A vehicle seat arrangement has a vehicle seat for attaching to a vehicle structure of a vehicle, in particular a motor vehicle, with a lower seat part having a seat structure and with a seat back. The lower seat part is mounted or can be mounted in a longitudinally displaceable manner on the vehicle structure by a seat console, wherein at least the seat back is adjustable from a sitting position into a resting or lying position, and wherein between the lower seat part and the vehicle structure an energy absorption device is provided. In the event of a collision of the vehicle with an obstacle, the energy absorption device permits a braked relative movement along a braking path between the vehicle seat, which persists in a forwards movement due to inertia, and the vehicle structure, which is braked due to the collision. In the normal state, the vehicle seat is locked relative to the vehicle structure by a locking device and the locking is released in the event of a collision. The locking device is designed such that the locking is released and the longitudinal displaceability of the vehicle seat is enabled before the mass-induced forces of inertia of the body of a person lying on the vehicle seat are completely supported on the seat structure of the lower seat part, and therefore the body only enters into force-transmitting contact with the seat structure when the vehicle seat is already moving forwards relative to the vehicle structure.

A long rail assembly is attached to a floor within an automotive vehicle for transposing vehicle seats between a plurality of positions. The long rail assembly includes a rail drive assembly configured to travel along an interior cavity of a fixed long rail. The fixed long rail has a generally U-shaped cross-section and includes a pair of flanges with mating teeth extending inwardly from a pair of outer walls. The rail drive assembly includes a retention latch and a wheel assembly coupled adjacent a first and a second end of the rail drive assembly. The rail drive assembly is operable between a use position and a loaded position in which at least one of the retention latches engages the mating teeth to interlock the rail drive assembly and the fixed long rail in response to forces causing upward loading on the rail drive assembly.

A seating system for a vehicle includes a seat back and a seat bottom selectively rotatable between a design position and a stowed position. A latch arrangement has a first cam with first and second surfaces, a support structure with first and second surfaces, and a second cam. The latch arrangement has a first locking position wherein the first surface of the first cam engages the first surface of the support structure so that movement of the seat bottom from the design position to the stowed position is inhibited. The latch arrangement also has a second locking position wherein the second cam engages a portion of the support structure so that movement of the seat bottom from the stowed position to the design position is inhibited.

A rail assembly includes a track assembly with a retaining lip and a carriage assembly that is received within the track assembly. The carriage assembly includes a body portion, an exterior surface of the body portion, and a retaining bracket fastened to the exterior surface. The retaining bracket extends outwardly from the point at which the retaining bracket is fastened to the exterior surface. The retaining bracket defines a notch that receives the retaining lip of the track assembly.

A rail assembly can include a track assembly, an elongate shaft mounted to the track assembly, and a carriage assembly received within the track assembly. The carriage assembly can include a slider bracket. The slider bracket includes a first ramp portion and a second ramp portion. The first and second ramp portions are disposed on opposite sides of the slider bracket. The first and second ramp portions each define a receiving aperture. The elongate shaft is received through the receiving apertures of the first and second ramp portions.

A knee bolster assembly for a vehicle seat includes a knee bolster moveably mounted in proximity to the vehicle seat, the knee bolster selectively moveable between a first position, wherein a passenger is able to enter and exit the vehicle seat, and a second position, wherein the knee bolster is positioned directly in front of a seating surface of the vehicle seat, such that legs of a passenger seated within the vehicle seat are positioned between the seating surface of the vehicle seat and the knee bolster, the knee bolster adapted to prevent an occupant of the vehicle seat from sliding forward off the vehicle seat and restrict any hyper-extending of their lower legs due to forward inertia, and an energy absorbing device adapted to absorb energy when knees or legs of a passenger within the vehicle seat impact the knee bolster.

The dynamic retention system may include at least one plunger assembly including a plunger base coupled to a base assembly of an aircraft seat and a spring-loaded plunger coupled to a seat frame. The spring-loaded plunger may be configured to contact the plunger base. The dynamic retention system may include at least one hook receptacle coupled to the base assembly, and at least one structural hook coupled to the seat frame. The at least one hook receptacle may be configured to receive the at least one structural hook responsive to the spring-loaded plunger contacting the plunger base. The seat frame may be coupled to the base assembly via an actuation assembly. The aircraft seat may be actuatable between a first position and at least a second position.

A seating system for at least one occupant in a vehicle interior is disclosed. The seating system may provide a seat assembly with a base assembly configured to be mounted in the vehicle interior and a seat structure configured to be coupled to the base assembly and providing a seat configured for movement relative to the base assembly. Movement of the seat relative to the base assembly may be made by at least two of recline movement or swivel movement or tilt movement. Recline movement may be generally translating movement of the seat structure. Swivel movement may be rotational movement of the seat structure. Tilt movement may be generally translating movement of the seat structure transverse to recline movement. The base assembly may be a mechanism configured to facilitate movement of the seat structure relative to the base assembly.

A vehicle seat console has at least one vehicle-mounted guiding element, at least one seat-mounted guiding element that runs parallel to the vehicle-mounted guiding element, and a longitudinal adjustment mechanism on which a driving device acts via a transmission mechanism and which is designed to cause a relative adjustment between the vehicle-mounted guiding element and the seat-mounted guiding element. The vehicle seat console is characterized in that the longitudinal adjustment mechanism and/or the transmission mechanism is/are equipped with at least one energy absorption device which is configured to dampen abrupt relative movements between the vehicle-mounted guiding element and the seat-mounted guiding element.

A motor-vehicle seat longitudinal adjuster (10) includes a seat part seat rail (14) and a vehicle structure seat rail (16). The seat rails (14, 16) are slidable relative to each other in a longitudinal direction (x) and engage each other forming an inner channel (18). An anchor (20), fastened to the second seat rail (16), is arranged in the inner channel (18). A reinforcing profiled element (22), fastened to the first seat rail (14), is arranged in the inner channel (18). The reinforcing profiled element (22) and the anchor (20) are spaced apart from each other and engage with each other in response to a defined application of force (a crash). The reinforcing profiled element (22) has a connecting section (24) extending out of the inner channel (18) toward a rear for connection to a rear end surface (8) of a seat frame side part (6).