An exemplary infinitely variable transmission includes a planetary gear set situated in a drive train of an automotive vehicle and interfaced with a worm gear driven by an electrical motor continuously controlled by an electronic control unit in response to a torque demand. Another aspect may be sel
An exemplary infinitely variable transmission includes a planetary gear set situated in a drive train of an automotive vehicle and interfaced with a worm gear driven by an electrical motor continuously controlled by an electronic control unit in response to a torque demand. Another aspect may be selection of the worm gear helix angle to effect a balance between worm gear teeth friction and load placed on the worm gear by the planetary gear set, such that power required to drive the worm gear is minimized for all input load conditions.
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1. An infinitely variable transmission for use with an automotive vehicle, the infinitely variable transmission comprising: a planetary gear set having a first input component, a second input component, and an output component, wherein the first input component comprises a drive shaft input componen
1. An infinitely variable transmission for use with an automotive vehicle, the infinitely variable transmission comprising: a planetary gear set having a first input component, a second input component, and an output component, wherein the first input component comprises a drive shaft input component,wherein the planetary gear set is positioned relative to a drivetrain of the automotive vehicle such that a drive shaft driven by an internal combustion engine of the automotive vehicle is connected to the drive shaft input component, and the output component is connected to an output shaft configured to drive a motivational mechanism of the automotive vehicle;an electrical motor configured to drive the second input component through a gear set interface; andan electronic control unit configured to control at least the electrical motor in response to a torque demand and in a manner to satisfy the torque demand by either: (a) operating the internal combustion engine at a set point associated with a particular efficiency, while modifying an angular velocity of the electrical motor to satisfy the torque demand; or(b) operating the internal combustion engine in a manner that deviates from the particular efficiency such that the torque demand is satisfied. 2. The infinitely variable transmission of claim 1, wherein the gear set interface comprises a worm gear set. 3. The infinitely variable transmission of claim 2, wherein the worm gear set has a helix angle selected to effect a balance between worm gear teeth friction and a load of the second input component, such that power required to drive the worm gear set is minimized for input load conditions. 4. The infinitely variable transmission of claim 1, wherein the particular efficiency is an optimum efficiency. 5. The infinitely variable transmission of claim 1, wherein the output component comprises a planetary carrier of the planetary gear set, the drive shaft input component comprises a sun gear of the planetary gear set, and the second input component comprises a ring gear of the planetary gear set. 6. The infinitely variable transmission of claim 1, wherein operating the internal combustion engine in a manner that deviates from the particular efficiency such that the torque demand is satisfied, comprises operating the internal combustion engine in a manner that deviates from the particular efficiency only to an extent necessary to satisfy the torque demand. 7. The infinitely variable transmission of claim 1, wherein the electronic control unit is operatively connected, during a start mode of operation, to: (i) operate the electrical motor in a direction to turn the drive shaft input component to start the internal combustion engine of the automotive vehicle, while a clutch is engaged;(ii) perform detection of a starting of the internal combustion engine of the automotive vehicle; and(iii) in response to the detection of the starting of the internal combustion engine, disengage the clutch to allow the internal combustion engine to reach an idle speed. 8. The infinitely variable transmission of claim 1, wherein the electronic control unit is operatively connected, during a start mode of operation, to: (i) operate the electrical motor in a direction to turn the drive shaft input component to start the internal combustion engine of the automotive vehicle, while a clutch is engaged;(ii) perform detection of a starting of the internal combustion engine of the automotive vehicle; and(iii) in response to the detection of the starting of the internal combustion engine, operate the electrical motor at an angular velocity to allow the internal combustion engine to operate at an idle speed. 