Claims
- 1. An energy saving gear system comprising:
a driven means, rotatably mounted on an axis, having a plurality of involute teeth mounted circumferentially thereto; a driving means in operative engagement with the involute teeth of said driven means; and a means for engaging the involute teeth of the driven means in conjunction with the driving means, said means for engaging the involute teeth of the driven means remaining in substantial rolling contact to a profile of a plurality of involute teeth of the driven means; and wherein the means for engaging the involute teeth of the driven means provides a variable pressure angle and a variable contact ratio of the gear system.
- 2. The gear system of claim 1, wherein said driven means includes a driven gear having a plurality of involute teeth circumferentially mounted thereto and said driving means includes a driving gear having a plurality of pins circumferentially mounted thereto.
- 3. The gear system of claim 2, wherein the means for engaging the involute teeth of the driven gear includes the plurality of pins circumferentially mounted to the driving gear, wherein the pins have a circular cross-section.
- 4. The gear system of claim 3, wherein the variable pressure angle is in the range of 2 to 7 degrees.
- 5. The gear system of claim 4, wherein the variable pressure angle decreases as a factor of the uniform radius of the plurality of pins on the driving gear increases.
- 6. The gear system of claim 5, wherein the contact ratio varies as a function of the uniform differential in the diameter of the plurality of pins on the driving gear.
- 7. The gear system of claim 6, wherein the contact ratio is a measure of the number of involute gear teeth of the driven gear in full contact with the plurality of pins of the driving gear.
- 8. The gear system of claim 7, wherein a high contact ratio provides for increased load and torque capacity to the gear system.
- 9. The gear system of claim 7, wherein the contact ratio is in the range of 1 to 2.5.
- 10. The gear system of claim 1, wherein the driven means and the driving means do not require an external layer of a friction reducing material.
- 11. The gear system of claim 1, in which the radius of the means for engaging the teeth of the driven means is defined at a maximum as effectively less than the distance between midpoints of the two teeth for a constant distance between the driven means and the driving means, if the radius of the means for engaging the teeth of the driven means is maximized then the pressure angle of the gear system is minimized.
- 12. The gear system of claim 4, wherein the variable pressure angle between two circular gears is calculated as follows: C=[rb÷cos Ø]+rp Sin Ø, where C is the center distance between gear 2 and gear 10, rb is the base circle radius and rp is the radius of the pin 60.
- 13. An energy saving gear system comprising:
a driven gear, rotatably mounted on an axis, having a plurality of involute teeth circumferentially mounted there to; a driving gear in operative engagement with the involute teeth of said driven gear; and a plurality of round pins circumferentially and rotatably mounted to said driving gear for engaging the involute teeth of the driven gear, said round pins being designed to engage and make substantial rolling contact with a profile of each of the plurality of involute teeth of the driven gear; and wherein the gear system has a variable pressure angle and a variable contact ratio.
- 14. A rack and pinion energy saving gear system comprising;
a pinion gear, rotatably mounted on an axis, having a plurality of involute teeth; a rack contacting the involute teeth of the pinion gear; and pins for engaging the involute teeth of the pinion gear rotatably mounted on the rack; wherein the rack and pinion gear system has a variable pressure angle and variable contact ratio.
- 15. The rack and pinion gear system of claim 14, wherein the pins for engaging the pinion gear have a circular cross-section.
- 16. The rack and pinion gear system of claim 15, wherein the variable pressure angle between the pinion gear and the rack is calculated as follows: R2=rp2+[C−(rb÷cos Ø]−{2rp[C −(rb÷cos Ø)]Sin Ø} where C is the center distance, rb is the base circle radius and rp is the radius of the pin 60.
- 17. The rack and pinion gear system of claim 16, wherein the variable pressure angle is in the range of 2 to 7 degrees.
- 18. The rack and pinion gear system of claim 14, wherein the contact ratio varies as a function of the uniform differential in the diameter of the plurality of pins on the rack.
- 19. The rack and pinion gear system of claim 18, wherein the contact ratio is a measure of the number of involute gear teeth of the pinion gear in full contact with the plurality of pins of the rack.
- 20. The rack and pinion gear system of claim 19, wherein a high contact ratio provides for increased load and torque capacity to the gear system.
Parent Case Info
[0001] Priority for this non-provisional patent application is claimed under 35 U.S.C. § 119, pursuant to Applicant's provisional patent application, application No. 60/291,981, filed on May 21, 2001.
Provisional Applications (1)
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Number |
Date |
Country |
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60291981 |
May 2001 |
US |