The present invention relates to a system that is mounted on a mounting structure or chassis intended to protect the vehicles and their occupants. The system uses a main computer, high-precision radars, external airbag impellers, airbags that protect the vehicle and to some extent help its buoyancy, fluid sensors to detect the water limit that the vehicle can reach, and if these sensors are activated send a signal to the main computer that is responsible for activating air bag impellers, an inclinometer to detect the limit of inclination established in the vehicle and if the inclinometer detects an inclination that exceeds the limit established, this sends a signal to the main computer that is responsible for activating all the air bag impeller devices; and a monitor with signal transmitters to visualize in the state in which the system is located.

System, methods, and other embodiments described herein relate to sensing ingress of water in a vehicle. In one embodiment, a method includes acquiring, from a radar of a vehicle, radar data about a passenger cabin of the vehicle. The method includes determining a current state of the passenger cabin according to the radar data. The method includes, responsive to identifying that the current state indicates an ingress of water into the passenger cabin, generating a response to the ingress of the water.

A device for the detection of an at least partial flooding of a motor vehicle. The device includes an ultrasonic sensor that is designed to transmit and to receive ultrasonic signals. The device also includes an electronic recognition device, which can recognize an at least partial flooding of the motor vehicle on the basis of an ultrasonic signal received by the ultrasonic sensor. The recognition device is designed to determine the amplitudes of ultrasonic signals received within a defined time window, and to compare the amplitudes to a defined threshold value. The recognition device is designed to detect a flooding of the ultrasonic sensor as a function of the result of the comparison.

A vehicle flotation assembly includes a plurality of bladders that is each coupled to a bottom side of a vehicle. Each of the bladders is inflatable to float the vehicle when the vehicle is exposed to flood waters. A water senor is coupled to the vehicle to sense flood waters rising beneath the vehicle. A pump is coupled to the vehicle and the pump inflates each of the bladders when the pump is turned on, and the pump is turned on when the water sensor senses flood waters. A plurality of anchor actuators is each of the anchor actuators is coupled to the bottom side of the vehicle. A plurality of anchors is each lowered from the respective anchor actuator when the respective anchor actuator is actuated into a lowering condition thereby inhibiting the vehicle from being floated away by the flood waters.

A pneumatic motor vehicle window breaking device used in vehicles, comprising: a cylinder and a spike, wherein one end of the spike is fixedly connected to an end of a piston rod of the cylinder, and the other end of the spike is tapered; the cylinder is mounted on a retaining frame. The pneumatic motor vehicle window breaking device directly uses the cylinder and takes high-pressure air as power; only a front end of the spike of the pneumatic motor vehicle window breaking device is required to be mounted at an appropriate position in alignment with a vehicle window before use, and an air valve controls high-pressure air source to drive the spike to complete window breaking, and the device employs a simple structure.

A rescue system includes an inflatable rescue cushion at the bottom of an automobile, which includes air cushion storage chambers in front, back, left, and right of the bottom of the automobile. A gas generator is correspondingly arranged in the air cushion storage chamber in each position, for inflating and opening air cushions in the corresponding air cushion storage chambers to form a front, back, left and right air cushion. The system also includes an electronic early warning and central processing collaboration part, which includes an external water level sensor, central collaborative processing unit, first grade early warning signal light, and a switch. The external water level sensor is connected to the central collaborative processing unit, which is connected to the warning signal light, the gas generator, and the automobile computer board. The switch is positioned in the automobile and is connected to the gas generators.

Disclosed is a rescue device for adjusting the direction of an automobile falling into water through buoyancy. The rescue device comprises an automobile body, wherein storage cavities are formed in the automobile head and the automobile tail of the automobile body, a first high-pressure quick inflation pump is embedded in the inner wall of the storage cavity, a square buoyancy air bag is folded and stored in the storage cavity, an annular storage box body is embedded in a shell of the automobile body, meanwhile, the annular storage box body is located on the side close to the driving position of the automobile body, and an annular buoyancy air bag is folded and stored in the annular storage box body.

Systems and methods of the present disclosure include a vehicle water detection system that includes a housing configured to be disposed within a vehicle. The vehicle water detection system also includes a water-activated battery disposed within the housing and configured to produce an electrical voltage upon contact with water. The vehicle water detection system further includes an electronic circuitry disposed within the housing and configured to detect a water event occurring in the vehicle based at least in part on the electrical voltage.

A system for self-extrication from a safety harness by the wearer, or during rescue of the wearer, in the event of an emergency including one or more combination cutter and glass break tools mounted onto and around selected portions of the safety harness at predetermined positions for use in cutting the webbing straps of the safety harness in the event of the inoperability of any safety harness release resulting in the severing of the harness at such a predetermined position and further resulting in the combination tool being freed for use in breaking glass out of a window of a vehicle.

Disclosed is a rescue device for adjusting the direction of an automobile falling into water through buoyancy. The rescue device comprises an automobile body, wherein storage cavities are formed in the automobile head and the automobile tail of the automobile body, a first high-pressure quick inflation pump is embedded in the inner wall of the storage cavity, a square buoyancy air bag is folded and stored in the storage cavity, an annular storage box body is embedded in a shell of the automobile body, meanwhile, the annular storage box body is located on the side close to the driving position of the automobile body, and an annular buoyancy air bag is folded and stored in the annular storage box body.