초록 ▼

A hybrid transmission for a hybrid vehicle mounting thereon an engine and a pair of electric motor/generators operates in a plurality of driving modes including EV mode in which the vehicle is powered by only the pair of motor/generators and EIVT mode in which the vehicle is powered by both the pair

A hybrid transmission for a hybrid vehicle mounting thereon an engine and a pair of electric motor/generators operates in a plurality of driving modes including EV mode in which the vehicle is powered by only the pair of motor/generators and EIVT mode in which the vehicle is powered by both the pair of motor/generators and the engine. The driving mode is shifted continuously and smoothly through a mode-shift transition process, in which the operating state is regulated to decrease the relative torque and/or the relative rotational speed between the contact elements of an engine clutch before engaging or disengaging the engine clutch.

대표청구항 ▼

What is claimed is: 1. A hybrid transmission for a hybrid vehicle with a plurality of motors, the motors including at least a prime mover and two motor/generators, the hybrid transmission comprising: a differential mechanism including a plurality of rotating members, the number of which is one more

What is claimed is: 1. A hybrid transmission for a hybrid vehicle with a plurality of motors, the motors including at least a prime mover and two motor/generators, the hybrid transmission comprising: a differential mechanism including a plurality of rotating members, the number of which is one more than the number of the motors, each rotating member connected to a respective one of the motors and a drive train, for a determination of a lever state in which driving power is shared among the motors; sensors for detecting an operating state of the hybrid vehicle; a power regulator for regulating output powers of the motors; and a hybrid controller connected electrically to the sensors and the power regulator, and programmed to perform the following: operating the hybrid vehicle at least in a first driving mode in which the driving power is implemented by all of the prime mover and the two motor/generators, and in a second driving mode in which the driving power is implemented only by the two motor/generators; determining a current driving mode as one of the first and second driving modes and a target driving mode as the other of the first and second driving modes based on the operating state of the hybrid vehicle; determining a current lever state and a target lever state based on the operating state of the hybrid vehicle; determining, when there is a difference between the current lever state and the target lever state, a mode-shift transition process from the current lever state in the current driving mode to the target lever state in the target driving mode, in which the lever state varies continuously and smoothly; and executing the transition process with the power regulator. 2. The hybrid transmission as claimed in claim 1, further comprising a torque transmitting mechanism selectively connectable between one of the rotating members of the differential mechanism and an associated one of the motors and actuated by the power regulator, for a selection of a driving mode, wherein the hybrid controller is programmed to perform the following: reducing a relative rotational speed between contact elements of the torque transmitting mechanism before engaging the torque transmitting mechanism if the mode-shift transition process includes a state shift of the torque transmitting mechanism from a disengaged state to an engaged state. 3. The hybrid transmission as claimed in claim 2, wherein the hybrid controller is programmed to perform the following: shifting an engagement state of the torque transmitting mechanism from a disengaged state to an engaged state when the relative rotational speed between the contact elements of the torque transmitting mechanism is equal to or smaller than a predetermined threshold speed. 4. The hybrid transmission as claimed in claim 3, wherein the hybrid controller is programmed to perform the following: reducing a relative rotational acceleration between the contact elements of the torque transmitting mechanism before engaging the torque transmitting mechanism. 5. The hybrid transmission as claimed in claim 1, further comprising a torque transmitting mechanism selectively connectable between one of the rotating members of the differential mechanism and an associated one of the motors and actuated by the power regulator, for a selection of a driving mode, wherein the hybrid controller is programmed to perform the following: decreasing torque transmitted between contact elements of the torque transmitting mechanism before disengaging the torque transmitting mechanism if the mode-shift transition process includes a state shift of the torque transmitting mechanism from an engaged state to a disengaged state. 6. The hybrid transmission as claimed in claim 5, wherein the hybrid controller is programmed to perform the following: shifting an engagement state of the torque transmitting mechanism from an engaged state to a disengaged state when the transmitted torque between the contact elements of the torque transmitting mechanism is equal to or smaller than a predetermined threshold torque. 7. The hybrid transmission as claimed in claim 6, wherein the hybrid controller is programmed to perform the following: reducing a rate of change of the transmitted torque before disengaging the torque transmitting mechanism. 8. The hybrid transmission as claimed in claim 1, further comprising a torque transmitting mechanism selectively connectable between one of the rotating members of the differential mechanism and an associated one of the motors and actuated by the power regulator, for a selection of a driving mode, wherein the hybrid controller is programmed to perform the following: reducing a relative rotational speed between contact elements of the torque transmitting mechanism before engaging the torque transmitting mechanism if the mode-shift transition process includes a state shift of the torque transmitting mechanism from a disengaged state to an engaged state; shifting an engagement state of the torque transmitting mechanism from a disengaged state to an engaged state when the relative rotational speed between the contact elements of the torque transmitting mechanism is equal to or smaller than a predetermined threshold speed; reducing a relative rotational acceleration between the contact elements of the, torque transmitting mechanism before engaging the torque transmitting mechanism; decreasing torque transmitted between the contact elements of the torque transmitting mechanism before disengaging the torque transmitting mechanism if the mode-shift transition process includes a state shift of the torque transmitting mechanism from an engaged state to a disengaged state; shifting the engagement state of the torque transmitting mechanism from an engaged state to a disengaged state when the transmitted torque between the contact elements of the torque transmitting mechanism is equal to or smaller than a predetermined threshold torque; and reducing a rate of change of the transmitted torque before disengaging the torque transmitting mechanism. 9. The hybrid transmission as claimed in claim 1, wherein the mode-shift transition process includes a first part in which the lever state varies from the current lever state to an intermediate lever state which enables a smooth mode-shift from the current driving mode to the target driving mode and a second part in which the lever state varies from the intermediate lever state to the target lever state. 10. A hybrid transmission for a hybrid vehicle with a plurality of motors, the motors including at least a prime mover and two motor/generators, the hybrid transmission comprising: means for including a plurality of rotating members, the number of which is one more than the number of the motors, each rotating member connected to a respective one of the motors and a drive train, for a determination of a lever state in which driving power is shared among the motors; sensing means for detecting an operating state of the hybrid vehicle; power regulating means for regulating output powers of the motors; and control means for performing the following: operating the hybrid vehicle at least in a first driving mode in which the driving power is implemented by all of the prime mover and the two motor/generators, and in a second driving mode in which the driving power is implemented only by the two motor/generators; determining a current driving mode as one of the first and second driving modes and a target driving mode as the other of the first and second driving modes based on the operating state of the hybrid vehicle; determining a current lever state and a target lever state based on the operating state of the hybrid vehicle; determining, when there is a difference between the current lever state and the target lever state, a mode-shift transition process from the current lever state in the current driving mode to the target lever state in the target driving mode, in which the lever state varies continuously and smoothly; and executing the transition process with the power regulating means.