An implement drive system is provided for an implement towed by a prime mover vehicle in a work vehicle train. The system includes an axle arrangement and an auxiliary power unit. The auxiliary power unit includes an electric motor; a planetary gear set receiving rotational input from the electric motor and providing a rotational output with a decreased rotational speed and an increased torque relative to the rotational input; and a disconnect device having an output configured to be coupled to the axle arrangement. The disconnect device is movable to a first position in which the disconnect device transfers the rotational output from the planetary gear set to the axle arrangement such the rotational input drives the wheels of the implement. The disconnect device is movable to a second position in which the disconnect device decouples the axle arrangement from the rotational input of the electric motor.

A method of controlling an input clutch and an output clutch, wherein the input clutch couples to a power source, the output clutch couples to a load, and the input clutch couples to the output clutch via gears, includes controlling torque of the input clutch based on a torque of the output clutch or a lookup table that controls the torque of the output clutch. The method also includes adjusting the torque of the input clutch based on a slip speed of the input clutch and a slip speed of the output clutch.

A wheel loader includes a boom, a forward clutch, and a controller configured to control hydraulic pressure of hydraulic oil supplied to the forward clutch. The controller performs clutch hydraulic pressure control for bringing the forward clutch into a semi-engagement state by controlling the hydraulic pressure of the hydraulic oil supplied to the forward clutch on condition that the wheel loader advances while raising the boom in at least a loaded state.

An integrated driveline (136, 236, 336, 36, 436) slip clutch (154, 254, 354, 454) system for a large square baler (28) for controlling a transfer of power from a tractor (26) to the baler (28). The clutch (254) system includes a slip clutch (154, 254, 354, 454) having a number of clutch plates (388). The slip clutch (154, 254, 354, 454) is moveable between a disengaged relationship in which no power is transferred from a driveline (136, 236, 336, 36, 436) to a gearbox (140, 240, 340, 40, 440), and one or more engaged relationships in which amounts of power are transferred from the driveline (136, 236, 336, 36, 436) to the gearbox (140, 240, 340, 40, 440). Movement of the slip clutch (154, 254, 354, 454) between engagement relationships may be controlled mechanically (by, e.g., centrifugal force) or electronically. For electronic control, a controller receives input data from sensors (504) concerning operation of the baler (28), and controls a valve to introduce or remove hydraulic fluid to or from a clutch cylinder (276, 376, 476) or a double acting cylinder (496) in accordance with a pressure control profile which ramps hydraulic pressure through levels to achieve the engagement relationships.

A rotor assembly for a rotary mixer is disclosed. The rotor assembly includes a main drive configured to rotatably drive the rotor assembly, a main drive clutch enclosed in a drivetrain housing of the main drive, an actuation valve operably coupled to the main drive clutch, the actuation valve configured to actuate the main drive clutch between at least a first position and a second position, a rotor drum, a rotor drive gearbox having an input and an output, the gearbox output operably coupled to the rotor drum, a main drive belt rotatably coupled to the main drive clutch and the rotor drive gear box input such that a rotation of the main drive clutch imparts a rotation on the rotor drive gear box, and a speed sensor operably coupled to the rotor drum, the speed sensor measuring a rotational speed of the gearbox and generating a rotor speed signal, wherein based on when the rotor speed signal is below a predetermined rotor speed threshold the actuation valve is activated to rotate the main drive clutch a predetermined amount between the first position and the second position.

A flow control system for an agricultural metering system includes a control system configured to be communicatively coupled to at least one clutch. The control system is configured to output a respective pulse-width modulation (PWM) signal to the at least one clutch, the PWM signal is configured to induce the at least one clutch to alternately engage to establish a rotatable connection between a respective drive input and a respective rotatable metering device and to disengage to interrupt the rotatable connection between the respective drive input and the respective rotatable metering device, and the control system is configured to adjust a duty cycle of the respective PWM signal to control a rotation rate of the respective rotatable metering device.

A hydraulic power module for a crop harvester, and in particular a cotton harvester, having an engine. The hydraulic power module includes a main drive gear, a drive shaft extending through the main drive gear, and a clutch operatively connected to the drive shaft, wherein the clutch has an engaged position and a disengaged position. The engaged position of the clutch fixedly connects the main drive gear to the drive shaft and the disengaged position of the clutch disconnects the main drive gear drive from the drive shaft. The hydraulic power module further includes a first pump device directly coupled to the drive shaft, wherein the first pump device is driven by the drive shaft during rotation of the drive shaft. A second pump device is indirectly connected to the drive shaft through the clutch, and is driven by the drive shaft when the clutch is in the engaged position.

A method for controlling engagement of a power take-off (PTO) clutch of a work vehicle may generally include transmitting, by a computing device, a control signal associated with initiating engagement of the PTO clutch, determining a clutch slippage energy generated during engagement of the PTO clutch due to clutch slippage and, while the PTO clutch is getting engaged, calculating a clutch engagement time remaining until engagement of the PTO clutch is completed based on the clutch slippage energy and a maximum clutch engagement energy associated with the PTO clutch. In addition, the method may include determining a torque command for controlling engagement of the PTO clutch as a function of the remaining clutch engagement time and controlling the engagement of the PTO clutch based on the torque command.

A method for controlling power takeoff (PTO) clutch engagement includes determining an output clutch speed, adjusting a clutch current at a predetermined rate, estimating an inertial load of a PTO implement and adjusting the clutch current for one or more times at a time interval, and selecting a clutch control algorithm configured for the inertial load of the PTO implement.

An implement drive system is provided for an implement towed by a prime mover vehicle in a work vehicle train. The system includes an axle arrangement and an auxiliary power unit. The auxiliary power unit includes an electric motor; a planetary gear set receiving rotational input from the electric motor and providing a rotational output with a decreased rotational speed and an increased torque relative to the rotational input; and a disconnect device having an output configured to be coupled to the axle arrangement. The disconnect device is movable to a first position in which the disconnect device transfers the rotational output from the planetary gear set to the axle arrangement such the rotational input drives the wheels of the implement. The disconnect device is movable to a second position in which the disconnect device decouples the axle arrangement from the rotational input of the electric motor.