A vehicle assembly includes a vehicle body including a frame backing member, and a vehicle seat including a seat back having a seat back frame. An energy attenuating member is positioned in a space between the frame backing member and the seat back frame in a front-rear direction of the vehicle assembly. The energy attenuating member is connected to the frame backing member. A mounting bracket is connected to the energy attenuating member. A connection support portion releasably connects the mounting bracket to an upper portion of the seat back frame in a height direction of the vehicle assembly.

Method and apparatus are provided for a vehicle seat weight detection system utilizing a metal deformation type energy attenuating device disposed in a load path between a seat and a vehicle structure. The energy attenuating device includes a weight sensing portion with a first end connected to one of the seat or vehicle structure, and a second end configured to transfer the seat weight load to a deformable portion of the energy attenuating device connected to the other of the seat and vehicle structure. An aperture in the weight sensing portion between the first and second ends divides a region adjacent the aperture into first and second sides. A slot intersecting the aperture and lying on a plane generally perpendicular to the load path divides the second side into upper and lower halves. A sensor on a surface of the first side of the weight sensing portion is configured to detect strain variations in the surface and produce a calibrated weight signal.

A vehicle includes a vehicle ceiling, a vehicle floor, and a vehicle seat assembly that couples with the vehicle ceiling and the vehicle floor. The vehicle seat assembly includes a seat support that supports a vehicle seat from the vehicle ceiling, a base that forms a slip joint with the seat support from the vehicle floor, and a set of limit straps constructed and arranged to limit deflection of the slip joint in response to deformation between the vehicle ceiling and the vehicle floor (e.g., a vehicle collision, deformation between the vehicle ceiling and the vehicle floor possibly due to a blast, etc.). Each limit strap of the set of limit straps has a first end that attaches to a portion of the slip joint and a second end that attaches to the vehicle floor.

The invention relates to a device for influencing a backward movement of a seat, in particular a backrest part of the seat, with at least one deformation element arranged in a hinged area of the seating part of the seat, the deformation element being configured such that the deformation element can be deformed due to a force acting on the seating part and/or the back part at a predefined torque curve. The invention also relates to a seat, in particular a vehicle seat, comprising a seating part, a backrest part and the type of device.

Disclosed is a seat rail pair (2) for adjustment of a vehicle seat (8), in particular of a motor vehicle seat, in an adjustment direction (x), comprising a guide rail (10) extending parallel to the adjustment direction (x) for fastening to a vehicle floor, and a fastening rail (21), which is adjustably guided on the guide rail (10) in the adjustment direction (x) for fastening the vehicle seat (8), wherein an energy absorber element (5) is provided in a path, which introduces the force acting on the vehicle seat (8) into the vehicle structure, which energy absorber element permits a movement of the vehicle seat in the adjustment direction (x) under plastic deformation when a predetermined value of the force is exceeded.

The present description relates to an occupant protecting system for a vehicle, a vehicle comprising such an occupant protecting system and an occupant protecting method for such a vehicle. The occupant protecting system comprises a seat assembly, a sensor unit, an actuator unit and a control unit. The sensor unit is configured to generate crash monitoring data of the vehicle. The control unit is configured to determine a crash type based on the crash monitoring data in case of a collision of the vehicle. The actuator unit comprises a pyrotechnic element. The actuator unit is arranged at the seat assembly and capable to adjust a position of the seat assembly. The control unit is configured to cause the actuator unit based on the crash type.

A combination adaptive energy absorption and emergency flotation device for positioning beneath a plurality of seat pans of a seat assembly in an aircraft seating application. The device includes a plurality of fluidly coupled inflatable elastic bladders, at least one constrictor valve fluidly coupling at least two adjacent ones of the plurality of inflatable elastic bladders allowing fluid flow therethrough in response to predetermined pressure on the device from the plurality of seat pans, and a fluid supply source fluidly coupled to the plurality of inflatable elastic bladders for outputting a positive flow of fluid to the plurality of inflatable elastic bladders, wherein the adaptive energy absorption device is detached from the plurality of seat pans to allow removal from beneath the plurality of seat pans for use as an emergency flotation device.

The invention relates to a device for influencing a backward movement of a seat, in particular a backrest part of the seat, with at least one deformation element arranged in a hinged area of the seating part of the seat, the deformation element being configured such that the deformation element can be deformed due to a force acting on the seating part and/or the back part at a predefined torque curve. The invention also relates to a seat, in particular a vehicle seat, comprising a seating part, a backrest part and the type of device.

The present invention is an elevated vehicle system. The preferred embodiment of the present invention has a steering wheel, an engine, a plurality of seats, a plurality of windows, and a plurality of wheels. The steering wheel rotates to turn the plurality of wheels. The engine has a transmission and power system. The power system is a battery that provides power to various components within the present invention. The plurality of seats has a seatbelt, a hydraulic lift, and a plurality of buttons. The seatbelt is a flexible, nonelastic material that holds a passenger in their seat. The hydraulic lift is a mechanical system that lifts and lowers the seat. The plurality of buttons is used to control the height positioning of the seat. Additionally, a sensor is used to control the raising and lowering of the seats.

A rotorcraft seating assembly includes a seat base supporting a seat bucket, the seat base having left- and right-side panel portions. Each side panel portion has a linear bucket guide channel set into its inside face (including an upper portion for adjusting the seat bucket relative to the seat base for pilots of varying heights, and a lower portion for energy attenuation (EA) stroking in response to a crash event) and a bucket guide slot set into its outside face (including a linear upper portion corresponding to the range of adjustment of the seat bucket and a curved lower portion allowing the seat bucket to translate forward and away from the seat base during EA stroking). The curved outer bucket guide slot allows for the required EA stroking distance within a minimal vertical space between the seat bucket and the flight deck floor.