Power Flow

Power Flow

P position
^ The driving force of the input shaft is transmitted to the rear sun gear and the reverse and high clutch drum. However, since none of the clutches are operating, the driving force is not transmitted to the output shaft. Accordingly, the vehicle is under conditions enabling movement but since the parking pawl mechanically locks the output shaft, the rear planetary gear and front internal gear are locked. Due to this, the vehicle is stopped.





R position
^ Driving force from the input shaft is transmitted to the reverse and high clutch drum, then via the reverse clutch to the front sun gear, which rotates clockwise. At this point, the front pinion gear does not revolve because the front planetary carrier is locked by the low and reverse brake. Due to this, the front sun gear causes the front pinion gear to rotate axially counterclockwise. This rotation causes the front internal gear and the rear planetary gear to rotate counterclockwise. As a result, the output shaft also rotates counterclockwise and this driving force is transmitted via the propeller shaft to the driving wheels.





N position
^ Driving force from the input shaft is transmitted to the rear sun gear and the reverse and high clutch drum. However, since none of the clutches are operating, the driving force is not transmitted to the output shaft. Accordingly, the vehicle is the vehicle is able to roll.





D range 1GR
^ Driving force from the input shaft is transmitted to the rear sun gear, which rotates clockwise, causing the rear pinion gear to rotate counterclockwise. At this point, since the rear planetary carrier is united with the output shaft (and therefore, the driving wheels), the load of the stopped vehicle fixes the rear planetary carrier and it does not revolve. Due to this, the counterclockwise rotation of the rear pinion gear causes the rear internal gear to also try to rotate counterclockwise but it is locked by the low one-way clutch via the low clutch. As a result, the rear pinion gear rotates axially counterclockwise, overcoming the load of the stopped vehicle and the rear planetary carrier revolves clockwise. Accordingly the output shaft also rotates clockwise and this driving force is transmitted via the propeller shaft to the driving wheels.
^ During deceleration, the rear internal gear tries to rotate clockwise due to the rotation of the rear planetary carrier (rear pinion gear) being comparatively higher to that of the rear sun gear. At this point, since the low one-way clutch is not utilized and rotates freely, the rear internal gear rotates clockwise. In this way, engine braking is not actuated since the reverse torque from the driving wheels is not transmitted back towards the engine.





M range 1GR
^ The driving force from the input shaft is transmitted to the rear sun gear, which rotates clockwise causing the rear pinion gear to rotate counterclockwise. The rear internal gear does not rotate since it is locked by the low and reverse brake via the low clutch. As a result, the rear pinion gear rotates axially counterclockwise, overcoming the load of the stopped vehicle, causing the rear planetary carrier to revolve clockwise. Accordingly, the output shaft rotates clockwise and this driving force is transmitted via the propeller shaft to the driving wheels.
^ During deceleration, the driving force is transmitted from the driving wheels. Due to this, the driving force becomes the reverse of that during acceleration and engine braking is actuated.





D, M range 2GR
^ The driving force from the input shaft is transmitted to the rear sun gear, which rotates clockwise causing the rear pinion gear to rotate counterclockwise. Then, the driving force causes the rear planetary carrier to rotate clockwise, similar to first gear. The front internal gear also rotates clockwise since it is united with the rear planetary gear. At this point, the front sun gear does not rotate because it is locked by the 2-4 brake. Due to this, the front pinion gear rotates axially clockwise and revolves clockwise, and the front planetary carrier rotates clockwise. The clockwise rotation of the front planetary carrier is transmitted via the low clutch to the rear internal gear, causing it to rotate clockwise. As a result, the rotation speed of the rear planetary carrier increases from that of first gear in proportion to the rotation of the rear internal gear. Accordingly, the driving force from the rear planetary carrier, whose speed has been increased, is transmitted via the propeller shaft to the driving wheels.
^ During deceleration, the driving force is transmitted from the driving wheels. Due to this, the driving force becomes the reverse of that during acceleration and engine braking is actuated.





D, M range 3GR
^ The driving force from the input shaft is transmitted to the reverse and high clutch drum and then via the high clutch to the front planetary carrier, causing it to rotate clockwise. This clockwise rotation of the front planetary carrier is transmitted via the low clutch to the rear internal gear causing it to rotate clockwise. The driving force of the input shaft is transmitted to the rear sun gear and causing to rotate clockwise. At this point, since the rear sun gear and rear internal gear are rotating clockwise at the same speed, the rear pinion gear does not rotate axially, and the rear sun gear and rear internal gear become united and revolve. The force of this revolution is transmitted to the rear planetary carrier, the output shaft and then, via the propeller shaft to the driving wheels.
^ During deceleration, the driving force is transmitted from the driving wheels. Due to this, the driving force becomes the reverse of that during acceleration and engine braking is actuated.





D, M range 4GR
^ The driving force from the input shaft is transmitted to the reverse and high clutch drum and then via the high clutch to the front planetary carrier, causing it to rotate clockwise. At this point, the front sun gear does not rotate because it is locked by the 2-4 brake. Due to this the front pinion gear revolves clockwise and rotates axially clockwise. This rotation causes the front internal gear rotation to increase speed and the rear planetary carrier to rotate clockwise. Accordingly, the driving force from the sped-up rear planetary carrier is transmitted, via the propeller shaft, to the driving wheels.
^ During deceleration, the driving force is transmitted from the driving wheels. Due to this, the driving force becomes the reverse of that during acceleration and engine braking is actuated.