Claims
- 1. An absolute sensor comprising:
a high speed rotational shaft; a planetary gear mechanism for reducing a high rotational speed delivered from the high speed rotational shaft; a low speed rotational shaft which is aligned coaxially with the high speed rotational shaft and to which is delivered a reduced speed rotation from the planetary gear mechanism; a high speed side encoder for detecting a rotational speed or rotational angle of the high speed rotational shaft; and a low speed side encoder for detecting a rotational speed or rotational angle of the low speed rotational shaft; the planetary gear mechanism has a fixed sun internal gear, a front stage planetary gear, a rear stage planetary gear which rotates integrally with the front stage planetary gear, and an output sun internal gear engaged with the rear stage planetary gear; and the front stage and rear stage planetary gears are rotatably supported by an eccentric shaft portion formed on the high speed rotational shaft and are maintained in a condition engaged with the fixed sun and output sun internal gears, and the output sun internal gear is connected to the low speed rotational shaft, whereby an absolute rotational angle of the low speed or high speed rotational shaft is detected based on outputs of the high speed side and low speed side encoders.
- 2. The absolute sensor of claim 1, wherein the rear stage planetary gear and the output sun internal gear are a scissors-type composite gear.
- 3. The absolute sensor of claim 1, further comprising an annular body, and the fixed sun internal gear is fixed to an internal surface of the annular body.
- 4. The absolute sensor of claim 3, further comprising a bearing between the internal surface of the annular body and the output sun internal gear, and the output sun internal gear is rotatably supported by the bearing.
- 5. The absolute sensor of claim 1, wherein the planetary gear mechanism has a reduction ration of 256.
- 6. The absolute sensor of claim 1, wherein the planetary gear mechanism has a reduction ration of 512.
- 7. The absolute sensor of claim 1, wherein the planetary gear mechanism has a reduction ration of 1024.
- 8. The absolute sensor of claim 1, wherein the planetary gear mechanism has a reduction ration which is a power of 2.
- 9. The absolute sensor of claim 1, wherein the high speed side encoder is for detecting a rotational speed of the high speed rotational shaft.
- 10. The absolute sensor of claim 9, wherein the low speed side encoder is for detecting a rotational speed of the low speed rotational shaft.
- 11. The absolute sensor of claim 1, wherein the high speed side encoder is for detecting a rotational angle of the high speed rotational shaft.
- 12. The absolute sensor of claim 9, wherein the low speed side encoder is for detecting a rotational angle of the low speed rotational shaft.
- 13. The absolute sensor of claim 10, further comprising an annular body, and the fixed sun internal gear is fixed to an internal surface of the annular body.
- 14. The absolute sensor of claim 13, further comprising a bearing between the internal surface of the annular body and the output sun internal gear, and the output sun internal gear is rotatably supported by the bearing.
- 15. The absolute sensor of claim 10, wherein the planetary gear mechanism has a reduction ration of 256.
- 16. The absolute sensor of claim 10, wherein the planetary gear mechanism has a reduction ration of 512.
- 17. The absolute sensor of claim 10, wherein the planetary gear mechanism has a reduction ration of 1024.
- 18. The absolute sensor of claim 10, wherein the planetary gear mechanism has a reduction ration which is a power of 2.
- 19. The absolute sensor of claim 12, wherein the planetary gear mechanism has a reduction ration which is a power of 2.
- 20. A method of determining an absolute rotational angle, the method comprising the steps of:
delivering a rotational force to a high speed rotational shaft; transferring the rotational force from the high speed rotational shaft to a low speed rotational shaft with a planetary gear mechanism, wherein the low speed rotational shaft is aligned coaxially with the high speed rotational shaft; detecting a rotational speed or rotational angle of the high speed rotational shaft with a high speed side encoder; detecting a rotational speed or rotational angle of the low speed rotational shaft with a low speed side encoder; and determining an absolute rotational angle of the low speed or high speed rotational shaft based on outputs of the high speed side and low speed side encoders.
Priority Claims (1)
Number |
Date |
Country |
Kind |
P2000-316902 |
Oct 2000 |
JP |
|
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The present application claims the priority of Japanese Patent Application No. 2000-316902 filed in Japan on Oct. 17, 200, the entire contents of which is hereby incorporated herein by reference.