An armrest serves as an elbow rest of a seat device in a case where the armrest is tilted forward and serves as a backrest of the seat device in a case where the armrest is raised rearward. The armrest includes an armrest pad configured to elastically support a load applied to a backrest surface forming a part of a front surface of the seat device in a case where the armrest serves as the backrest, an armrest cover configured to cover the armrest pad, a protrusion that protrudes from the backrest surface of the armrest cover and abuts against an upper surface of a seat cushion of the seat device in a case where the armrest is tilted forward, and a cutout portion formed in a region that overlaps the protrusion of the armrest cover in a thickness direction of the armrest.

A vehicle seat partitioning system includes a partition structure attached to a first and a second backrest structure of a vehicle seat unit. The first and/or second backrest structure are arranged to be foldable between raised and lowered positions in relation to a common seating structure. The partition structure has a first and a second side edge, the first side edge connected to the first backrest structure and the second side edge connected to the second backrest structure. The system further includes a first track unit arranged on the first backrest structure and/or a second track unit arranged on the second backrest structure. The first side edge has a first connection member connected to and movably arranged in relation to the first track unit and/or the second side edge has a second connection member connected to and movably arranged in relation to the second track unit.

A vehicle seat assembly includes a seatback rotationally coupled to a base at a seat pivot. A securing pin is coupled with the seatback. An inertial latch is operable about a latch pivot to define an idle position defined by the inertial latch biased distal from the securing pin, and a deployed position defined by an opposing directional force biasing the inertial latch into selective engagement with the securing pin wherein the seatback is maintained in a predetermined rotational position. A guide latch is biased against the inertial latch and having an idle notch and a deployed notch. The idle notch selectively maintains the inertial latch in the idle position. The deployed notch secures the inertial latch in the deployed position in response to the opposing directional biasing force.

A dual gear type recliner device includes a recliner device having a hinge structure applied to an intermediate section of a seat and configured to form a fixed end hinge point with a seatback frame of a seatback and form a free end hinge point with a cushion frame and configured to impart movements of folding and unfolding to the seatback. The dual gear type recliner device further includes a controller configured to output motor control signals to a cushion motor and a seatback motor and to generate the movements of the folding and the unfolding. Therefore, two drivers are integrated into one device to improve the degree of freedom in designing an outer circumference of the seat and built in a gear box to perform a large angle adjustment so that a back table mode and a leg rest mode can be easily implemented.

An occupant support includes a seat bottom and a seat back coupled to the seat bottom and arranged to extend upwardly away from the seat bottom in a normal-seating configuration. The seat back is pivotable relative to the seat bottom between a plurality of positions. The seat back may be changed from an upright position to a folded-forward position.

A set of seats for an automotive vehicle, where the set of seats comprises a first seat and a second seat, where the first seat is provided with a first seatback and a first seat bottom, where the second seat is provided with a second seatback and a second seat bottom, the set of seats is configured in order to have: a road configuration in which the first seat bottom extends substantially horizontally and the first seatback extends substantially vertically; and a relaxed configuration in which the second seat is in a table position in which the second seatback extends substantially horizontally and the second seat bottom extends substantially vertically, where the second seatback and the second seat bottom delimit a knee space.

Aspects of the disclosure relate to vehicles capable of autonomous driving. These vehicles may include seats for accommodating different numbers of passengers. In some cases, the seats may be reconfigurable. For instance, a vehicle may include a first row of seating having a first, passenger use configuration. The first row may allow a passenger to sit in a seat of the first row of seating and access user input controls for the vehicle. The first row of seating may also have a second, folded configuration where the first row is in a folded configuration and no longer usable for passenger seating. The vehicle may also have a second row of seating. When the first row of seating is in the second, folded configuration, the second row of seating may still be usable for seating and may include additional legroom for the passenger as compared to when the first row of seating is in the first passenger use configuration.

The present invention provides an aircraft seat unit comprising a main seat, and a companion seat, the main seat and the companion seat facing each other, wherein the companion seat comprises a seat pan, providing a seat pan surface, and a moveable seat element, the moveable seat element being moveable in relation to the seat pan between a stowed position, in which the companion seat provides an additional support surface for a main passenger in the main seat, and a deployed position, in which the moveable seat element provides a backrest surface for a companion passenger in the companion seat. The invention also provides a method of deploying and a method of stowing a companion seat.

A vehicle seating arrangement includes a first seating assembly, a second seating assembly, and a third seating assembly. The second seating assembly is adjacent to the first seating assembly. Each of the first, second, and third seating assemblies include a seat and a seatback. The seatbacks are pivotably coupled to their respective seats such that the seatbacks are each pivotable between a use position and a forward-dumped position. A remote control is positioned on at least one of the first seating assembly, the second seating assembly, and the third seating assembly. Actuation of the remote control in a first direction transitions the seatback of the first seating assembly toward the forward-dumped position. Actuation of the remote control in a second direction transitions the seatback of at least one of the second and third seating assemblies toward the forward-dumped position.

A vehicle seating assembly has a seat, a seatback and a bracket extending between the seat and the seatback with a first pivotable coupling between the bracket and the seat, a second pivotable coupling between the bracket and the seatback, and a sector gear portion with a gear assembly including a spur gear. The sector gear portion is disposed along an edge of the bracket, wherein the spur gear is rotatable to engage the sector gear portion of the bracket to move the bracket from a first position to a second position to move the second pivotable coupling from a primary position to a secondary position.