In embodiments, a work vehicle magnetorheological fluid (MRF) joystick system includes a joystick device, an MRF joystick resistance mechanism, and a controller architecture. The joystick device includes, in turn, a base housing, a joystick movably mounted to the base housing, and a joystick position sensor configured to monitor movement of the joystick relative to the base housing. The MRF joystick resistance mechanism is controllable to vary a first joystick stiffness resisting movement of the joystick relative to the base housing in at least one degree of freedom. The controller architecture is configured to: (i) detect when unintended joystick motion conditions occur during operation of the work vehicle; and (ii) when detecting unintended joystick motion conditions, command the MRF joystick resistance mechanism to increase the first joystick stiffness in a manner reducing susceptibility of the joystick device to unintended joystick motions.

An accelerator pedal system includes a pedal lever that performs an operation in accordance with a step-on operation, a lock mechanism configured to restrict the operation of the pedal lever, and an actuator configured to switch between a locked state in which the operation of the pedal lever is restricted by the lock mechanism and an unlocked state in which the operation of the pedal lever is not restricted by the lock mechanism. A controller includes a locking operation determination unit that determines switching of a locking operation by the lock mechanism, an actuator control unit that controls a driving operation of the actuator, and an information acquisition unit that acquires vehicle speed information. The locking operation determination unit locks the pedal lever when a vehicle is traveling in an automatic driving mode and when a vehicle speed is equal to or more than an activation-determination lower limit value.

An accelerator pedal system includes a pedal lever, a lock mechanism, an actuator, and an ECU. The pedal lever operates according to a step-on operation. The lock mechanism can restrict an operation of the pedal lever. The actuator switches between a locked state in which the operation of the pedal lever is restricted by the lock mechanism and an unlocked state in which the operation of the pedal lever is not restricted. The ECU includes a lock operation determination unit and an actuator control unit. The lock operation determination unit unlocks the pedal lever when an approaching object from behind is detected during a travel of a vehicle in the locked state.

An apparatus for controlling a vehicle includes a vehicle state detector for detecting a vehicle state, a function unit that performs at least one vehicle function, an operation unit that enables a transmission operation to allow selection of a transmission stage from among a plurality of transmission stages, and a position adjusting unit to switch the operation unit between a first position where the transmission operation is disabled and a second position where the transmission operation is enabled, by rotating the operation unit with respect to the functional unit, based on the detected vehicle state.

The present disclosure discloses a foldable pedal apparatus for a vehicle in which a pedal pad 210 protrudes to be exposed to the interior of a vehicle and pop up toward a driver in a manual driving mode in which the driver is actively involved in driving, in which the pedal pad 210 is inserted into a footrest panel 10 such that exposure toward the driver is blocked in a hide state in an autonomous driving mode, and which may generate a signal relating to a pedal function by operating the pedal pad 210 by pressure through the pressure-operated pedal assembly 200 in a pop-up state.

A throttle control mechanism for a surfacing machine, the control mechanism comprising a control member (310) arranged movable (M, D) in a support structure (320), wherein the control member (310) is arranged to be tensely attached to a throttle actuator (330) of the surfacing machine via a tensile engagement member (340), wherein the control member (310) is arranged to be held fixed in the support structure in at least a first throttle position (350), where the control member is arranged biased towards an idle throttle position (370) when released from the first throttle position (350), and wherein the first throttle position (350) and the idle throttle position (370) are configurable to provide an engine speed margin with respect to a clutch engagement engine speed range of the surfacing machine.

The present invention is an Electric servo system which controls and automates gate openings based on GPS speed and position data that results in precise and reliable modern variable and constant rate application. The Electric servo system also allows for Mechanical gate linkages to remain intact, resulting in few changes to the aircraft and redundancy of emergency components. A Mechanical input connect/disconnect is used to effortlessly transfer between the automated Electric servo system and the Mechanical gate system.

A lever latching system comprising: a housing; a lever having a latch pin fixedly mounted to the lever, the lever being movably mounted to the housing so that the latch pin moves in an arc; and a latch plate movably mounted to the housing for linear movement with respect to the housing, the latch plate comprising a labyrinth for receiving the latch pin.

Provided is a foldable pedal apparatus for a vehicle that is configured such that a pedal pad protrudes toward a driver to be exposed (pop-up state) such that the pedal pad can be operated by the driver in a manual driving mode in which the driver manually drives, and the pedal pad is hidden not to be exposed to the driver (hidden state) such that the pedal pad cannot be operated by the driver in an autonomous driving situation.

A cooking appliance or knob assembly may include a surface panel, a knob switch, a support plate, a control body, a central projection, and a spacing stake. The knob switch may be disposed behind the surface panel. The knob switch may include an internal spring and a slidable stem extending through a central axis. The slidable stem may be in forward-biased mechanical communication with the internal spring. The support plate may be rotabably mounted about the slidable stem. The control body may be mounted to the slidable stem. The control body may be rotationally fixed to the support plate and slidable relative thereto. The control body may include a primary grip extending about at least a portion of the slidable stem. The central projection may be disposed radially inward from the primary grip and define an axially fixed stop surface disposed forward from the control body.