A system and method for positioning a seat arrangement in a vehicle includes moving the seat arrangement forward by a first amount when a certain criteria are met. The criteria may include at least one criterion related to occupancy of a seat directly behind the seat arrangement and at least one criterion related to a likelihood of an impact into the vehicle from behind the seat arrangement. The method may also include not moving the seat arrangement forward by the first amount when at least one of the criteria is not met.

An aircraft passenger seat (100) is fixed to a floor via a seat track fitting (110), and a reclining assembly of the seat is supported by pipes (130, 132) passed through left and right legs (120) and spreaders (170). A linear actuator (300) operates a reclining motion. A curved arm for deformation is provided to a mount (320) on which the actuator (300) is mounted, and a slit (145) is provided in a link plate (140) to which a rod is connected, and in a state where a forward force F is applied, the curved arm deforms and absorbs the impact. An impact absorbing structure is also provided to the legs (120).

The invention relates to a foot prop (1) adapted to be attached to a child safety seat, comprising an elongate component (10), comprising an upper portion (11) and a lower portion (12), wherein the lower portion is slidable relative to the upper portion in longitudinal direction of the elongate component. The foot prop is configured such that a force applied in the longitudinal direction causes the lower portion to automatically move away from the upper portion whenever the force exceeds a predetermined threshold, so that the length of the elongate component is increased; and the foot prop is configured such that the lower and the upper portion are releasably blocked against relative movement towards one another. The invention further relates to a seat base and a child safety seat comprising a foot prop.

Various seating arrangements for a vehicle are described. Generally, the vehicle includes an electromagnetic array featured on a floor of the vehicle. The chair includes base having a plurality of magnets featured thereon. The vehicle generates signals for the electromagnetic array to generate a wave and impart a force on the chair in a determined direction via the plurality of magnets.

An energy-absorbing assembly includes an outer assembly with an outer hollow cylindrical member, and an inner assembly with an inner hollow cylindrical member having an end disposed in the outer member. The inner and outer assemblies are axially movably engaged with each other and define first and second cavities separated by a membrane: a first cavity inside the outer hollow cylindrical member and a second cavity inside the inner hollow cylindrical member. An adjustable-size orifice is disposed between the first and second cavities, and is configured to reduce diameter in response to a stroke motion of the energy-absorbing assembly.

Ramp mounts may facilitate the movement of a passenger seat pan relative to a passenger seat frame during movement of the seat pan between an upright position and a recline position relative to the passenger seat frame. During cycling of the seat pan from the recline position to the upright position, ramp mounts may break. Embodiments of the ramp mount disclosed herein may increase the ramp mount durability so as to reduce the instances of ramp mounts breaking during cycling of the seat pan between the recline and upright positions. Additionally, some embodiments may provide for a ramp mount that has fewer components. Such embodiments may simplify coupling of the ramp mount to a seat pan and may reduce passenger seat system assembly time. Moreover, in some embodiments, the reduced number of components may further reduce manufacturing time and/or coststhereby providing a relatively low cost ramp mount.

A method for adjusting a vehicle seat onboard a vehicle is provided. The method obtains vehicle status data, by a processor communicatively coupled to a plurality of sensors onboard the vehicle; detects a current actuation state of the vehicle seat based on the vehicle status data, by the processor, wherein the current actuation state comprises at least one of a user input actuation state and an emergency actuation state; calculates seat adjustments, by the processor, based on the current actuation state; and actuates the vehicle seat based on the seat adjustments, via an electromagnetic vehicle seat rail device communicatively coupled to the processor.

Methods and apparatus are provided for a shock absorbing vehicle seating system. In one embodiment the seating system includes a seat moveably attached to a vehicle by a seat guide apparatus configured to constrain seat movement to a stroking direction. The system further includes a spring damper with opposed first and second ends, configured to compress along a longitudinal axis extending through the ends in response to an external compressive load, and an energy attenuating component with a deformable portion disposed between a first end and a second end thereof. The spring damper and energy attenuating component are arranged serially with respect to one another, and together form a seat supporting assembly disposed between the seat and the vehicle. The energy attenuating component is configured to deform in a predictable manner in response to a shock load that reaches a predefined threshold value, allowing the seat to stroke in the stroking direction as the energy attenuating component absorbs energy.

Methods and apparatus are provided for a shock attenuation device configured for use in conjunction with a body movably mounted to a structure along a stroking direction to attenuate shock loads associated with a high energy impact event on the structure. The device includes an elongated metal frame with left and right sides symmetrically disposed about a longitudinal slot extending from proximate a first end of the frame to a second end. The frame is mountable to one of the body and structure in an orientation causing the longitudinal slot to align with the stroking direction. A mandrel mountable to the other one of the body and structure is positioned in the frame at one end of the slot. The mandrel has width and length dimensions measured in the plane of the frame, wherein a maximum width of the mandrel is greater than a width of the slot.

A system and method are provided for controlling an interior configuration of a vehicle following a collision. Sensor data that includes, or is derived from data that includes, data collected by one or more sensors is received, and a vehicle accident condition indicative of an accident having occurred is detected by processing the sensor data. After detecting the vehicle accident condition, an actuator component is caused to prevent a passenger from adjusting an interior vehicle component outside a predetermined range of physical configurations, while allowing the passenger to adjust the interior vehicle component within the predetermined range of physical configurations.