Solar tracker

Having thus described the invention, what is claimed as new and secured by Letters Patent is: 1. A system for tracking a sun to provide solar exposure to a solar device, the system comprising: an altitude motor for adjusting an altitude of the device; an azimuth motor for adjusting an azimuth of the device; a controller for controlling an activation and deactivation of said altitude motor and said azimuth motor; an altitude sensor for detecting solar exposure to the device, said altitude sensor being coupled to said controller; an azimuth sensor for detecting solar exposure to the device, said azimuth sensor being coupled to said controller; an altitude switch for reversing a polarity of said altitude motor, said altitude switch being activated when said device is at a solar noon position; an azimuth switch for reversing a polarity of said azimuth motor, said azimuth switch being activated when said device reaches an extreme azimuth position; a main supporting shaft for supporting said device; at least one torsion spring coupled to a supporting mechanism for said device, said at least one torsion spring being attached to said supporting mechanism such that said at least one torsion spring partially supports a weight of said device when said altitude of said device is being adjusted by said altitude motor, said at least one torsion spring being attached to a shaft perpendicular to a longitudinal axis of said main supporting shaft; wherein said controller activates and deactivates said altitude motor based on readings from said altitude sensor, said altitude motor being deactivated when said altitude sensor detects sufficient solar exposure for said device; said at least one torsion spring provides a braking force which alleviates an amount of torque needed from said altitude motor when said altitude of said device is being adjusted by said altitude motor, said at least one torsion spring stores energy as said device transitions from a horizontal position to a vertical position and said at least one torsion spring releases energy as said device transitions from said vertical position to said horizontal position; and said controller activates and deactivates said azimuth motor based on readings from said azimuth sensor, said azimuth motor being deactivated when said azimuth sensor detects sufficient solar exposure for said device. 2. A system according to claim 1 wherein said extreme azimuth position is a westernmost azimuth position for said device. 3. A system according to claim 1 wherein at least one of said azimuth switch and altitude switch is a software-activated switch. 4. A system according to claim 1 wherein at least one of said azimuth sensor and said altitude sensor is a photo sensor. 5. A system according to claim 1 wherein said solar device comprises at least one solar collector. 6. A system according to claim 1 wherein said solar device comprises at least one photo sensor. 7. A system according to claim 1 wherein said solar device comprises at least one solar shade. 8. A system according to claim 1 wherein said at least one torsion spring is adjustable to compensate for heavier solar devices. 9. A system according to claim 1 further comprising a single-axis slew drive, said single-axis slew drive being for adjusting either said altitude or said azimuth of said device. 10. A system according to claim 1 further comprising a dual-axis slew drive, said dual-axis slew drive being for adjusting at least one of said altitude or said azimuth of said device. 11. A system for tracking a sun to provide solar exposure to a solar device, the system comprising: an altitude motor for adjusting an altitude of the device; an azimuth motor for adjusting an azimuth of the device; a controller for controlling an activation and deactivation of said altitude motor and said azimuth motor; an altitude sensor for detecting solar exposure to the device, said altitude sensor being coupled to said controller; an azimuth sensor for detecting solar exposure to the device, said azimuth sensor being coupled to said controller; an altitude switch for reversing a polarity of said altitude motor, said altitude switch being activated when said device is at a solar noon position; an azimuth switch for reversing a polarity of said azimuth motor, said azimuth switch being activated when said device reaches an extreme azimuth position; wherein said controller activates and deactivates said altitude motor based on readings from said altitude sensor, said altitude motor being deactivated when said altitude sensor detects sufficient solar exposure for said device; said controller activates and deactivates said azimuth motor based on readings from said azimuth sensor, said azimuth motor being deactivated when said azimuth sensor detects sufficient solar exposure for said device; and wherein said system further comprises: a load compensation means coupled to a supporting mechanism for said device, said load compensation means being attached to said supporting mechanism such that said load compensation means partially supports a weight of said device when said altitude of said device is being adjusted by said altitude motor, said load compensation means providing a braking force which alleviates an amount of torque needed from said altitude motor when said altitude of said device is being adjusted by said altitude motor, said load compensation means being at least one of: at least one torsion spring; at least one torsion bar; and a plurality of springs; wherein said load compensation means is attached to a shaft that is perpendicular to a longitudinal axis of a main supporting shaft of said system and wherein: said load compensation means stores energy as said device transitions from a horizontal position to a vertical position; said load compensation means releases energy as said device transitions from a vertical position to a horizontal position. 12. A system according to claim 11 wherein said load compensation means comprises a plurality of torsion springs arranged in a series configuration. 13. A system according to claim 11 wherein said load compensation means comprises a plurality of torsion springs arranged in a parallel configuration. 14. A system according to claim 11 wherein said load compensation means comprises a plurality of torsion springs arranged in a combination of series and parallel configurations. 15. A system according to claim 11 further comprising a single-axis slew drive, said single-axis slew drive being for adjusting either said altitude or said azimuth of said device. 16. A system according to claim 11 further comprising a dual-axis slew drive, said dual-axis slew drive being for adjusting at least one of said altitude or said azimuth of said device.