An energy absorbing headrest for a vehicle includes a base member, a frame pivotally mounted to the base member, and a biasing member mounted between the base member and the frame. The biasing member provides a biasing force to the frame. A release mechanism is mounted to the base member and retains the frame against the biasing force. The release mechanism selectively releases the frame upon receipt of a release signal.

A headrest apparatus in accordance with this disclosure supports the head and cervical spine during driving and driving events. The headrest apparatus including a headrest, one or more rods extending from the headrest, and a rotation mechanism located in the headrest coupled between the headrest and the plurality of rods. The headrest may include at least a front face, a rear face opposite the front face, a bottom face located between a lower portion of the front face and a lower portion of the rear face, and two side faces located opposite each other between the front face and the rear face. In a first position a profile of the front face may conform to a normal cervical spine curvature of an occupant in a seated position.

A headrest apparatus in accordance with this disclosure supports the head and cervical spine during driving and driving events. The headrest apparatus including a headrest, one or more rods extending from the headrest, and a rotation mechanism located in the headrest coupled between the headrest and the plurality of rods. The headrest may include at least a front face, a rear face opposite the front face, a bottom face located between a lower portion of the front face and a lower portion of the rear face, and two side faces located opposite each other between the front face and the rear face. In a first position a profile of the front face may conform to a normal cervical spine curvature of an occupant in a seated position.

The present disclosure relates to an apparatus for adjusting a headrest wing, and more particularly, to an apparatus for adjusting a headrest wing in which a wire is used to make operating forces at the time of pushing and pulling a headrest wing to be different so that convenience is given to a user.

A head restraint for a seat being adjustable in a vertical direction, and angularly adjustable with regard to lateral portions of the head restraint. A mechanism providing this adjustability is a linear and rotational locking mechanism with a shaft and a slide. The slide is selectively slidably and rotatably mounted on the shaft. The slide has a locked state which linearly and rotationally fixes the slide on, and with respect to, the shaft. The slide has a release state where the slide is linearly and rotatably movable on the shaft. The slide is fixable in a plurality of linear and rotational positions on the shaft in the locked state. The number of linear and rotational positions on the shaft is considered infinite since for all practical purposes, the slide is not restricted to individual discrete positions, but is continuously adjustable to practically any linear and rotational position.

A head restraint for a seat being adjustable in a vertical direction, and angularly adjustable with regard to lateral portions of the head restraint. A mechanism providing this adjustability is a linear and rotational locking mechanism with a shaft and a slide. The slide is selectively slidably and rotatably mounted on the shaft. The slide has a locked state which linearly and rotationally fixes the slide on, and with respect to, the shaft. The slide has a release state where the slide is linearly and rotatably movable on the shaft. The slide is fixable in a plurality of linear and rotational positions on the shaft in the locked state. The number of linear and rotational positions on the shaft is considered infinite since for all practical purposes, the slide is not restricted to individual discrete positions, but is continuously adjustable to practically any linear and rotational position.

A power actuated tilting head restraint assembly includes a head restraint mountable to a vehicle seat. The assembly also includes a power actuation assembly including an electric motor to adjust a rotational position of the head restraint, the electric motor programmed to adjust the rotational position at a first speed during manual adjustment of the head restraint and at a second speed upon detection of an imminent impact by an impact detection system, the second speed greater than the first speed.

A power actuated tilting head restraint assembly includes a head restraint mountable to a vehicle seat. The assembly also includes a power actuation assembly including an electric motor to adjust a rotational position of the head restraint, the electric motor programmed to adjust the rotational position at a first speed during manual adjustment of the head restraint and at a second speed upon detection of an imminent impact by an impact detection system, the second speed greater than the first speed.

A vehicle with a vehicle seat arranged in the vehicle interior, which is paired with an occupant protection system, which has at least one crash detection sensor system that detects at least one acceleration value in the event of a crash, which influences the vehicle in the event of a crash so that inertial forces act on the vehicle seat connected to the vehicle and on the occupant sitting on the vehicle seat on the basis of an acceleration value, wherein the acceleration value is used for the crash-adaptive specification, over time, of said displacement travel of the occupant secured with a belt system on the vehicle seat. A total displacement travel of the vehicle seat in the travel direction comprises an additional, exclusively crash-active displacement travel adjoining a displacement travel of the vehicle seat for seat length adjustment in the travel direction.

A vehicle with a vehicle seat arranged in the vehicle interior, which is paired with an occupant protection system, which has at least one crash detection sensor system that detects at least one acceleration value in the event of a crash, which influences the vehicle in the event of a crash so that inertial forces act on the vehicle seat connected to the vehicle and on the occupant sitting on the vehicle seat on the basis of an acceleration value, wherein the acceleration value is used for the crash-adaptive specification, over time, of said displacement travel of the occupant secured with a belt system on the vehicle seat. A total displacement travel of the vehicle seat in the travel direction comprises an additional, exclusively crash-active displacement travel adjoining a displacement travel of the vehicle seat for seat length adjustment in the travel direction.