초록 ▼

A telescoping mast able to efficiently extend and retract multiple telescoping sections without jar and minimal energy. The telescoping mast has multiple telescoping sections, a position feedback sensor, a motor, a spring motor, and a computation unit. The position feedback sensor is coupled to at l

A telescoping mast able to efficiently extend and retract multiple telescoping sections without jar and minimal energy. The telescoping mast has multiple telescoping sections, a position feedback sensor, a motor, a spring motor, and a computation unit. The position feedback sensor is coupled to at least one telescoping section and configured to identify a position of the telescoping sections. The motor is also coupled to the telescoping sections, and raises and lowers the telescoping sections. The computation unit controls the motor based on the position of the telescoping sections.

대표청구항 ▼

1. A telescoping mast comprising: a plurality of telescoping sections;a position feedback sensor coupled to at least one telescoping section, configured to identify a position of the telescoping sections;a motor coupled to the telescoping sections, and configured to extend and retract the telescopin

1. A telescoping mast comprising: a plurality of telescoping sections;a position feedback sensor coupled to at least one telescoping section, configured to identify a position of the telescoping sections;a motor coupled to the telescoping sections, and configured to extend and retract the telescoping sections;a computation unit configured to control the motor based on the position of the telescoping sections:wherein the motor is coupled to the telescoping sections via a drive shaft; anda spring motor, coupled to the drive shaft, configured to rotate the drive shaft and store mechanical energy. 2. The telescoping mast of claim 1, wherein the motor is an electric motor. 3. The telescoping mast of claim 2, further comprising: an electrical energy storage unit, coupled to the electric motor, configured to supplement electrical power to the electric motor. 4. The telescoping mast of claim 3, wherein the computation unit further comprises: an application interface configured to read a set position input from a user of the telescoping mast. 5. The telescoping mast of claim 4, wherein the computation unit further comprises: a position monitor configured to receive the position of the telescoping sections from the position feedback sensor. 6. The telescoping mast of claim 5, wherein the computation unit further comprises: a drive control unit configured to decelerate the motor when the position of the telescoping sections is close to the set position, and accelerate the motor when the position of the telescoping sections is not close to the set position. 7. The telescoping mast of claim 6, further comprising: a receiver configured to receive the user interface image from an external source. 8. The telescoping mast of claim 7, further comprising: a payload. 9. The telescoping mast of claim 8, wherein the payload is a camera. 10. The telescoping mast of claim 8, wherein the payload is a radio-frequency antenna. 11. A method of raising or lowering a telescoping mast, comprising: receiving a set position input from a user of the telescoping mast via an application interface;reading an actual position of the telescoping mast via a position feedback sensor;decelerating a motor when the actual position of the telescoping mast is close to the set position, the motor being coupled to the telescoping sections via a drive shaft, and with a spring motor, coupled to the drive shaft, configured to rotate the drive shaft and store mechanical energy;accelerating the motor when the actual position of the telescoping mast is not close to the set position; andstopping the motor when the actual position of the telescoping mast is the set position. 12. The method of claim 11, wherein the motor is an electric motor. 13. The method of claim 12, the telescoping mast further comprising: an electrical energy storage unit, coupled to the electric motor, configured to supplement electrical power to the electric motor. 14. The method of claim 13, the telescoping mast further comprising: a payload. 15. The method of claim 14, wherein the payload is a camera. 16. The method of claim 15, wherein the payload is a radio-frequency antenna. 17. A computer-readable medium configured to raise or lower a telescoping mast, encoded with data and instructions, such that when executed by a device, the instructions causes the device to: receive a set position input from a user of the telescoping mast via an application interface;read an actual position of the telescoping mast via a position feedback sensor;decelerate a motor when the actual position of the telescoping mast is close to the set position, the motor being coupled to the telescoping sections via a drive shaft, and with a spring motor, coupled to the drive shaft, configured to rotate the drive shaft and store mechanical energy;accelerate the motor when the actual position of the telescoping mast is not close to the set position; andstop the motor when the actual position of the telescoping mast is the set position. 18. The computer-readable medium of claim 17, wherein the motor is an electric motor. 19. The computer-readable medium of claim 18, the telescoping mast further comprising: an electrical energy storage unit, coupled to the electric motor, configured to supplement electrical power to the electric motor. 20. The computer-readable medium, of claim 19, the telescoping mast further comprising: a payload. 21. The computer-readable medium of claim 20, wherein the payload is a camera. 22. The computer-readable medium of claim 21, wherein the payload is a radio-frequency antenna.