Disclosed is an armrest assembly for a vehicle seat such as a pilot seat positioned in an aircraft cockpit. The armrest assembly generally includes a pivoting armrest and an arm pad repositionable relative to the armrest to change the arm pad width. The arm pad includes two functional sides each having a different width dimension. The arm pad is coupled to the armrest such that sequential translational and rotational motion of the arm pad moves one of the first and second sides into a use position atop the armrest and the other of the first and second sides into an out of use position alongside the armrest. The armrest assembly according to the present disclosure is ideal for use in tight quarters within the flight deck, among other installation environments requiring a functional armrest.

A seating assembly of a row of seating of a vehicle comprising: (a) a seat including a frame having an inboard side; and (b) an inboard armrest assembly comprising: (i) a lower bracket attached to the inboard side of the frame of the seat; (ii) an upper bracket pivotally coupled to the lower bracket about a pivot axis extending generally forward-to-rearward; and (iii) a cushion unit mounted upon the upper bracket, the upper bracket having an inboard position and, upon application of an outboard force to the upper bracket, an outboard position further outboard than the inboard position, the upper bracket transitioning from the inboard position to the outboard position about the pivot axis. The outboard force moving the cushion unit to the outboard position removes the inboard armrest assembly from projecting into a center aisle of a vehicle.

An autonomous vehicle may include a plurality of seats rotatably provided on a vehicle floor of the vehicle; a console device rail provided between the plurality of seats and extending in a longitudinal direction thereof; and a console device mounted on the console device rail and configured for sliding between the plurality of seats along the console device rail, the console device mounted on the console device rail via a rotation shaft to be rotatable about the rotation shaft relative to the console device rail, wherein when the console device is slid along and rotated relative to the console device rail during rotation of the seat, the interference by the seats and the console device is prevented.

A working machine according to an embodiment of the present invention includes an operator seat, an operation base arranged in front of the operator seat, an operation member arranged on the operation base and configured to be gripped and moved, and an armrest member extending from the operation base toward a side of the operator seat.

An armrest arrangement having an armrest structure supported in a pivotably movable manner relative to a fixed carrier structure and having an inclination adjustment device which has at least one rotationally movably supported adjustment element which can be displaced along a fixed guide path. The armrest arrangement has an actuation device for activating the inclination adjustment device which is operationally connected to a mechanical coupling in order to release or to block the adjustment element for a rotational movement. A mechanical forced control device which switches an activation of the coupling by the actuation device for a limited inclination angle range of the armrest structure relative to the carrier structure without effect is associated with the coupling.

An occupant protection apparatus includes: a vehicle seat arranged in an inner space of a side wall of a vehicle; a side airbag device provided in the side wall or the vehicle seat and including a side airbag to be inflated and deployed between the side wall and the vehicle seat. The vehicle seat includes: a pressure-receiving portion to receive a load from an occupant seated on the vehicle seat; and a frame to support the pressure-receiving portion. The occupant protection apparatus further comprising an electronic control circuit configured to perform moving the pressure-receiving portion so that the occupant is pushed away from the side wall before the occupant comes into contact with the side airbag at an activation time when the side airbag device is activated by an impact acting on the side wall from an outside of the vehicle and the side airbag is inflated and deployed.

The present disclosure relates to an armrest arrangement for a vehicle seat including an armrest and a seating portion connection for connecting the armrest to a seating portion in such a way that the armrest can be adjusted via a kinematic construction in relation to the seating portion.

A system may include a seat assembly. The seat assembly may include a seat base, a seat portion mounted to the seat base, and an armrest assembly configured to be in an up position or a down position. The armrest assembly may include a handle operable by a user to lock or unlock at least one functionality of at least one adjustable seat assembly feature. Operation of the handle may be configured at least to: unlock the at least one functionality of at least one adjustable seat assembly feature while locking the armrest assembly from moving between the up position and the down position.

Disclosed is an armrest assembly for a vehicle seat such as a pilot seat positioned in an aircraft cockpit. The armrest assembly generally includes a pivoting armrest and an arm pad repositionable relative to the armrest to change the arm pad width. The arm pad includes two functional sides each having a different width dimension. The arm pad is coupled to the armrest such that sequential translational and rotational motion of the arm pad moves one of the first and second sides into a use position atop the armrest and the other of the first and second sides into an out of use position alongside the armrest. The armrest assembly according to the present disclosure is ideal for use in tight quarters within the flight deck, among other installation environments requiring a functional armrest.

A motion sickness mitigation method for the purposes of mitigating motion sickness of a vehicle occupant travelling in a motor vehicle includes moving at least a portion of a backrest, a portion of a seat squab, a portion of a head restraint, a portion of an armrest and/or a portion of a footrest as a function of a detected and/or an anticipated driving situation of the motor vehicle, in each case proceeding from a starting position in at least one spatial direction. The movement is situational on the basis of an actual or anticipated trajectory of the motor vehicle.