovercraft
US8109802Sep 2, 2008Feb 7, 2012Mattel, Inc.Toy helicopter having a stabilizing bumper

Claims

1. A tethered model gyroglider comprising:

(a) a fuselage having a longitudinal axis with forward and rearward vectors;
(b) rotor support means for supporting a rotor for rotation in a mean plane above said fuselage, said rotor support means extending upwardly from said fuselage;
(c) a unitary two-bladed rotor rotatably mounted onto said rotor support means, said rotor rotating in said mean plane about a rotor axis;
(d) teeter means for permitting said rotor to pivot about a teeter axis generally parallel to said mean plane and generally perpendicular to said rotor proximate a center of said rotor such that, when the gyroglider is subjected to a relative wind generally along said rearward vector, a forward-moving blade of said rotor is raised and a rearward-moving blade of said rotor is lowered, thereby equalizing the aerodynamic forces about said longitudinal axis; and
(e) roll trim means for changing a lateral position of said rotor axis relative to said longitudinal axis of said fuselage, comprising:
(i) a bushing having first and second apertures said second aperture defining a bearing;
(ii) a mast extending upwardly from said fuselage and inserted into said first aperture; and
(iii) a rotatable shaft for supporting said rotor inserted into said bearing of said second aperture;
(iv) said bushing being pivotable about said mast to permit changing said lateral position of said rotor axis to trim the gyroglider about said longitudinal axis.

2. A tethered model gyroglider according to claim 1, wherein said teeter means comprise said rotatable shaft pivotally connected to a hub portion of said rotor for pivotal movement about said teeter axis.

3. A tethered model gyroglider according to claim 2, further comprising teeter limiting means for limiting the extent of the downward rotation of the rearward-moving blade and the upward rotation of the forward-moving blade to a predetermined number of degrees.

4. A tethered model gyroglider according to claim 3, wherein said teeter limiting means include a stop.

5. A tethered model gyroglider according to claim 4, wherein said stop comprises an aperture through the center of said rotor having opposite ends, wherein the extent of the downward rotation of the rearward-moving blade and the upward rotation of the forward-moving blade is limited by at least one of said opposite ends of said aperture impinging upon said shaft.

6. A tethered model gyroglider according to claim 5, wherein said rotor comprises at least one blade member and a hub member, said hub member including said aperture, said shaft extending through said aperture and being pivotally connected to said hub member above said rotor.

7. A tethered model gyroglider according to claim 1, wherein the pivotal position of said bushing is held in place by a friction fit between said mast and an inner wall of said first aperture of said bushing.

8. A tethered model gyroglider according to claim 7, wherein the extent of the pivotal rotation of said bushing about said mast is limited by a slot in a side of said mast and a pin extending through said bushing and said slot wherein, as said bushing is rotated in either direction, said pin impinges upon said mast, thereby limiting the extent of the rotation of said bushing to a predetermined number of degrees.

9. A tethered model gyroglider according to claim 1, wherein said second aperture of said bushing is defined by a bearing member fixedly held within said bushing, said rotatable shaft having an inner core member held at least partially within an outer sleeve member, with a bottom surface of said outer sleeve member being supported by a shaft supporting surface, and further including shaft retaining means for preventing said shaft from rising upwardly.

10. A tethered model gyroglider according to claim 9, wherein said bearing extends sufficiently above and below said bushing to prevent said bottom surface of said sleeve member from rubbing against an upper surface of said bushing and said shaft retaining means from rubbing against a lower surface of said bushing, respectively, thereby reducing the friction generated when said shaft is rotated.

11. A tethered model gyroglider according to claim 1, wherein said bushing is connected to said mast at a slight angle, such that said mean plane of rotation of said rotor is about between two to eight degrees upward relative to said forward vector of said fuselage.

12. A tethered model gyroglider according to claim 1, wherein each of the blades of said rotor includes at least one weight in an outer portion of said blades proximate a leading edge of said blades, thereby preventing said rotor from speeding up or slowing down excessively.

13. A tethered model gyroglider according to claim 1, the fuselage having a horizontal pitch axis perpendicular to said longitudinal axis, the gyroglider further including a horizontal stabilizer attached to said fuselage for providing stability about said pitch axis.

14. A tethered model gyroglider according to claim 1, the fuselage having a vertical yaw axis perpendicular to said longitudinal axis, the gyroglider further including a vertical stabilizer attached to said fuselage for providing stability about said yaw axis.

15. A tethered model gyroglider according to claim 2, wherein said rotor comprises at least one blade member and a hub member, said hub member being detachably connected to said rotatable shaft, thereby permitting replacement of said rotor.

16. A tethered model gyroglider according to claim 1, further comprising landing gear detachably connected to said fuselage, said landing gear being attachable to said fuselage in a first and a second orientation, wherein changing from said first to said second orientation varies the center of gravity of said gyroglider along said longitudinal axis, thereby affecting the longitudinal aerodynamic stability characteristics of said gyroglider.

17. A tethered model gyroglider according to claim 1, further comprising pitch limiting means for limiting the extent of the pitch rotation of the gyroglider when it is on the ground such that, when the gyroglider lands the tether can be pulled to rotate the gyroglider onto said pitch limiting means, thereby placing said mean plane of rotation of said rotor at an angle of attack relative to said relative wind appropriate to cause said gyroglider to regain flight.

18. A tethered model gyroglider comprising:

(a) a fuselage having a longitudinal axis;
(b) rotor support means for supporting a rotor above said fuselage, said rotor support means extending upwardly from said fuselage;
(c) a rotor rotatably mounted onto said rotor support means, said rotor rotating about a rotor axis;
(d) roll trim means for changing a lateral position of said rotor axis relative to said longitudinal axis of said fuselage, comprising:
(i) a bushing having an aperture defining a bearing;
(ii) a mast extending upwardly from said fuselage and pivotally connected to said bushing; and
(iii) a rotatable shaft for supporting said rotor inserted into said aperture;
(iv) said bushing being pivotable about said mast to permit changing said lateral position of said rotor axis to trim the gyroglider about said longitudinal axis.

Drawings