The present invention discloses a lateral shock absorber disposed on a base of a child car safety seat. The lateral shock absorber includes a protective fender. An end of the protective fender is pivoted to the base, so that the protective fender is pivotally switchable between a folded state and an unfolded state relative to the base. The unfolded protective fender can collide with a car body during a side impact collision for transferring a side impact to the base and away from a child sitting in the child car safety seat. Therefore, it can effectively reduce a risk of injury or death of the child due to the side impact and provide enhanced protection for the child. Furthermore, the lateral shock absorber has advantages of simple structure and easy operation. Besides, the present invention further discloses a child car safety seat with the aforementioned lateral shock absorber.

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 scenarioand 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 method for determining an occupant class for a vehicle seat includes obtaining, via first and second seat weight sensors, first and second seat weight indications for the vehicle seat. The first seat weight sensor is located on the lateral side of the vehicle seat at a front location on the vehicle seat. The second seat weight sensor is located on the lateral side of the vehicle seat at a rear location on the vehicle seat. The method also includes obtaining a vehicle acceleration value from a vehicle acceleration sensor. The method also includes determining a raw weight on the vehicle seat as twice the sum of the first and second seat weight indications, and determining a filtered weight based on the raw weight. The method further includes determining the occupant class based on the filtered weight in response to the vehicle acceleration value being less than a predetermined value.

An airbag apparatus includes an airbag bag body that is inflated and expanded by a gas which is generated from an inflator. The airbag bag body includes an inner bag and an outer bag. The inner bag is inflated and expanded by the gas which is supplied from the inflator. The outer bag covers the inner bag and communicates with the inner bag via a communication hole. The outer bag has a depression part on a lower part of the outer bag in a state of being supplied with the gas through the communication hole from the inner bag and being inflated and expanded.

A lateral shock absorber is provided and includes a protective fender and a locking mechanism. The protective fender is pivoted to a base of a child car safety seat and pivotally switchable relative to the base. The locking mechanism is for selectively engaging with the protective fender to restrain the protective fender from switching to an 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 a folded state. The locking mechanism includes a locking assembly and an abutting block. The locking assembly is driven to a locking state for engaging with the protective fender when the abutting block is pressed downwardly. The locking assembly is driven to a releasing state for disengaging from the protective fender when the abutting block is not pressed. Besides, a related child car safety seat is also provided.

A computing device is provided to monitor or ascertain various characteristics of one or more of a wheeled mobility device securement system, a wheeled mobility device, and an occupant of the wheeled mobility device. The computing device can send any and all data available to it, including but not limited to time, dynamic information concerning the vehicle, the wheeled mobility device securement system, the wheeled mobility device, and the occupant, the actions taken by the computing device during an adverse driving condition, and when those actions were taken, to memory for use after the adverse driving event for analysis purposes to understand and recreate the event.

A vehicle seat has a seatback and a seat bottom defining an occupant-seating area. An inflatable device is fixed to the seatback and is inflatable from the seatback vehicle-forward along the occupant-seating area from an uninflated position to an inflated position. The inflatable device has an inflation chamber. The inflatable device is a thermoplastic elastomer. The vehicle includes a computer including a processor and a memory storing instructions executable by the processor to: detect a removeable child-restraint system on the occupant-seating area; and based on the detection of the removeable child-restraint system on the occupant-seating area, inflate the inflatable device in response to detection of certain vehicle impacts.

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 vehicle seat having a seatback and a seat bottom defining an occupant-seating area. The vehicle includes an airbag housing having a first arm fixed to the seatback and a second arm rotatable from the seatback toward the seat bottom adjacent the occupant-seating area. An airbag extends from the first arm to the second arm. The airbag is fixed to the first arm and the second arm. The vehicle includes a computer including a processor and a memory storing instructions executable by the processor to detect a removeable child-restraint system (CRS) on the occupant-seating area, and based on the detection of the removeable CRS on the occupant-seating area, inflate the airbag in response to detection of certain vehicle impacts.

Methods and systems for providing accident information from a vehicle to an emergency responder when a vehicle accident occurs. One system includes a sensor and an electronic processor. The electronic processor is configured to receive vehicle data from the sensor. The electronic processor is also configured to determine a child presence indication of whether a child is present in the vehicle based on the vehicle data. The electronic processor is also configured to determine a state of a windshield of the vehicle based on the vehicle data. The electronic processor is also configured to generate an emergency message including the child presence indication and the state of a windshield of the vehicle. The electronic processor is also configured to automatically transmit the emergency message to an emergency responder.