A system and method for evaluating and reporting of trauma to organs of passengers in a vehicular crash in real time is provided. The systems and methods include and use one or more in-vehicle sensors, a processor, a server, and one or more non-transitory computer-readable media to analyze a crash and trauma to passengers. The systems and methods may be further configured to optimize operation of a vehicle to minimize trauma.

An airbag device for a vehicle provided with a door and a side sill includes an airbag and an application state detector. The airbag is deployed from a container to be disposed on a lower side of the door on a vehicle body to a region on a vehicle-widthwise outside of the door. The application state detector detects a load application state of a load from the airbag to the vehicle body. The airbag includes a first air chamber, a second air chamber, and an internal pressure controller. The first air chamber transmits a load applied from the vehicle-widthwise outside to a side surface of the side sill. The second air chamber couples a lower part of the first air chamber and the container. The internal pressure controller controls an internal pressure of the second air chamber based on the load application state detected by the application state detector.

An airbag device to be applied to a vehicle provided with A to C pillars, a door, and a side sill includes an airbag, a collision mode predictor, and a pressure controller. The airbag is deployed from a container to be disposed on a lower side of the side sill to a region on a vehicle-widthwise outside of a side surface of a vehicle body including the door. The airbag includes a first air chamber disposed mainly in front of the B pillar after being deployed and a second air chamber disposed mainly behind the B pillar after being deployed. The collision mode predictor predicts a collision mode of an object with the vehicle. The pressure controller increases or reduces at least either of internal pressures of the first air chamber and the second air chamber independently of the other, based on the predicted collision mode.

A restraint system for a ride vehicle includes a rigid restraint configured to extend across a passenger to secure the passenger within a seat of the ride vehicle and a soft restraint coupled to the rigid restraint. The soft restraint includes a pliable material configured to conform to a substantial portion of a torso of the passenger and a haptic feedback system integrated with the soft restraint. The haptic feedback system is configured to generate vibrational forces and impart the vibrational forces to the torso of the passenger.

Airbag deployment data is collected using a plurality of sensors located along a line of weakening formed in a vehicle interior panel. The sensors are configured to provide information pertinent to separation of adjacent portions of the panel from each other as a function of time at a plurality of locations along the line of weakening. Each sensor is attached to the panel so that the sensor crosses the line. The relative time at which a conductive part of each sensor breaks is recorded and provides useful information about airbag door behavior during airbag deployment.

An airbag module having a retainer, a primary airbag cushion affixed to the retainer, a secondary airbag cushion affixed to the retainer, and an inflator, affixed to the retainer. The inflator configured to inflate the primary airbag cushion and the secondary airbag cushion. The secondary airbag cushion is configured to control a trajectory of the primary airbag cushion during deployment.

The present invention relates to a system and method for evaluating and reporting trauma suffered by organs of one or more passengers in a vehicular crash to an emergency management client computer, automatically and in real time. An aspect of the invention relates to steps for improving accuracy of an algorithm for trauma report accuracy, by optimization or training, as the system receives feedback comprising an aggregation of reports medical examinations (made by medical personnel such as a physician) of injured passengers processed by the system.

In an exemplary embodiment, the method comprises steps of 1) taking readings of in-vehicle sensors during a car accident; 2) wirelessly transmitting the readings to a server; 3) classifying a of crash type; 4) computing forces exerted on an organ of a passenger in the vehicle; 5) assessing trauma to the organ, based on the forces and published medical data; and 7) sending a trauma assessment report to an emergency management client.

Airbag deployment data is collected using a plurality of sensors located along a line of weakening formed in a vehicle interior panel. The sensors are configured to provide information pertinent to separation of adjacent portions of the panel from each other as a function of time at a plurality of locations along the line of weakening. Each sensor is attached to the panel so that the sensor crosses the line. The relative time at which a conductive part of each sensor breaks is recorded and provides useful information about airbag door behavior during airbag deployment.

A restraint system for a ride vehicle includes a soft restraint configured to extend across a passenger to secure the passenger within a seat of the ride vehicle. The soft restraint includes a pliable material configured to conform to a substantial portion of a torso of the passenger, and a sensory stimulation system integrated with the soft restraint. The sensory stimulation system is configured to generate sensory effects and impart the sensory forces to the torso of the passenger. The soft restraint also includes an inflatable bladder system integrated with the soft restraint and the inflatable bladder system is configured to inflate with a gas to increase contact between the soft restraint and the torso of the passenger.

A restraint system for a ride vehicle includes a soft restraint configured to extend across a passenger to secure the passenger within a seat of the ride vehicle. The soft restraint includes a pliable material configured to conform to a substantial portion of a torso of the passenger, and a sensory stimulation system integrated with the soft restraint. The sensory stimulation system is configured to generate sensory effects and impart the sensory forces to the torso of the passenger. The soft restraint also includes an inflatable bladder system integrated with the soft restraint and the inflatable bladder system is configured to inflate with a gas to increase contact between the soft restraint and the torso of the passenger.