Conversion of rotary to linear motion inside a linear actuator is accomplished through a threaded nut and lead screw. The inside of the rotor is threaded and the shaft is replaced by a lead screw. In order to generate linear motion the lead screw must be prevented from rotation. As the rotor turns the internal threads engage the lead screw resulting in linea.
ccurately controlled to drive 35mm movement by a 10K data pulses input. Accomplishing the conversion of rotary to linear motion inside the rotor greatly simplifies the process of delivering linear motion for many applications. Because the linear actuator is self-contained, the requirements for external components such as belts and pulleys are greatly reduced or eliminated. Fewer components make the design process easier, reduce overall system cost and size and improve product reliability. Application: Various valve intelligent controls, Telecommunication Tuning, as vell as other linear motion c.
No. | Partie # | Fabricant | Description | Fiche Technique |
---|---|---|---|---|
1 | 16HY7006-06 |
ETC |
Hybrid Stepper Motors | |
2 | 16HY7010 |
ETC |
Hybrid Stepper Motors | |
3 | 16HY0016 |
ETC |
Hybrid Stepper Motors | |
4 | 16HY0017 |
ETC |
Hybrid Stepper Motors | |
5 | 16HY0401 |
MotionKing |
2 Phase Hybrid Stepper Motor | |
6 | 16HY1005-04 |
ETC |
Hybrid Stepper Motors | |
7 | 16HY1006 |
ETC |
Hybrid Stepper Motors | |
8 | 16HY2410 |
MotionKing |
2 Phase Hybrid Stepper Motor | |
9 | 16HY3401 |
MotionKing |
2 Phase Hybrid Stepper Motor | |
10 | 16HY3402 |
MotionKing |
2 Phase Hybrid Stepper Motor | |
11 | 16HY3630 |
MotionKing |
2 Phase Hybrid Stepper Motor | |
12 | 16HY4401 |
MotionKing |
2 Phase Hybrid Stepper Motor |