Disclosed is a low-posture zero-gravity seat frame capable of being adjusted in multiple directions. A first left front connecting rod has a lower end hinged to a left slide rail front bracket and an upper end hinged to one end of a second left front connecting rod, and the other end of the second left front connecting rod is hinged to a front horizontal tube. A second toothed plate driving device is able to adjust the height of a seat framework through the movement of a rear horizontal tube. A seatbelt retractor is disposed below the seat framework. The seat frame can realize zero-gravity adjustment, occupies a small space, and can fulfill low-posture seat arrangement.

A device for reducing kinetosis-related disorders of an occupant of a vehicle includes a vehicle seat with a headrest. A seat belt is assigned to the vehicle seat which is configured to increase a connection of the occupant to the vehicle seat before an onset of an acceleration. An actuator system is coupled to the headrest which is configured to move the headrest automatically, at least in sections, counter to an expected direction of an acceleration of a head of the occupant before the onset of the acceleration. The seat belt is tightenable by a reversible belt tensioner before the onset of the acceleration.

A seat system includes: a base; a seatback; at least one recliner connecting the base and the seatback to each other for pivoting of the seatback relative to the base; a slider coupled to the base and configured for sliding engagement with a track having a detent region and a tilt-and slide region; and an electronic controller, wherein without mechanical interlock between the recliner and the slider, the electronic controller causes the recliner to place the seatback in a non-passenger position when the slider is within the tilt-and-slide region, and causes the recliner to place the seatback in a passenger position when the slider is within the detent region.

Described are headrests with integrated entertainment systems. The headrest includes a shell that is coupled to a seat through a headrest mount that has at least one degree of freedom of movement. The headrest shell also supports a visor with at least one side arm and a display span that may rotate between stowed and deployed positions. A neutral position mechanism supports the headrest in a neutral position and provides resistance to movement between the headrest and the passenger seat. The attachment of the visor to the headrest shell may also include an adjustment slot to allow fore and aft translation of the visor with respect to the headrest shell. The fore and aft translation of the visor allows for positioning the visor at different focal lengths, and provides extra clearance for the visor as it moves between stowed and deployed positions.

A seat assembly is provided with a seat bottom, a seat back, and a plurality of sensors operably connected to at least one of the seat bottom and the seat back to detect a seating condition of a seated occupant. A controller is in electrical communication with the plurality of sensors. The controller is programmed to receive input from the plurality of sensors indicative of a seating condition of the seated occupant. The seating condition is compared to a predetermined seating condition. An output indicative of the predetermined seating condition is transmitted. An actuator is in electrical communication with the plurality of sensors and operably connected to at least one of the seat bottom and the seat back for adjustment of at least one of a plurality of settings of the seat assembly. The actuator is adjusted to a predetermined setting corresponding to the predetermined seating condition.

The present disclosure relates to the brake device of the power swivel seat that ensures to have no clearance in the rotational direction during operation of the swivel seat, resulting in improved stability of the operation, and minimized generation of operating noise. Disclosed is a brake device of a power swivel seat including: a brake ring connected to a swivel fixing part; a brake wedge connected to a swivel rotating part; a brake roller and a brake spring installed in a wedge space formed between an inner circumferential surface of the brake ring and an outer circumferential surface of the brake wedge; and an unlocking block installed to rotate the brake wedge in a direction allowing to release lock caused by the brake roller in the wedge space.

A seating assembly includes a seatback having a frame and a cushion assembly. A cushion carrier includes a lower member defining a frame receiving cavity. A first set of ribs extend across the frame receiving cavity in a direction perpendicular to a longitudinal extent of the lower member. The first set of ribs extend between the lower member and a lower brace of the frame. A second set of ribs are parallel with the first set of ribs. The second set of ribs are longer than the first set of ribs.

Provided is an automatic pop-up device for a vehicle legrest having the following effects. A seatback reclining mechanism, a tilting mechanism, and a legrest deployment mechanism are formed as a simple integrated mechanism configured to adjust a relaxation position of a passenger, and the integrated mechanism allows the legrest to be automatically deployed when a reclining operation of a seatback and a tilting operation of a seat cushion are performed together, thereby reducing the number of components, costs, and weight. Additionally, provided is a single switch configured to adjust the relaxation position of the passenger, thereby improving the convenience of a switch operation of adjusting the relaxation position of the passenger.

A vehicle seating assembly includes a seatback. A back panel includes a front closeout panel. A carrier supports the seatback and includes an upper thoracic region having a peripheral support. A peripheral gap is defined between the front closeout panel and the upper thoracic region. A bottom portion of the upper thoracic region includes a lower wall having a sinusoidal configuration. A lower lumber region includes a peripheral support. A peripheral gap is defined between the front closeout panel and the lower lumber region. An upper portion of the lower lumbar region includes an upper wall having a sinusoidal configuration. A plurality of concave connectors couple the lower wall of the upper thoracic region with the upper wall of the lower lumber region.

A vehicle seat is provided herein. The vehicle seat includes a cushion disposed within a seating member having at least one inflatable first bladder for selectively adjusting the firmness of the cushion. An inflatable second bladder is separated from a support surface of the seating member by the first bladder and fluidly connected to the first bladder. A vehicle seat hip pivot point is maintained when adjusting the firmness of the cushion by increasing the pressure in the second bladder when the pressure in the first bladder is selectively decreased, and by decreasing the pressure in the second bladder when the pressure in the first bladder is selectively increased.