Various embodiments of vehicle occupant safety systems having extendable restraints for use with, for example, airbags are described herein. In one embodiment, for example, the disclosed technology includes a 2-point occupant restraint that secures an occupant in an aircraft seat. In this embodiment, the aircraft seat is positioned in a seating area that includes a forward monument housing a stowed airbag. In the event of a crash or other significant dynamic event that causes, for example, a rapid deceleration of the aircraft above a preset magnitude, the airbag deploys between the occupant and the monument as the dynamic forces cause the occupant to pitch forward. The forward momentum of the occupant's body creates a significant tension load in the 2-point restraint, which causes the restraint to extend by a preset amount, thereby allowing the occupant to move forward in the seat more than the occupant would have moved had the occupant been wearing a conventional, non-extending 2-point restraint. Although the occupant is allowed to move forward, the occupant remains secured to the extended restraint by means of non-extending webbing that is secured around the waist of the occupant. Allowing the occupant to move forward in this manner enables the occupant's upper torso to impact the airbag at a reduced or otherwise more favorable angle. This can reduce both the speed and the angle at which the occupant's head impacts the airbag, thereby reducing the likelihood of injury.

An electronic module assembly (EMA) for use in controlling one or more personal restraint systems. A programmed processor within the EMA is configured to determine when a personal restraint system associated with each seat in a vehicle should be deployed. In addition, the programmed processor is configured to perform a diagnostic self-test to determine if the EMA and the personal restraint systems are operational. In one embodiment, results of the diagnostic self-test routine are displayed on a display included on the electronic module assembly. In an alternative embodiment, the results of the diagnostic self-test routine are transmitted via a wireless transceiver to a remote device. The remote device can include a wireless interrogator or can be a remote computer system such as a cabin management computer system.

Methods and apparatus for determining seatbelt status are disclosed. An example seatbelt system for a mass transit vehicle includes a first seatbelt of a first seat that includes a first buckle and a first magnetically-responsive switch to detect a first tongue when the first seatbelt is in a fastened position. The example apparatus includes a second seatbelt of a second seat that includes a second buckle and a second magnetically-responsive switch to detect a second tongue when the second seatbelt is in the fastened position. The example apparatus includes a remote monitoring unit to indicate, when the first seat is occupied, if the first seatbelt is in the fastened positioned or an unfastened position. The remote monitoring unit is to indicate, when the second seat is occupied, if the second seatbelt is in the fastened positioned or the unfastened position.

An energy absorbing system that is adapted for absorbing energy of an object in a vehicle in a crash situation by decreasing acceleration and force acting on the object in the crash situation, the energy absorbing system comprising at least one plastically deformable energy absorber that is plastically deformable in the crash situation. A mass-dependent self-adjusting mechanism is provided, the mass-dependent self-adjusting mechanism being adapted for adjusting, on the basis of an underlying mass of the object, a required compensation force that is to be provided by the energy absorbing system in the crash situation for plastically deforming the at least one plastically deformable energy absorber in order to decrease the acceleration and force acting on the object.

An aircraft passenger restraint and protection system including an aircraft seat mounted at an oblique angle to a direction of forward travel, a multi-point seat belt associated with the aircraft seat, and a structural mounted airbag located forward of the aircraft seat.

A neck protection system includes a support structure, helmet, force transmission arrangement, actuator arrangement, sensor arrangement, and controller. The force transmission arrangement is coupled to the support structure and the helmet and applies a relative force between them. The actuator arrangement applies a load to the force transmission arrangement to initiate the relative force between the support structure and the helmet. The sensor arrangement measures movement changes of a vehicle. The controller is connected to the sensor arrangement to receive data representing the measured movement changes, and connected to the actuator arrangement, and generates and sends control commands to the actuator arrangement based on which the actuator arrangement applies the load to the force transmission arrangement. The controller receives maneuver information from a control computer of a vehicle and generates the control commands based on the received maneuver information and/or based on measurements of the sensor arrangement.

An electronic module assembly (EMA) for use in controlling one or more personal restraint systems. A programmed processor within the EMA is configured to determine when a personal restraint system associated with each seat in a vehicle should be deployed. In addition, the programmed processor is configured to perform a diagnostic self-test to determine if the EMA and the personal restraint systems are operational. In one embodiment, results of the diagnostic self-test routine are displayed on a display included on the electronic module assembly. In an alternative embodiment, the results of the diagnostic self-test routine are transmitted via a wireless transceiver to a remote device. The remote device can include a wireless interrogator or can be a remote computer system such as a cabin management computer system.

A vehicle includes: a front seat capable of changing a posture between a first posture in which a seating surface of the front seat faces forward and a second posture in which the seating surface of the front seat faces backward; a rear seat disposed behind the front seat, a seating surface of the rear seat facing forward; and a protective device emerging between the front seat and the rear seat when impact force acts on the vehicle or when impact force is predicted to act on the vehicle.

The present invention discloses a multiple-chamber airbag structure where the airbag design has at least a stiff lower section to reduce the chest velocity and a soft upper section to meet the HIC requirements. Although stowed and deployed as a unitary airbag, the present invention includes separate chambers, which allows for independent gas inflation and stiffness control with venting.