Wind drive apparatus for an aerial wind power generation system

1. Wind driven apparatus for an aerial power generation system for generation of power from the wind, comprising:

a driven element including a trapezoidal sail portion, an upper spar, a spaced lower spar, and a plurality of spaced battens, said driven element having a high force configuration and a low force configuration, a pitch angle and an azimuth angle, said driven element having, when in said high force configuration, an airfoil shape, said sail portion having a leading edge, a trailing edge, and a camber, said upper spar being connected to and extending laterally along said leading edge of said sail portion, said lower spar being connected to and extending laterally along said trailing edge of said sail portion, and said battens being connected to and extending longitudinally along said sail portion for flattening said sail portion,

means, connected to said sail portion, for changing said driven element between said high force and low force configurations while in flight, and

means for controlling said camber of said sail portion while said sail portion is in flight,

whereby said camber is increased when said driven element is in a high force configuration and said driven element is flattened when said sail portion is in a low force configuration, and whereby said means for changing changes said sail portion to a said high force configuration to generate power, and said means for changing changes said sail portion to a said low force configuration to pull said sail portion upwind.

2. The apparatus as set forth in claim 1 wherein said means for changing includes a first tow line connected to said upper spar and a second tow line connected to said lower spar,

whereby said means for changing effectively shortens and lengthens said second tow line relative to said first tow line to change said driven element between high force and low force configurations.

3. The apparatus as set forth in claim 2 wherein said means for changing includes a remote control winch mounted on said first tow line and spaced from said upper spar, said winch being connected to said second tow line opposite said lower spar,

whereby said winch effectively shortens and lengthens said second tow line relative to said first tow line to change said driven element between high force and low force configurations.

4. The apparatus as set forth in claim 1 wherein said means for changing changes said pitch angle to change said sail portion between high force and low force configurations.

5. The apparatus as set forth in claim 4 wherein said means for changing includes a remote control airfoil connected to one of said upper and lower spars,

whereby said airfoil raises and lowers said spar to change said pitch angle to change said driven element between high force and low force configurations.

6. The apparatus as set forth in claim 1 wherein said means for controlling includes at least one remote control winch mounted on one of said upper and lower spars, and said winch includes a tension line connected to said other one of said upper and lower spars,

whereby effectively shortening said tension line with said winch increases said camber and effectively lengthening said tension line flattens said sail portion.

7. The apparatus as set forth in claim 1:

including a plurality of upper bridle lines that connect at one end in a spaced arrangement to said upper spar, and a plurality of lower bridle lines that connect at one end in a spaced arrangement to said lower spar, and

wherein said means for controlling includes a plurality of intermediate bridle lines that each connect at one end to said sail portion intermediate said upper and lower spars and connect at the opposite end to one of said lower bridle lines intermediate the ends of said lower bridle line, said intermediate bridle lines each having a selected length to limit said camber to a selected maximum camber when said driven element is in a high force configuration.

8. The apparatus as set forth in claim 1 wherein said means for controlling includes a remote control airfoil connected to one of said upper and lower spars,

whereby said airfoil raises and lowers said spar to control said camber.

9. The apparatus as set forth in claim 1 including means for adjusting said azimuth angle.

10. The apparatus as set forth in claim 9 wherein said means for adjusting includes first and second control lines connected near opposite ends of one of said upper and lower spars,

whereby said azimuth angle is adjusted by differential effective lengthening and shortening of said first and second control lines.

11. The apparatus as set forth in claim 10 wherein said means for adjusting includes a winch connected to said first control line opposite said one of said upper and lower spars for differential effective lengthening and shortening of said first and second control lines.

12. The apparatus as set forth in claim 9 wherein said means for adjusting includes remote control first and second winches mounted on opposite ends of one of said upper and lower spars, and first and second tension lines attached to said first and second winches, respectively, and connecting to opposite ends of said other one of said upper and lower spars,

whereby differential effective lengthening and shortening of said first and second tension lines creates differential camber in said sail portion and thereby adjusts said azimuth angle.

13. The apparatus as set forth in claim 9 wherein said means for adjusting includes spaced, remote control first and second airfoils attached at opposite ends of one of said upper and lower spars,

whereby differential adjustment of said first and second airfoils adjusts said azimuth angle.

