Proposed is an operation apparatus for a vehicle that improves visibility and interior aesthetics by appearing/disappearing mechanism of a button. The operation apparatus includes a panel, an operation module capable of moving, through an opening of the panel, between a first position and a second position spaced apart from each other in a front-back direction, a button placed on the operation module, a rotary link rotatably provided on an axis orthogonal to the front-back direction, a drive source for rotating the rotary link, and a cam mechanism having a guide path for inducing an angular motion of the rotary link and, thereby, moving the operation module to the first position or the second position.

Proposed is an operation apparatus for a vehicle that improves visibility and interior aesthetics by appearing/disappearing mechanism of a button. The operation apparatus includes a panel, an operation module capable of moving, through an opening of the panel, between a first position and a second position spaced apart from each other in a front-back direction, a button placed on the operation module, a rotary link rotatably provided on an axis orthogonal to the front-back direction, a drive source for rotating the rotary link, and a cam mechanism having a guide path for inducing an angular motion of the rotary link and, thereby, moving the operation module to the first position or the second position.

A shifting device (2) for an automatic gearbox of a motor vehicle has a housing (4) and a selector lever (6) for selecting a gear stage which selector lever is guided in the housing (4). The shifting device (2) has an automatic shift gate (18) and a sequential shift gate (20), and the housing (4) has fasteners (projections and recesses) (10.2, 10.3, 10.4, 10.5) for fixing the shifting device (2) in the motor vehicle. The housing (4) can be fixed in a first position for right hand driving and in a second position which is rotated by 180 degrees relative to the first position for left hand driving. The fasteners are arranged point-symmetrically in order to rotate the shifting device (2) by 180 degrees, with the result that the respective fastening points coincide with the original fastening points after the rotation and the fasteners are fixed on in each case the same motor vehicle-side fastening points.

A self-centering knob assembly comprising a back disk, a pair of rotary arms, a spring, and a circuit board fixed to the knob shaft, is provided, with the pair of rotary arms and spring disposed between the back disk and circuit board. Each rotary arm defines first and second slots at opposing ends and a center aperture therebetween that rotatably engages the knob shaft. The first slot engages the end stop pin to limit rotation of the rotary arm. The spring defines opposing arms that engage and oppose rotation of respective rotary arms of the pair. The circuit board includes circuitry configured to provide positioning data of the knob shaft, and including a drive pin that, for each rotary arm, engages and carries the second slot in a respective direction of an opposing direction when the knob shaft and thereby the circuit board is rotated in the respective direction.

A self-centering knob assembly comprising a back disk, a pair of rotary arms, a spring, and a circuit board fixed to the knob shaft, is provided, with the pair of rotary arms and spring disposed between the back disk and circuit board. Each rotary arm defines first and second slots at opposing ends and a center aperture therebetween that rotatably engages the knob shaft. The first slot engages the end stop pin to limit rotation of the rotary arm. The spring defines opposing arms that engage and oppose rotation of respective rotary arms of the pair. The circuit board includes circuitry configured to provide positioning data of the knob shaft, and including a drive pin that, for each rotary arm, engages and carries the second slot in a respective direction of an opposing direction when the knob shaft and thereby the circuit board is rotated in the respective direction.

Apparatus and methods for a modular robotic device with artificial intelligence that is receptive to training controls. In one implementation, modular robotic device architecture may be used to provide all or most high cost components in an autonomy module that is separate from the robotic body. The autonomy module may comprise controller, power, actuators that may be connected to controllable elements of the robotic body. The controller may position limbs of the toy in a target position. A user may utilize haptic training approach in order to enable the robotic toy to perform target action(s). Modular configuration of the disclosure enables users to replace one toy body (e.g., the bear) with another (e.g., a giraffe) while using hardware provided by the autonomy module. Modular architecture may enable users to purchase a single AM for use with multiple robotic bodies, thereby reducing the overall cost of ownership.

Disclosed is an articulated harvesting combine of a forward powered processing unit (PPU), a rear grain cart, and an articulation joint connecting the PPU and rear grain cart. Loss sensor pads in the straw discharge stream are graphically displaying to the operator. Articulation joint sensors rear teeth on an articulation joint arcuate beam and are used to display the degree of articulation to the operator. A jog motor permits the operator to move the feed house forwards/backwards to clear blockages. A right hand joystick and a left hand joystick provided control of all combine functions.

A control knob for an appliance includes an outer control ring, a stationary hub, a rotation modulating mechanism coupled to the outer control ring and engaged with an outer surface of the stationary hub, wherein the outer control ring is rotationally operable about the stationary hub at a first rate, an indicial ring positioned around the stationary hub, wherein the indicial ring engages a portion of the rotation modulating mechanism, wherein rotation of the outer control ring at the first rate causes the rotation modulating mechanism to rotate the indicial ring about the stationary hub at a second rate, the second rate being different than the first rate and an encoder shaft positioned within the stationary hub, wherein an inner gearing mechanism extends between an exterior surface of the encoder shaft and one of the outer control ring and the indicial ring.

A control knob for an appliance includes an outer control ring, a stationary hub, a rotation modulating mechanism coupled to the outer control ring and engaged with an outer surface of the stationary hub, wherein the outer control ring is rotationally operable about the stationary hub at a first rate, an indicial ring positioned around the stationary hub, wherein the indicial ring engages a portion of the rotation modulating mechanism, wherein rotation of the outer control ring at the first rate causes the rotation modulating mechanism to rotate the indicial ring about the stationary hub at a second rate, the second rate being different than the first rate and an encoder shaft positioned within the stationary hub, wherein an inner gearing mechanism extends between an exterior surface of the encoder shaft and one of the outer control ring and the indicial ring.

A front loader includes a working tool and an attachment body to which the working tool is attached, including a lock pin configured to attach and fix the working tool, a lock lever configured to move the lock pin between a releasing position and an attaching position, and a latching portion having a retaining mechanism configured to retain the lock lever at the releasing position and another mechanism configured to move the lock lever to the attaching position.