A controller performs control in a vehicle having a planetary gear mechanism, a forward clutch, an engine rotation sensor. a PRI rotation sensor, and a rotation sensor. The controller determines a rotation direction of a primary pulley corresponding to a rotation direction of a carrier on the basis of a rotation speed corresponding to a rotation speed of a sun gear, a rotation speed corresponding to a rotation speed of the carrier C, and a rotation speed of a ring gear, respectively.

A vehicle control system includes: an operation element; a travel control unit configured to accelerate or decelerate a vehicle; and a shift range control unit configured to control a shift range of the vehicle. In a state where the shift range of the vehicle is set to a first travel range, the travel control unit accelerates the vehicle according to a moving operation on the operation element in a first travel direction and decelerates the vehicle according to the moving operation on the operation element in a second travel direction. In a state where the shift range of the vehicle is set to a second travel range, the travel control unit accelerates the vehicle according to the moving operation on the operation element in the second travel direction and decelerates the vehicle according to the moving operation on the operation element in the first travel direction.

Described herein is a control system for a vehicle having an infinitely variable transmission (WT) having a ball planetary variator (CVP), providing a smooth and controlled operation. In some embodiments, the vehicle is a fork lift truck. An operator commands a brake pedal, an accelerator pedal, and a direction switch (or gear selector), which are evaluated by the control system to determine a current operating state of the vehicle. Some operating states include, forward drive, reverse drive, vehicle braking, automatic deceleration, inching, power reversal, vehicle hold, and park, among others.

A controller performs control in a vehicle having a planetary gear mechanism, a forward clutch, an engine rotation sensor. a PRI rotation sensor, and a rotation sensor. The controller determines a rotation direction of a primary pulley corresponding to a rotation direction of a carrier on the basis of a rotation speed corresponding to a rotation speed of a sun gear, a rotation speed corresponding to a rotation speed of the carrier C, and a rotation speed of a ring gear, respectively.

A method for controlling a transmission of a marine propulsion device powered by an engine is carried out by a control module and includes monitoring a requested gear state of the transmission and a requested throttle position of a throttle valve on the engine. In response to the requested gear state being a neutral state or in response to the requested throttle position decreasing by more than a predetermined amount within a predetermined period of time, the control module controlling at least one of a pressure in a forward clutch of the transmission and a pressure in a reverse clutch of the transmission in a manner that is contraindicated by the requested gear state.

A control system operates a power train of a work vehicle. The system includes a transmission arrangement which transfers power from an engine to an output shaft of the vehicle to drive the vehicle in a first or second direction according to at least one forward or reverse modes. The arrangement includes a forward directional clutch and a reverse directional clutch, and a controller. The controller is configured to determine if one of the clutches is engaged; evaluate a speed of the engine; and provide a torque command to engage the other of the clutches to slow the speed of the engine when a shuttle shift is initiated, or when the speed of the engine exceeds a predetermined speed threshold.

A method is provided for controlling a gear shift from a forward gear to a reverse gear in a transmission arrangement, the method including the steps of: positioning a first locking mechanism and a first connecting mechanism at least in a partially engaged state for reducing a rotational speed of a planet carrier of a second planetary gear set; and positioning a second locking mechanism in an engaged state when a rotational speed of the planet carrier of the second planetary gear set is below a predetermined threshold limit.

A gear change and gear change biasing mechanism for use in an automatic swimming pool cleaner.

A switchback control apparatus for an industrial vehicle, includes a forward and reverse operating part, a forward and reverse position detector detecting a position of the forward and reverse operating part, a vehicle speed detector; and a shift control section shifting the transmission forcibly to a first speed stage and then, releasing the first speed stage of the transmission that is set forcibly when the forward and reverse operating part is shifted from the forward position to the reverse position or from the reverse position to the forward position by the forward and reverse position detector and a vehicle speed detected by the vehicle speed detector greater is than or equal to a threshold value that is smaller than a shift-up vehicle speed for shifting the transmission from the first speed stage to a second speed stage.

The present invention proposes a transmission control device capable of shortening a switching time between forward control and reverse control of a transmission. The present invention relates to a transmission control device that controls a transmission, including: a forward power transmission mechanism configured to move a vehicle forward; and a reverse power transmission mechanism configured to reverse the vehicle. Each of the forward power transmission mechanism and the reverse power transmission mechanism includes a driving-side connector and a driven-side connector. The forward power transmission mechanism and the reverse power transmission mechanism are configured to be capable of changing a contact state where the driving-side connector and the driven-side connector are pushed to contact each other, a retracted state where pushing forces are released to retract the driving-side connector and the driven-side connector, and an intermediate state formed as the intermediate state between the contact state and the retracted state. When the vehicle is controlled based on a previously-generated control content including switching between forward control and reverse control, one of the forward control and the reverse control is performed by controlling one power transmission mechanism between the forward power transmission mechanism and the reverse power transmission mechanism to the contact state while controlling the other power transmission mechanism to the intermediate state.