System and method for converting fluid motion into electrical power

What is claimed is: 1. A system for converting fluid motion into electrical power, the system being deployable in a body of fluid and comprising: a support structure including a generator assembly configured to convert mechanical energy to electrical energy and provide electric power from the electrical energy; and a movable structure connected to the support structure and including a canopy coupled to and extending from a base, the canopy including first and second opposing major surfaces joined by first and second opposing minor surfaces, the movable structure being configured to generate mechanical energy for conversion by the generator assembly during a power generation phase of a power cycle in which the fluid motion acts on the movable structure, the movable structure having three or more degrees of freedom, wherein the movable structure has a first configuration during the power generation phase in which the canopy is arranged with the first major surface facing a direction of fluid motion, the first minor surface extending out from the base by the first and second major surfaces, and the second minor surface held against or proximate the base, wherein the movable structure is reconfigurable from the first configuration to a second, different configuration for a recovery phase of the power cycle in which the movable structure has a lesser surface area normal to the flow of fluid than the movable structure in the first configuration, wherein reconfiguration of the movable structure includes the first minor surface being caused by the fluid motion to move in the direction of fluid motion and then downward toward the base, and the second minor surface being caused to move along the base opposite the direction of fluid motion, until the canopy lies approximately against the base, at which point the movable structure is in the second configuration, wherein the body of fluid has a surface generally perpendicular to a first axis and parallel with second and third axes of a Cartesian coordinate system, and in which the fluid motion has one or more of a first-axis component, second-axis component or third-axis component, and wherein the support structure includes a swivel structure configured to swivel relative to the support structure and thereby permit movement of the movable structure with the second-axis component and third-axis component of the fluid motion, the swivel structure being configured to swivel with the direction of fluid motion and independent of movement of the movable structure away from the support structure. 2. The system of claim 1 , wherein the movable structure is connected to the generator assembly by a cable that allows movement of the movable structure away from the support structure during the power generation phase, and that allows movement of the movable structure back to the support structure during the recovery phase. 3. The system of claim 1 , wherein the support structure further includes a pivotable guide structure configured to pivot and thereby permit movement of the movable structure with the first-axis component of the fluid motion. 4. The system of claim 1 , wherein the system is deployable underneath a surface of the body of fluid, the system further comprising: a buoy to which the support structure is tethered, the buoy being configured to hold the support structure upright when deployed. 5. The system of claim 2 , wherein the generator assembly includes a spool around which the cable is unwound and wound during respectively the power generation phase and recovery phase, the spool being rotatable about an axis coplanar with the second-axis component and third-axis component of the fluid motion. 6. A method for converting fluid motion into electrical power comprising: providing a system including movable structure connected to a support structure that includes a swivel structure, the movable structure including a canopy coupled to and extending from a base, the canopy including first and second opposing major surfaces joined by first and second opposing minor surfaces, the system being deployed in a body of fluid; generating mechanical energy by the movable structure in reaction to fluid motion acting on the movable structure during a power generation phase of a power cycle, the movable structure having three or more degrees of freedom; converting the mechanical energy to electrical energy and providing electric power from the electrical energy; and reconfiguring the movable structure from a first configuration in which the canopy is arranged with the first major surface facing a direction of fluid motion, the first minor surface extending out from the base by the first and second major surfaces, and the second minor surface held against or proximate the base, the movable structure being reconfigured from the first configuration to a second, different configuration for a recovery phase of the power cycle in which the movable structure has a lesser surface area normal to the flow of fluid than the movable structure in the first configuration, wherein reconfiguring the movable structure includes the fluid motion causing the first minor surface to move in the direction of fluid motion and then downward toward the base, and the second minor surface being caused to move along the base opposite the direction of fluid motion, until the canopy lies approximately against the base, at which point the movable structure is in the second configuration, wherein the body of fluid has a surface generally perpendicular to a first axis and parallel with second and third axes of a Cartesian coordinate system, and in which the fluid motion has one or more of a first-axis component, second-axis component or third-axis, and wherein generating the mechanical energy includes swiveling of the swivel structure relative to the support structure and thereby movement of the movable structure with the second-axis component and third-axis component of the fluid motion, and movement away from the support structure, the swivel structure swiveling with the direction of fluid motion and independent of movement of the movable structure away from the support structure. 7. The method of claim 6 , wherein generating the mechanical energy includes movement of the movable structure away from the support structure, the movable structure being connected to the support structure by a cable that allows the respective movement. 8. The method of claim 7 further comprising pulling the movable structure back to the support structure by the cable during the recovery phase. 9. The method of claim 6 , wherein the support structure further includes a pivotable guide structure, and wherein generating the mechanical energy further includes pivoting of the pivotable guide structure and thereby movement of the movable structure with the first-axis component of the fluid motion. 10. The method of claim 6 further comprising: deploying the system underneath a surface of the body of fluid, the system further including a buoy to which the support structure is tethered, the buoy being configured to hold the support structure upright when deployed.