Systems and methods for damping photovoltaic panel arrays

The invention claimed is: 1. A damper for reducing vibrations in a rotatable photovoltaic panel array, wherein the damper is configured to provide a first damping force during slow movement of the photovoltaic array and a second damping force during fast movement of the array, the second damping force being greater than the first damping force, the damper comprising: a housing having proximal and distal ends; a first attachment point proximate the distal end of the housing; a rod having proximal and distal ends at least partially disposed within the housing and moveable relative to the housing between an extended position and a compressed position; a second attachment point proximate the proximal end of the rod; a piston joined to the rod within the housing proximate the distal end of the rod, the piston including a bypass groove having a flow area defined therein to allow fluid to flow from a first side of the piston to an opposing side of the piston; and a first washer disposed proximate a first end of the piston and at least partially covering the flow area of the bypass groove, the first washer configured to deflect to uncover the flow area of the bypass groove at a selected maximum damping force such that the damper assembly is configured to apply no more than the selected maximum damping force. 2. The damper of claim 1 , wherein the first attachment point is configured to attach to a torque arm of a rotatable photovoltaic panel array, and the second attachment point is configured to attach to a non-rotatable support member of the photovoltaic array. 3. The damper of claim 1 , wherein the piston includes a second bypass groove having a flow area defined therein to allow fluid to flow from a first side of the piston to an opposing side of the piston and a second washer disposed proximate a second end of the piston and at least partially covering the flow area of the second bypass groove, the second washer configured to deflect to uncover the flow area of the second bypass groove at the selected maximum damping force. 4. The damper of claim 1 , wherein the first and second attachment points each comprise hardened steel ball studs. 5. The damper of claim 1 , wherein the damper provides similar damping forces during compression and extension of the rod. 6. The damper of claim 1 , further comprising a bottom valve disposed within the housing. 7. The damper of claim 1 , further comprising an external wiper seal proximate the proximal end of the housing. 8. The damper of claim 1 , wherein an outer surface of the housing comprises a corrosion and scratch-resistant coating. 9. The damper of claim 1 , wherein a sealing ring is disposed about the piston to prevent or inhibit flow of fluid about the piston. 10. The damper of claim 1 , further comprising a fluid disposed within the housing, wherein the fluid comprises a biodegradable oil. 11. A rotatable photovoltaic panel assembly including a damper for reducing vibrations in a photovoltaic panel, comprising: a photovoltaic panel configured to rotate to maintain alignment with the sun; and a damper attached to the photovoltaic panel such that rotation of the photovoltaic panel translates into a linear movement of the damper, wherein the damper is configured to provide a first damping force during slow movement of the photovoltaic array and a second damping force during fast movement of the array, the second damping force being greater than the first damping force, the damper further comprising: a housing having proximal and distal ends; a first attachment point proximate the distal end of the housing; a rod having proximal and distal ends at least partially disposed within the housing and moveable relative to the housing between an extended position and a compressed position; a second attachment point proximate the proximal end of the rod; a piston joined to the rod within the housing proximate the distal end of the rod, the piston including a bypass groove having a flow area defined therein to allow fluid to flow from a first side of the piston to an opposing side of the piston; and a first washer disposed proximate a first end of the piston and at least partially covering the flow area of the bypass groove, the first washer configured to deflect to uncover the flow area of the bypass groove at a selected maximum damping force such that the damper assembly is configured to apply no more than the selected maximum damping force. 12. The apparatus of claim 11 , wherein the first damper attachment point is attached to a torque arm of a rotatable photovoltaic panel, and the second damper attachment point is attached to a non-rotatable support member of the rotatable photovoltaic panel. 13. The apparatus of claim 11 , wherein the piston includes a second bypass groove having a flow area defined therein to allow fluid to flow from a first side of the piston to an opposing side of the piston and a second washer disposed proximate a second end of the piston and at least partially covering the flow area of the second bypass groove, the second washer configured to deflect to uncover the flow area of the second bypass groove at the selected maximum damping force. 14. The apparatus of claim 11 , wherein the damper provides similar damping forces during compression and extension of the rod. 15. The apparatus of claim 11 , wherein a plurality of dampers are attached to the solar panel such that rotation of the solar panel translates into a linear movement of each damper. 16. The apparatus of claim 11 , further comprising a fluid disposed within the housing, wherein the fluid comprises a biodegradable oil. 17. A method for reducing vibrations in a rotatable photovoltaic panel array, the method comprising: attaching a damper to a rotatable photovoltaic panel array such that a first damper attachment point moves with the rotatable photovoltaic panel array, and a second damper attachment point does not move with the rotatable photovoltaic array, wherein the damper is configured to provide a first damping force during slow movement of the photovoltaic array and a second damping force during fast movement of the array, the second damping force being greater than the first damping force, the damper comprising: a housing having proximal and distal ends; a first attachment point proximate the distal end of the housing; a rod having proximal and distal ends at least partially disposed within the housing and moveable relative to the housing between an extended position and a compressed position; a second attachment point proximate the proximal end of the rod; a piston joined to the rod within the housing proximate the distal end of the rod, the piston having a including a bypass groove having a flow area defined therein to allow fluid to flow from a first side of the piston to an opposing side of the piston; and a first washer disposed proximate a first end of the piston and at least partially covering the flow area of the bypass groove, the first washer configured to deflect to uncover the flow area of the bypass groove at a selected maximum damping force such that the damper assembly is configured to apply no more than the selected maximum damping force. 18. The method of claim 17 , wherein the first damper attachment point is attached to a torque arm of a rotatable photovoltaic panel, and the second damper attachment point is attached to a non-rotatable support member of the rotatable photovoltaic panel. 19. The method of claim 17 , wherein the piston includes a second bypass groove having a flow are