A multi-speed transfer case equipped with a planetary reduction gearset and a range clutch disposed between an input shaft and an output shaft. A clutch actuation mechanism controls actuation of the range clutch to establish distinct ratio drive connections between the input shaft and the output shaft.

A system for and method of shifting a drive configuration of an all-terrain vehicle (ATV) is provided. The system includes a shifter assembly, a gear case, and a linkage assembly extending therebetween. The shifter assembly includes a trigger lever for receiving a mechanical user input, thereby moving the shifter assembly between a locked configuration and an unlocked configuration. The linkage assembly translates the user input to the gear case, thereby causing the gear case to shift between an engaged configuration and a disengaged configuration, respectively. A linkage biasing member provides mechanical flexibility between the shifter assembly and the gear case, facilitating shifting on the fly. The trigger lever is operated by toggling it from a rest position to a deployed position. Upon user release, the trigger lever is automatically returned to its rest position for future engagement by the user.

For use in all wheel drive vehicles with a rear electronic differential, a device containing a switch for making and breaking an electrical connection in a ground line of a differential harness. When the circuit is broken and the rear electronic differential is no powered, the rear electronic differential does not power the rear axles. A wireless remote control has buttons that when pressed send a wireless signal to a receiver connected to the switch. When the first button in the remote control is pressed, the switch breaks the connection in the ground line. When the second button in the remote control is pressed, the switch completes the connection in the ground line.

A vehicle includes a continuously variable transmission (CVT) operatively connected to an engine, the CVT being disposed on a right side of the engine. A sub-transmission is operatively connected to the CVT and includes: an output shaft rotatable about an output shaft axis; a plurality of sub-transmission driven members mounted to the output shaft and operatively connected to the CVT, the plurality of sub-transmission driven members including a first sub-transmission driven member and a second sub-transmission driven member; a shifter selectively drivingly engaging the first sub-transmission driven member and the second sub-transmission driven member with the output shaft; and a sub-transmission driving member mounted to the output shaft and rotatable therewith. One of a differential assembly and a spool operatively connects the sub-transmission driving member to at least one ground-engaging member of the vehicle.

In accordance with one aspect of the techniques described herein, there is provided a vehicle comprising an engine, an automatic, robotic, or continuously variable transmission mechanically coupled to the engine, a four-wheel drive system, a vehicle control system coupled to the engine, the four-wheel drive system and the transmission, a braking system, a gas pedal for controlling the operation of the engine, a brake pedal for controlling the operation of the braking system, the gas pedal and the brake pedal being disposed in the vehicle for control by a right foot of the driver, the vehicle further comprising an additional pedal being disposed in the vehicle for control by a left foot of the driver and coupled to the vehicle control system, wherein the additional pedal is separate and distinct from the brake pedal and the gas pedal and wherein additional pedal controls the four-wheel drive system of the vehicle.

A system for controlling movement of a vehicle includes a user input device and computing system. The user input device dynamically controls a settings or balance of driving dynamics in a vehicle, and the user input device is configured to receive a manual input from a user. The computing system controls the settings of the vehicle driving dynamics and/or balance of the vehicle, the computing system is in data communication with the user input device and configured to change the driving dynamics balance proportionately to the manual input upon receiving an input command based on the manual input from the user input device.

A vehicle system comprises an engine driving a vehicle, a front wheel and a rear wheel, a suspension device with an attachment portion to a vehicle body which is located at a higher level than a center axis of the rear wheel, an electromagnetic coupling to distribute a torque of the engine to the front wheel and the rear wheel, a steering wheel to be operated by a driver, a steering angle sensor to detect a steering angle corresponding to operation of the steering wheel, and a controller to control the engine and the electromagnetic coupling. The controller is configured to control the electromagnetic coupling such that the torque distributed to the rear wheel is increased in accordance with turning operation of the steering wheel which is detected by the steering angle sensor.

The present invention relates to a transfer gearbox having an input shaft, a first output shaft, a second output shaft, a friction clutch, by means of which, in a manner which is dependent on its engagement state, a variable proportion of a drive torque which is transmitted from the input shaft to the first output shaft can be transmitted to the second output shaft, and a rotationally driven actuator unit for controlling the engagement state of the friction clutch. Furthermore, the transfer gearbox has an electromagnetically actuable latch for locking the actuator unit as required.

The present disclosure describes an apparatus, and method of operation for an axial coupling that includes a shift linkage having a first end and a second end, the shift linkage configured to pivot between a first position and a second position. The axial coupling further includes a first solenoid affixed to the first end of the shift linkage, and actuating the first solenoid pivots the shift linkage between the first and second positions. A latch is configured to engage with the shift linkage retaining the shift linkage in the first position when engaged and a second solenoid positioned to contact the latch, that when energized, pivots the latch into and maintain the latch in an engaged position.

A neutral release mechanism for an outdoor power equipment is discussed. One example embodiment comprises a neutral release mechanism that switches a gearbox or a transmission between neutral mode and drive, comprising: a user input that rotates between a first angle and a second angle; and a plunger coupled to the user input and a pin, wherein the plunger and the pin move parallel to an axis of the drive wheel between a first and a second position, wherein the pin is at the first position when the user input is at the first angle and the second position when the user input is at the second position, wherein the pin places the gearbox or the transmission in drive when the pin is at the first position and places the gearbox or the transmission in neutral when the pin is at the second position.