A lateral shock absorber includes a protective fender pivoted to a base of a child car safety seat and a locking mechanism disposed on the base. The protective fender is pivotally switchable between a folded state or an unfolded state. The locking mechanism is for selectively engaging with the protective fender to restrain the protective fender from switching to the unfolded state or disengaging from the protective fender to allow the protective fender to switch to the unfolded state when the protective fender is located in the folded state. The locking mechanism includes a locking assembly, an abutting component and an abutting block connected to the abutting component. The locking assembly engages with the protective fender to restrain the protective fender from moving, and the abutting component is driven by the abutting block to disengage the locking assembly from the protective fender when the abutting block is pressed downwardly.

A vehicle and control method include: a seat; an image acquirer to acquire an image of the seat; a first type of roof airbag module in a fixed position in a first area of a headlining; a rail member in a second area of the headlining in a left-right direction of a vehicle body; a second type of roof airbag module in the rail member and movable in left and right directions along the rail member; an angle detector to detect a rotation angle of the seat; and a controller. The controller identifies the seat rotation angle based on the image of the seat and controls activation of at least the first type of roof airbag module or the second type of roof airbag module based on at least the seat rotation angle based on the image of the seat or detected by the angle detector.

A vehicle includes a floor and a seat supported by the floor. The seat is translatable relative to the floor along a longitudinal axis of the vehicle. An airbag housing is supported by the floor and is disposed alongside the seat. The airbag housing is translatable relative to the floor along the longitudinal axis. An airbag is supported by the airbag housing. The airbag is inflatable to an inflated position that extends from the airbag housing away from the floor.

A vehicle airbag device includes: an inflator configured to generate gas when a first squib and a second squib are fired, respectively; an airbag including a main bag portion configured to inflate and deploy between an occupant seated in a passenger seat and an instrument panel and between the occupant and a windshield when the gas generated by the inflator is supplied into the airbag, and a center bag portion configured to project between the passenger seat and a driver seat from the main bag portion; and a controlling portion configured to control the inflator such that, when a head-on collision occurs, the second squib is fired after the first squib is fired, and when an oblique collision occurs, the second squib is fired after the first squib is fired and at a timing earlier than that when the head-on collision occurs.

A vehicle detects a rotation angle of a seat, controls activation of a first type of roof airbag module provided in a central portion of a headlining and located at a side of the seat when the detected rotation angle of the seat is greater than a first reference angle and less than or equal to a second reference angle, controls activation of the first type of roof airbag module and a second type of roof airbag module provided in the central portion of the headlining and provided at a rear of the seat when the detected rotation angle of the seat is greater than the second reference angle and less than or equal to a third reference angle, determines whether a collision with an obstacle has occurred during traveling, and deploys and expands the activated airbag module when determining that the collision with the obstacle has occurred.

A vehicle includes a floor and a seat supported by the floor. The seat is translatable relative to the floor along a longitudinal axis of the vehicle. An airbag housing is supported by the floor and is disposed alongside the seat. The airbag housing is translatable relative to the floor along the longitudinal axis. An airbag is supported by the airbag housing. The airbag is inflatable to an inflated position that extends from the airbag housing away from the floor.

The present disclosure relates to a vehicle control apparatus for safety of a vehicle occupant, a vehicle system including the same, and a method thereof. An exemplary embodiment of the present disclosure provides a vehicle control apparatus, including: a processor configured to recognize information related to occupants in a vehicle using a radar and to generate information for air conditioning control and airbag control depending on the occupant information; and a communication device configured to transmit the information for the air conditioning control and the airbag control depending on the occupant information to an air conditioning control device and an airbag control device.

A passenger-side airbag includes a first side panel, a second side panel opposite the first side panel, a first center panel having a first side edge part toward the first side panel, a second side edge part opposite the first side edge part, and a first front face situated between the first side edge part and the second side edge part to face an occupant, and a second center panel having a third side edge part toward the second side panel, a fourth side edge part opposite the third side edge part, and a second front face situated between the third side edge part and the fourth side edge part to face an occupant, wherein the second side edge part has a flange projecting in an opposite direction from the first side edge part, and the flange is bonded to the fourth side edge part such that the second front face bulges relative to the first front face.

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.

A system and method for determining when a child safety system is present in a passenger seat in a vehicle and restrained, including at least one of: a) two lower anchors each including a lower anchor sensor, or b) an upper anchor including an upper anchor sensor; an occupancy sensor; a seatbelt buckle sensor; a microprocessor control system in communication with at least one of the sensors. The microprocessor control system includes executable code to: provisionally determine whether the child safety system is detected in the passenger seat; determine whether at least one of: a) a strap is connected to each lower anchor and b) a tether is connected to the upper anchor; determine whether the seatbelt is buckled; and verify the presence of a child safety system in the passenger seat. Executable code can also be included to detect strap and tether tension.