An apparatus for protecting a passenger in a vehicle and a control method thereof. The apparatus includes a collision detection unit that detects a predicted collision state and a collision state of a vehicle; a seat belt driving unit that adjusts tension of a seat belt according to an operation mode; an airbag driving unit that deploys each of a plurality of airbags according to a driving signal; a capturing unit that captures images of an interior of the vehicle; an image processing unit that extracts passenger information by processing images inputted from the capturing unit; and a control unit that recognizes a passenger type and a seating position based on the passenger information, operates the seat belt driving unit by setting the operation mode, adjusts deployment time points of the plurality of airbags, and outputs the driving signal to the airbag driving unit.

An apparatus for protecting a passenger in a vehicle and a control method thereof. The apparatus includes a collision detection unit that detects a predicted collision state and a collision state of a vehicle; a seat belt driving unit that adjusts tension of a seat belt according to an operation mode; an airbag driving unit that deploys each of a plurality of airbags according to a driving signal; a capturing unit that captures images of an interior of the vehicle; an image processing unit that extracts passenger information by processing images inputted from the capturing unit; and a control unit that recognizes a passenger type and a seating position based on the passenger information, operates the seat belt driving unit by setting the operation mode, adjusts deployment time points of the plurality of airbags, and outputs the driving signal to the airbag driving unit.

In a driver's seat airbag apparatus for vehicles, which includes a driver airbag which is deployed and expanded from a hub region towards a driver's seat via the inner peripheral side of a rim of a steering wheel surrounding this hub region, the driver airbag is configured so as to include: a back panel which is attached and fixed to an inflator provided in the hub region, and a bag body which is provided so as to be bonded to this back panel and deployed and expanded from this back panel towards the driver's seat, and wherein the attachment center S of the inflator to this back panel is set with respect to the center P of the back panel so as to be close to the 6 o'clock direction side in the 12 o'clock direction and the 6 o'clock direction of the steering wheel.

A steering-wheel assembly includes an actuator, an actuator controller, a steering wheel, an attachment, and a data connector (referred to hereinafter as a first data connector). The actuator controller includes a processor and a memory and is communicatively coupled to the actuator. The steering wheel is rotatably coupled to the actuator. The attachment is coupled to the actuator. The first data connector is mounted on the attachment and in communication with the actuator controller. The actuator controller is programmed to instruct the actuator to rotate the steering wheel based on steering-wheel control data provided via the first data connector.

A steering-wheel assembly includes an actuator, an actuator controller, a steering wheel, an attachment, and a data connector (referred to hereinafter as a first data connector). The actuator controller includes a processor and a memory and is communicatively coupled to the actuator. The steering wheel is rotatably coupled to the actuator. The attachment is coupled to the actuator. The first data connector is mounted on the attachment and in communication with the actuator controller. The actuator controller is programmed to instruct the actuator to rotate the steering wheel based on steering-wheel control data provided via the first data connector.

An assembly for a vehicle includes interior component and a panel rotatably connected to the interior component. The assembly includes an actuator designed to rotate the panel relative to the interior component. A sheet extends from the interior component to the panel. An airbag is supported by the interior component and is inflatable to an inflated position adjacent the sheet.

A low-profile clamp consists of a band (20) and a buckle (21) mounted on a first end portion of the band. During mounting, the second and portion (23) of the band (20) which surrounds the object to be fastened is fed through the buckle (21); after tightening the band is locked to the buckle (21) by deformation. The deformation may be done with a plier-type tool which engages the side edges (37) of the second band end portion (23) through lateral windows (36) formed in the buckle (21).

A curtain airbag for a vehicle may include a curtain airbag cushion, a first folding portion formed from an indoor side to a window side of the curtain airbag cushion, at a predetermined distance rearward from a front end of the curtain airbag cushion, a second folding portion formed from the indoor side to the window side of the cushion airbag at a predetermined distance rearward from the first folding portion, a panel tether connecting the first folding portion and the second folding portion to each other on the window side of the curtain airbag cushion, the panel tether being shorter than a length of the window side of the curtain airbag cushion between the first folding portion and the second folding portion, and a protruding portion protruding inward between the first folding portion and the second folding portion of the curtain airbag cushion by tension of the panel tether.

A curtain airbag for a vehicle may include a curtain airbag cushion, a first folding portion formed from an indoor side to a window side of the curtain airbag cushion, at a predetermined distance rearward from a front end of the curtain airbag cushion, a second folding portion formed from the indoor side to the window side of the cushion airbag at a predetermined distance rearward from the first folding portion, a panel tether connecting the first folding portion and the second folding portion to each other on the window side of the curtain airbag cushion, the panel tether being shorter than a length of the window side of the curtain airbag cushion between the first folding portion and the second folding portion, and a protruding portion protruding inward between the first folding portion and the second folding portion of the curtain airbag cushion by tension of the panel tether.

A pre/post-tensioning controller system for a wheelchair tie-down and occupant restraint system (“WTORS”) will be a comprehensive energy management system for controlling excessive excursions of a wheeled mobility device during various adverse driving scenarios. The system uses multiple pre-tensioning and post-tensioning events during a front, side, or rear impact crash or rollover scenario—and effectively controls excursions by the tensioning of the WTORS equipment at specific and ideal moments. The system also uses tensioning events on the tie-down equipment during a long duration turn or other aggressive maneuvers. The system may also use tensioning events on the occupant restraints. The energy management system can be adapted for use with traditional four-point tie-downs and newer three- and two-point tie-down systems that incorporate fixed or movable bumpers, as well as compressive-type securement systems, and other systems as well, including docking systems.