The present invention relates to a fire suppression system applied to a battery pack of an electric vehicle, in particular, a fire suppression system applied to the electric vehicle according to various embodiments of the present disclosure in order to accomplish the objects as described in the disclosure is described. The fire suppression system may include: an energy storage system installed inside the electric vehicle; a sensor unit provided in the energy storage system in order to acquire battery environmental information; an fire suppression unit to inject an extinguishing agent to the energy storage system; and a control unit to control an extinguishing operation of the fire suppression unit based on the battery environmental information.

A vehicular control system includes at least one camera disposed in a vehicle and viewing a driver of the vehicle who is sitting in a driver seat of the vehicle. The vehicular control system is operable to drive the vehicle along a road in accordance with SAE Level 3. The vehicular control system determines, at least in part via processing of image data captured by the at least one camera, ability of the driver to take over driving the vehicle from the vehicular control system. While the vehicular control system is driving the vehicle in accordance with SAE Level 3, and responsive at least in part to determination by the vehicular control system that the driver is not able to take over driving the vehicle from the vehicular control system, the vehicular control system continues driving the vehicle in accordance with SAE Level 3 and initiates an emergency action.

A vehicular control system includes at least one camera disposed in a vehicle and viewing a driver of the vehicle who is sitting in a driver seat of the vehicle. The vehicular control system is operable to drive the vehicle along a road in accordance with SAE Level 3. The vehicular control system determines, at least in part via processing of image data captured by the at least one camera, ability of the driver to take over driving the vehicle from the vehicular control system. While the vehicular control system is driving the vehicle in accordance with SAE Level 3, and responsive at least in part to determination by the vehicular control system that the driver is not able to take over driving the vehicle from the vehicular control system, the vehicular control system continues driving the vehicle in accordance with SAE Level 3 and initiates an emergency action.

A motor vehicle has a front engine compartment housing a powertrain unit and at least one side-member on which a safety device is mounted; the safety device is configured so as to move said powertrain unit sideways during an impact, towards the opposite side to that which is subject to the impact; the safety device is provided with a beam having a first end, spaced from a terminal portion of the side-member towards the outside of the engine compartment, and a second end fixed to the side-member at an intermediate portion next to the powertrain unit; the safety device is further provided with a pin, which is fixed with respect to the second end of the beam and projects from said second end through a hole of the intermediate portion towards the powertrain unit.

A transport refrigeration system having: a first engine (26) configured to power a refrigeration unit (22); a first fuel tank (330) fluidly connected to the first engine through a first fuel line (332); a first shut off valve (450) located within the first fuel line proximate the first fuel tank; a second shut off valve (72) located within the first fuel line proximate the first engine; a sensor system (80) configured to detect at least one of a crash of the transport refrigeration system, a fuel leak in the first fuel line, and an engine stall in the first engine; and a controller (30) configured to close the first shutoff valve and the second shutoff valve when the sensor system detects at least one of a crash of the transport refrigeration system, a fuel leak in the first fuel line, and an engine stall in the first engine.

A transport refrigeration system having: a first engine (26) configured to power a refrigeration unit (22); a first fuel tank (330) fluidly connected to the first engine through a first fuel line (332); a first shut off valve (450) located within the first fuel line proximate the first fuel tank; a second shut off valve (72) located within the first fuel line proximate the first engine; a sensor system (80) configured to detect at least one of a crash of the transport refrigeration system, a fuel leak in the first fuel line, and an engine stall in the first engine; and a controller (30) configured to close the first shutoff valve and the second shutoff valve when the sensor system detects at least one of a crash of the transport refrigeration system, a fuel leak in the first fuel line, and an engine stall in the first engine.

An engine control method for the straddle-type vehicle including a non-driving wheel state determination step of determining whether a front wheel of the straddle-type vehicle is in a substantially stopped state, a driving wheel state determination step of determining whether a rear wheel of the straddle-type vehicle is in a substantially rotating state, and an engine stop control step of performing an engine stop control of the straddle-type vehicle. In the engine stop control step, the engine stop control of the straddle-type vehicle is performed when it is determined that the front wheel is in the substantially stopped state in the non-driving wheel state determination step, and the rear wheel is in the substantially rotating state in the driving wheel state determination step.

An engine control method for the straddle-type vehicle including a non-driving wheel state determination step of determining whether a front wheel of the straddle-type vehicle is in a substantially stopped state, a driving wheel state determination step of determining whether a rear wheel of the straddle-type vehicle is in a substantially rotating state, and an engine stop control step of performing an engine stop control of the straddle-type vehicle. In the engine stop control step, the engine stop control of the straddle-type vehicle is performed when it is determined that the front wheel is in the substantially stopped state in the non-driving wheel state determination step, and the rear wheel is in the substantially rotating state in the driving wheel state determination step.

The invention is a pedestrian safety method and system that compares characteristic acoustic and motion signatures to sound and motion signatures collected in real-time through a vehicle's monitoring system to detect and confirm that the vehicle itself presents a danger to pedestrians or others in proximity to the vehicle and autonomously stops the offending vehicle by quickly initiating disabling measures.

Aspects of the disclosure relate to detecting vehicle collisions. In one example, one or more computing devices may receive acceleration data of a vehicle and the expected acceleration data of the vehicle over a period of time. The one or more computing devices may determine a change in the vehicle's acceleration over the period of time, where the change in the vehicle's acceleration over the period of time is the difference between the expected acceleration data and the acceleration data. The one or more computing devices may detect an occurrence when the change in the vehicle's acceleration is greater than a threshold value and assign the occurrence into a collision category. Based on the assigned collision category, the one or more computing devices may perform a responsive action.