9. The infinitely variable transmission of claim 1, wherein the electronic control unit is operatively connected, during a reverse mode of operation, to: operate the electrical motor at an angular velocity to satisfy the torque demand while moving the automotive vehicle in reverse; andrespond to at least one of a state of a brake signal or a setting of a clutch of the automotive vehicle by operating the electrical motor at an angular velocity to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 10. The infinitely variable transmission of claim 1, wherein the electronic control unit is operatively connected, during a drive mode of operation, to: operate the electrical motor at an angular velocity to satisfy the torque demand while moving the automotive vehicle forward; andrespond to at least one of a state of a brake signal or a setting of a clutch connecting the drive shaft to the drive shaft input component by operating the electrical motor at an angular velocity to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 11. The infinitely variable transmission of claim 1, wherein: the torque demand is indicated by an accelerator pedal signal generated by an accelerator pedal of the automotive vehicle;the electronic control unit is operatively connected to receive RPM signals indicative of angular velocity of the drive shaft and angular velocity of the electrical motor; andthe electronic control unit is operatively connected to (a) determine one or more operational parameters based at least in part on the accelerator pedal signal, the angular velocity of the drive shaft, and the angular velocity of the electrical motor, and (b) apply the one or more operational parameters to modify the angular velocity of the drive shaft and the angular velocity of the electrical motor. 12. The infinitely variable transmission of claim 1, wherein: the electronic control unit is configured to receive: (a) at least one of: (i) a brake signal generated by a brake pedal of the automotive vehicle, or (ii) a state of a clutch that connects the drive shaft to the drive shaft input component, and(b) a signal indicative of angular velocity of at least one of the motivational mechanism of the automotive vehicle or the output shaft;the electronic control unit is configured to determine, conditioned on a state of at least one of the brake signal or the clutch, one or more operational parameters based on at least one of the angular velocity of the motivational mechanism or the angular velocity of the output shaft; andthe electronic control unit is operatively connected to apply the one or more operational parameters to control the angular velocity of the drive shaft and the angular velocity of the electrical motor in a manner to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 13. The infinitely variable transmission of claim 1, wherein one or more operational parameters are determined using at least one from the group consisting of: a datastore, a data look-up table, a formula, and a data map. 14. A method of operation for use with an infinitely variable transmission of an automotive vehicle, the method comprising: receiving, by an electronic control unit of the automotive vehicle, a torque demand generated, at least in part, by an operator of the automotive vehicle;controlling, by the electronic control unit, an electrical motor in response to the torque demand in a manner to satisfy the torque demand by either: (a) operating, by the electronic control unit, an internal combustion engine of the automotive vehicle at a set point associated with a particular efficiency, while modifying, by the electronic control unit, an angular velocity of the electrical motor to satisfy the torque demand, or(b) operating, by the electronic control unit, the internal combustion engine in a manner that deviates from the particular efficiency such that the torque demand is satisfied;wherein the electrical motor is configured to drive a gear interfaced with an input component of a planetary gear set, the planetary gear set being positioned relative to a drivetrain of the automotive vehicle such that a drive shaft driven by the internal combustion engine is connected to a drive shaft input component of the planetary gear set, and an output component of the planetary gear set is connected to an output shaft for driving a motivational mechanism of the automotive vehicle. 15. The method of claim 14, wherein the gear interfaced with the input component comprises a worm gear set. 16. The method of claim 15, wherein the gear interfaced with the input component has a helix angle selected to effect a balance between worm gear teeth friction and load of the input component, such that power required to drive the gear is minimized for input load conditions. 17. The method of claim 14, wherein the particular efficiency is an optimum efficiency. 18. The method of claim 14, wherein the input component comprises a ring gear of the planetary gear set, the drive shaft input component comprises a sun gear of the planetary gear set, and the output component comprises a planetary carrier of the planetary gear set. 19. The method of claim 14, wherein operating, by the electronic control unit, the internal combustion engine in a manner that deviates from the particular efficiency such that the torque demand is satisfied, comprises operating the internal combustion engine in a manner that deviates from the particular efficiency only to an extent necessary to satisfy the torque demand. 20. The method of claim 14, further comprising: during a start mode of operation:(i) operating, by the electronic control unit, the electrical motor in a direction to turn the drive shaft input component to start the internal combustion engine of the automotive vehicle, while a clutch is engaged;(ii) performing, by the electronic control unit, detection of a starting of the internal combustion engine of the automotive vehicle; and(iii) in response to the detection of the starting of the internal combustion engine, disengaging the clutch to allow the internal combustion engine to reach an idle speed. 