Non-rotating wind energy generator

What is claimed is: 1. A non-rotating wind energy generating apparatus, comprising: a bluff body operable to initiate and sustain non-rotational oscillatory motion in response to wind energy; and an alternator system operable to generate electrical energy via the motion of the bluff body. 2. The non-rotating wind energy generating apparatus of claim 1 , wherein the bluff body comprises: a frame movably supporting at least one beam; one or more first springs; one or more second springs; wherein the one or more first springs attach a first portion of the frame to a first portion of the beam and the one or more second springs attach a second portion of the frame to a second portion of the beam such that the beam is suspended between the first and second portions of the frame; and wherein the alternator system comprises at least one electromagnetic coil attached to one of the beam or a third portion of the frame; at least one magnet attached to one of the third portion of the frame or the beam; wherein motion of the beam when exposed to wind causes the first electromagnetic coil to pass at least one magnet. 3. The non-rotating wind energy generating apparatus of claim 2 , wherein the beam has a D-shape. 4. The non-rotating wind energy generating apparatus of claim 2 , wherein the beam is hollow. 5. The non-rotating wind energy generating apparatus of claim 2 , further comprising one or more motion guides. 6. The non-rotating wind energy generating apparatus of claim 2 , further comprising: one or more additional beams; one or more additional upper springs; one or more additional lower springs; wherein the one or more additional upper springs attach a first portion of the additional beam to a third portion of the beam and the one or more additional lower springs attach a second portion of the additional beam to a fourth portion of the beam such that the one or more additional beams are suspended between the first and second portions of the frame. 7. The non-rotating wind energy generating apparatus of claim 2 , wherein the first portion of the frame is an upper portion, the first portion of the beam is an upper portion, the second portion of the frame is a lower portion, and the second portion of the beam is a lower portion. 8. The non-rotating wind energy generating apparatus of claim 2 , wherein the third portion of the frame is a side portion. 9. The non-rotating wind energy generating apparatus of claim 2 , wherein the beam is suspended substantially horizontally. 10. The non-rotating wind energy generating apparatus of claim 2 , wherein the motion of the beam is substantially vertical. 11. The non-rotating wind energy generating apparatus of claim 2 , wherein a surface of the beam is uniformly smooth. 12. The non-rotating wind energy generating apparatus of claim 2 , wherein a surface of the beam is partially smooth. 13. The non-rotating wind energy generating apparatus of claim 2 , wherein a surface of the beam is uniformly rough. 14. The non-rotating wind energy generating apparatus of claim 2 , wherein a surface of the beam is partially rough. 15. The non-rotating wind energy generating apparatus of claim 2 , wherein the at least one electromagnetic coil or the at least one magnet is attached to a first end of the beam. 16. The non-rotating wind energy generating apparatus of claim 2 , wherein the spring mass is selected to promote self-oscillatory motion. 17. The non-rotating wind energy generating apparatus of claim 2 , wherein the beam has a cross-sectional geometry selected from the group consisting of a square, a cylinder, a reversed D-Beam (where the wind is primarily incident on the round portion of the beam rather than the flat portion), and an equilateral wedge in either a “greater than” or “less than” orientation relative to the incident wind. 18. The non-rotating wind energy generating apparatus of claim 2 , wherein the springs are stretched in a resting state. 19. The non-rotating wind energy generating apparatus of claim 2 , wherein the beam mass is selected to promote self-oscillatory motion. 20. A method of generating electrical energy from wind energy comprising: exposing the non-rotating wind energy generating apparatus of claim 1 to wind to generate oscillatory motion in response to wind energy; and generating electrical energy via motion of the non-rotating wind energy generating apparatus using electromagnetic induction. 21. The non-rotating wind energy generating apparatus of claim 1 , wherein the alternator system comprises: at least one electromagnetic coil; at least one magnet; wherein motion of the bluff body when exposed to wind causes the first electromagnetic coil to pass the at least one magnet. 22. The non-rotating wind energy generating apparatus of claim 21 , wherein the at least one magnet is stationary and the at least one electromagnetic coil is moveable. 23. The non-rotating wind energy generating apparatus of claim 21 , wherein the at least one magnet is moveable and the at least one electromagnetic coil is stationary. 24. The non-rotating wind energy generating apparatus of claim 1 , wherein the bluff body is configured to oscillate based on at least one of vortex shedding and transverse galloping. 25. The non-rotating wind energy generating apparatus of claim 1 , further comprising at least one stop configured to limit a range of motion of the bluff body. 26. The non-rotating wind energy generating apparatus of claim 1 , wherein the bluff body comprises: a frame movably supporting at least one beam; one or more springs; wherein the one or more springs attach a portion of the frame to a portion of the beam; and wherein the one or more springs are configured to transmit energy. 27. The non-rotating wind energy generating apparatus of claim 26 , wherein the alternator system comprises at least one electromagnetic coil attached to the beam or the frame; and wherein the at least one electromagnetic coil attaches to the one or more springs at a first end of the one or more springs and the one or more springs attach to the other of the frame or the beam at a second end of the one or more springs such that the one or more springs transmit energy between the beam and the frame. 28. A method of generating electrical energy comprising: exposing a bluff body to wind to generate oscillatory motion in response to wind energy using at least one of vortex shedding and transverse galloping; and generating electrical energy via motion of the bluff body. 29. The method of claim 28 , comprising exposing the bluff body to wind to generate oscillatory motion in response to wind energy using vortex shedding and transverse galloping.