Morphing segmented wind turbine and related method

We claim: 1. A rotor blade for a wind turbine, said blade comprising: a plurality of blade segments for use as part of a rotor; each of said plurality of blade segments comprising an internal passage extending longitudinally from a first end to a second end of each of said blade segments; a plurality of spar members extending longitudinally through said internal passages of each of said blade segments such that said plurality of said spar members are aligned and in communication end-to-end through said internal passages and said plurality of blade segments are aligned and in communication with said aligned spar members and define a complete rotor blade from a root that connects to a rotor hub to a blade tip of said rotor blade; a tension member extending longitudinally through said aligned spar members, said tension member configured to exert a force longitudinally toward said rotor hub to establish a first pitch configuration of said plurality of blade segments in the absence of centrifugally-induced rotation of said blade segments about an axis of said longitudinally-extending plurality of spar members; wherein said aligned spar members are configured to rotate relative to one another about said axis in response to centrifugal forces exerted on said blade segments and said aligned spar members due to a prevailing wind, and in response, said blade segments are configured to rotate relative to one another to establish a second pitch configuration. 2. The rotor blade of claim 1 , wherein said tension member comprises at least one of the following: cable, rod, chain, or rope. 3. The rotor blade of claim 1 , wherein said first pitch configuration includes a higher angle of attack for said plurality of blade segments as compared to said second pitch configuration. 4. The rotor blade of claim 3 , wherein the second pitch configuration includes an angle of attack below a stall threshold for said plurality of blade segments. 5. The rotor blade of claim 1 , wherein said communication of said plurality of spar members includes a threaded coupling between adjacent spar members. 6. The rotor blade of claim 1 , wherein said rotation of said plurality of spar members relative to one another induces gaps between adjacent blade segments; and wherein the rotor blade of claim 1 further comprises at least one sheath configured to cover said induced gaps between adjacent blade segments. 7. The rotor blade of claim 6 , wherein the sheath is elastomeric. 8. The rotor blade of claim 1 , wherein a cross section of each of said spar members is circular. 9. A method of manufacturing a rotor blade for a wind turbine, said method comprising: providing a plurality of blade segments for use as part of a rotor; each of said plurality of blade segments comprising an internal passage extending longitudinally from a first end to a second end of each of said blade segments; providing a plurality of spar members extending longitudinally through said internal passages of each of said blade segments such that said plurality of said spar members are aligned and in communication end-to-end through said internal passages and said plurality of blade segments are aligned and in communication said aligned spar members and define a complete rotor blade from a root that connects to a rotor hub to a blade tip of said rotor blade; providing a tension member extending longitudinally through said aligned spar members, said tension member configured to exert a force longitudinally toward said rotor hub to establish a first pitch configuration of said plurality of blade segments in the absence of centrifugally-induced rotation of said blade segments about an axis of said longitudinally-extending plurality of spar members; and wherein said aligned spar members are configured to rotate relative to one another about said axis in response to centrifugal forces exerted on said blade segments and said aligned spar members due to a prevailing wind, and in response, said blade segments are configured to rotate relative to one another to establish a second pitch configuration. 10. The method of claim 9 , wherein said first pitch configuration includes a higher angle of attack for said plurality of blade segments as compared to said second pitch configuration. 11. The method of claim 10 , wherein the second pitch configuration includes an angle of attack below a stall threshold for said plurality of blade segments. 12. The method of claim 9 , wherein said communication of said plurality of spar members includes a threaded coupling between adjacent spar members. 13. The method of claim 9 , wherein said rotation of said plurality of spar members relative to one another induces gaps between adjacent blade segments; and wherein the rotor blade further comprises at least one sheath configured to cover said induced gaps between adjacent blade segments. 14. The method of claim 9 , wherein said tension member comprises at least one of the following: cable, rod, chain, or rope. 15. A rotor blade kit for forming rotor blade on a wind turbine, said kit comprising: a plurality of blade segments for use as part of a rotor; each of said plurality of blade segments comprising an internal passage extending longitudinally from a first end to a second end of each of said blade segments; a plurality of spar members for extending longitudinally through said internal passages of each of said blade segments such that said plurality of said spar members are aligned and in communication end-to-end through said internal passages and said plurality of blade segments are aligned and in communication said aligned spar members and define a complete rotor blade from a root that connects to a rotor hub to a blade tip of said rotor blade; a tension member for extending longitudinally through said aligned spar members, said tension member configured to exert a force longitudinally toward said rotor hub to establish a first pitch configuration of said plurality of blade segments in the absence of centrifugally-induced rotation of said blade segments about an axis of said longitudinally-extending plurality of spar members; and wherein said aligned spar members are configured to rotate relative to one another about said axis in response to centrifugal forces exerted on said blade segments and said aligned spar members due to a prevailing wind, and in response, said blade segments are configured to rotate relative to one another to establish a second pitch configuration. 16. The rotor blade kit of claim 15 , wherein said first pitch configuration includes a higher angle of attack for said plurality of blade segments as compared to said second pitch configuration. 17. The rotor blade kit of claim 16 , wherein the second pitch configuration includes an angle of attack below a stall threshold for said plurality of blade segments. 18. The rotor blade kit of claim 15 , wherein said communication of said plurality of spar members includes a threaded coupling between adjacent spar members. 19. The rotor blade kit of claim 15 , wherein said rotation of said plurality of spar members relative to one another induces gaps between adjacent blade segments; and wherein the rotor blade kit further comprises at least one sheath configured to cover said induced gaps between adjacent blade segments. 20. The rotor blade kit of claim 15 , wherein said tension member comprises at least one of the following: cable, rod, chain, or rope.