14. Wind driven apparatus for an aerial power generation system for generation of power from the wind, comprising:

a driven element including a trapezoidal sail portion, an upper spar, a spaced lower spar, and a plurality of spaced battens, said driven element having a high force configuration and a low force configuration, a pitch angle and an azimuth angle, said driven element having, when in said high force configuration, an airfoil shape, said sail portion having a leading edge, a trailing edge, and a camber, said upper spar being connected to and extending laterally along said leading edge of said sail portion, said lower spar being connected to and extending laterally along said trailing edge of said sail portion, and said battens being connected to and extending longitudinally along said sail portion for flattening said sail portion,

means, connected to said driven element, for changing said driven element between said high force and low force configurations while in flight,

means for controlling said camber of said sail portion while said driven element is in flight, and

means for adjusting said azimuth angle,

whereby said means for changing changes said driven element to a said high force configuration to generate power, and said means for changing changes said driven element to a said low force configuration to pull said driven element upwind.

15. Wind driven apparatus for an aerial power generation system for generation of power from the wind, comprising:

a driven element including a sail portion, a lower spar, and a plurality of spaced battens, said driven element having a high force configuration and a low force configuration, a pitch angle and an azimuth angle, said driven element having, when in said high force configuration, an airfoil shape, said sail portion having a leading edge, a trailing edge, and a camber, said lower spar being connected to and extending laterally along said trailing edge of said sail portion, and said battens being connected to said sail portion and extending transverse to said lower spar for flattening said sail portion,

means, connected to said driven element, for changing said driven element between said high force and low force configurations while in flight,

means for controlling said camber of said sail portion while in flight, and

means for adjusting said azimuth angle,

whereby said means for changing changes said driven element to a said high force configuration to generate power, and said means for changing changes said driven element to a said low force configuration to pull said driven element upwind.

16. The apparatus as set forth in claim 15 wherein said sail portion has a substantially triangular shape.

17. The apparatus as set forth in claim 15 wherein said means for adjusting includes spaced, independently controlled first and second control lines connected to opposite ends of said lower spar.

18. The apparatus as set forth in claim 15 wherein:

said means for changing includes a leading edge control line that connects to said leading edge,

said means for adjusting includes a first trailing edge control line that connects to one end of said lower spar and a spaced second trailing edge control line that connects to the other end of said lower spar, and

said means for controlling includes a plurality of intermediate bridle lines that each connect at one end to said sail portion intermediate said leading edge and said lower spar and connect at the opposite end to one of said first and second trailing edge control lines, said intermediate bridle lines each having a selected length to limit said camber to a selected maximum camber when said driven element is in a high force configuration.

19. The apparatus as set forth in claim 15 wherein said means for controlling includes a remote control winch mounted on said lower spar, and said winch includes a tension line connected to said leading edge,

whereby effectively shortening said tension line with said winch increases said camber and effectively lengthening said tension line flattens said sail portion.

20. Wind driven apparatus for an aerial power generation system for generation of power from the wind, comprising:

a driven element including a sail portion, a lower spar, and a plurality of spaced battens, said driven element having a high force configuration and a low force configuration, a pitch angle and an azimuth angle, said driven element having, when in said high force configuration, an airfoil shape, said sail portion having a leading edge, a trailing edge, and a camber, said lower spar being connected to and extending laterally along said trailing edge of said sail portion, and said battens being connected to said sail portion and extending transverse to said lower spar for flattening said sail portion,

a leading edge control line that connects to said leading edge, for changing said driven element between high force and low force configurations while said sail portion is in flight, a first trailing edge control line that connects to one end of said lower spar and a spaced second trailing edge control line that connects to the other end of said lower spar, for adjusting said azimuth angle, and

a plurality of intermediate bridle lines that each connect at one end to said sail portion intermediate said leading edge and said lower spar and connect at the opposite end to one of said first and second trailing edge control lines, said intermediate bridle lines each having a selected length to limit said camber to a selected maximum camber when said driven element is in a high force configuration,

whereby said leading edge control line changes said driven element to said high force configuration to generate power, and said leading edge control line changes said driven element to said low force configuration to pull said driven element upwind, said first and second trailing edge control lines adjust said azimuth angle, and said intermediate bridle lines control said camber.