21. The method of claim 14, further comprising: during a start mode of operation:(i) operating, by the electronic control unit, the electrical motor in a direction to turn the drive shaft input component to start the internal combustion engine of the automotive vehicle, while a clutch is engaged;(ii) performing, by the electronic control unit, detection of a starting of the internal combustion engine of the automotive vehicle; and(iii) in response to the detection of the starting of the internal combustion engine, operating the electrical motor at an angular velocity to allow the internal combustion engine to operate at an idle speed. 22. The method of claim 14, further comprising: during a reverse mode of operation, operating, by the electronic control unit, the electrical motor at an angular velocity to satisfy the torque demand while moving the automotive vehicle in reverse; andduring the reverse mode of operation, responding, by the electronic control unit, to at least one of a state of a brake signal or a setting of a clutch of the automotive vehicle by operating the electrical motor at an angular velocity to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 23. The method of claim 14, further comprising: during a drive mode of operation:operating, by the electronic control unit, the electrical motor at an angular velocity to satisfy the torque demand while moving the automotive vehicle forward; andresponding to at least one of a state of a brake signal or a setting of a clutch connecting the drive shaft to the drive shaft input component by operating the electrical motor at an angular velocity to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 24. The method of claim 14, further comprising: receiving, by the electronic control unit, the torque demand as an accelerator pedal signal generated by an accelerator pedal of the automotive vehicle;receiving, by the electronic control unit, a first RPM signal indicative of angular velocity of the drive shaft;receiving, by the electronic control unit, a second RPM signal indicative of angular velocity of the electrical motor;determining, by the electronic control unit, one or more operational parameters based at least in part on the accelerator pedal signal, the angular velocity of the drive shaft, and the angular velocity of the electrical motor; andapplying, by the electronic control unit, the operational parameters to control the angular velocity of the drive shaft and the angular velocity of the electrical motor. 25. The method of claim 14, further comprising: receiving, by the electronic control unit, a brake signal generated by a brake pedal of the automotive vehicle;receiving, by the electronic control unit, a signal indicative of at least one of an angular velocity of the motivational mechanism of the automotive vehicle or an angular velocity of the output shaft;conditioned on a state of the brake signal, determining, by the electronic control unit, one or more operational parameters based at least in part on at least one of the angular velocity of the motivational mechanism or the angular velocity of the output shaft; andapplying, by the electronic control unit, the one or more operational parameters to control the angular velocity of the drive shaft and the angular velocity of the electrical motor in a manner to match the angular velocity of the drive shaft input component to the angular velocity of the drive shaft. 26. The method of claim 14, wherein one or more operational parameters are determined using at least one from the group consisting of: a datastore, a data look-up table, a formula, and a data map. 27. An infinitely variable transmission for use with an automotive vehicle, the infinitely variable transmission comprising: a planetary gear set having a first input component, a second input component, and an output component, the planetary gear set operable to be coupled to a drivetrain of the automotive vehicle such that the first input component is coupled to a drive shaft driven by an engine of the automotive vehicle, and the output component is connected to an output shaft configured to drive a motivational mechanism of the automotive vehicle;an electrical motor connected to drive the second input component through a gear set interface; andan electronic control unit operable to control the electrical motor in response to a torque demand generated at least in part by the automotive vehicle and in a manner to satisfy the torque demand by either:(a) operating the engine at a set point associated with a particular efficiency, while modifying an angular velocity of the electrical motor to satisfy the torque demand; or(b) operating the engine in a manner that deviates from the particular efficiency such that the torque demand is satisfied. 28. The infinitely variable transmission of claim 27, wherein the gear set interface comprises a worm gear set. 29. The infinitely variable transmission of claim 27, wherein the output component comprises a planetary carrier of the planetary gear set, the first input component comprises a sun gear of the planetary gear set, and the second input component comprises a ring gear of the planetary gear set. 30. The infinitely variable transmission of claim 27, wherein the particular efficiency is an optimum efficiency.
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이 특허에 인용된 특허 (50)
Kasahara Hiroyuki (Tokyo JPX), ATM transmission system with a variable transmission rate.
Giuliani Robert L. (1456 Thurston Ave. Honolulu HI 96822) Giuliani Mark A. (45-310 Akimala Pl. Kaneohe HI 96744) Giuliani Karen A. (45-310 Akimala Pl. Kaneohe HI 96744), Continuously variable transmission.
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