A system for a vehicle includes a seat belt height adjuster and a sensor configured to determine eye location of a driver of the vehicle. A control module is in communication with the sensor and the seat belt height adjuster. The control module is programmed to adjust a position of the seat belt height adjuster based at least on the eye location.

A vehicle includes a vehicle body. The vehicle includes a first track and a second track supported by the vehicle body. The first track and the second track are elongated along a longitudinal axis. The vehicle includes a third track and a fourth track supported by the vehicle body. The third track and the fourth track are elongated along a vertical axis. The vehicle includes a harness having a first webbing movable along the first track, a second webbing movable along the second track, a third webbing movable along the third track, and a fourth webbing movable along the fourth track.

A sliding mechanism a first part and a second part adapted for sliding translation within the first part. A guide rib structure is included on the first part to constrain a lateral motion of the second part, including one or more ribs each defining at least one inclined plane. The guide rib structure may be a continuous rib member defining a sinusoidal or trapezoidal wave pattern, or may include a plurality of ribs each defining an inclined plane.

A sliding mechanism includes a first part and a second part adapted for sliding translation within the first part. A bracket attached to the first part includes a bracket guide rib structure for constraining a lateral motion of the second part, including a rib defining an unbroken interface surface for the second part. The bracket guide rib structure may include a continuous rib member defining a continuous a continuous planar slider interface surface, a sinusoidal wave pattern, or a trapezoidal wave pattern. The sinusoidal wave pattern and the trapezoidal wave pattern may include a plurality of waves having a same or a different wave frequency.

A buckle device including: a buckle that is configured to engage with a tongue of a seatbelt device, a cover member that includes a first member and a second member for assembly together, and at which the buckle is provided; an elongated member that is anchored to the first member at a length direction leading end portion of the elongated member, and a retention section that is provided at the first member, and that is configured to engage a portion of the elongated member that is further toward a length direction base end side of the elongated member than the length direction leading end portion.

A seat includes a seat base including a first side and a second side, and a seat back including a first side portion and a second side portion. The seat back is pivotable between an upright configuration and a highly reclined configuration. A torso belt system is arranged at the seat system. The torso belt system includes a retractor mechanism positioned adjacent to one of the seat base and the seat back. An amount of flexible webbing includes a first end anchored at the retractor mechanism and a second end. A selectable anchor is connectable to the second end of the amount of flexible webbing. The selectable anchor is selectively arranged in a first position at the seat base when the seat back is in the upright seating configuration and in a second position at the seat back when the seat back is in the highly reclined seating configuration.

A vehicle includes a vehicle body. The vehicle includes a first track and a second track supported by the vehicle body. The first track and the second track are elongated along a longitudinal axis. The vehicle includes a third track and a fourth track supported by the vehicle body. The third track and the fourth track are elongated along a vertical axis. The vehicle includes a harness having a first webbing movable along the first track, a second webbing movable along the second track, a third webbing movable along the third track, and a fourth webbing movable along the fourth track.

A seat includes a seat base including a first side and a second side, and a seat back including a first side portion and a second side portion. The seat back is pivotable between an upright configuration and a highly reclined configuration. A torso belt system is arranged at the seat system. The torso belt system includes a retractor mechanism positioned adjacent to one of the seat base and the seat back. An amount of flexible webbing includes a first end anchored at the retractor mechanism and a second end. A selectable anchor is connectable to the second end of the amount of flexible webbing. The selectable anchor is selectively arranged in a first position at the seat base when the seat back is in the upright seating configuration and in a second position at the seat back when the seat back is in the highly reclined seating configuration.

A web position and attenuation apparatus includes an elastically deformable body having a first end and a second end opposite the first end, one of the first and second ends configured to be affixed to a frame of a movable vehicle, a web coupling member received on the elastically deformable body, the web coupling member movable relative to, and positionable along, the elastically deformable body, the web coupling member defining a web slot, and a flexible web extending through the web slot, the flexible web part of a restraint system to restrain an occupant of a vehicle seat mounted within the vehicle. The elastically deformable body is responsive to dynamic loads applied by the occupant through the flexible web to the web coupling member to absorb energy and attenuate tension in the flexible web via elastic deformation of the elastically deformable body.

Method for controlling a vehicle including a smartphone-engaging coupling element. Data about operational status of the vehicle is transferred from one or more vehicle-resident systems to a smartphone when the smartphone is engaged with the coupling element. Commands are received by the vehicle from the smartphone when the smartphone is engaged with the coupling element, which commands being based in part on data previously transferred from the vehicle-resident system(s) to the smartphone when the smartphone is engaged with the coupling element. A vehicular system, e.g., seat positioning system, mirror positioning system, passenger compartment temperature control system, route guidance or navigation system, changes its operation in accordance with the commands received by the vehicle from the smartphone when the smartphone is engaged with the coupling element.