A turn signal device comprising: a right-turn signal and a left-turn signal provided in a host vehicle; an operation device for generating operation signals; an acquisition unit that acquires determination signals indicating determination results regarding the risk of a collision between the host vehicle and a following vehicle; a normal situation control unit that, based on the operation signals, outputs normal situation control signals such that light-emitting units for either or both the left-turn signal and the right-turn signal light up sequentially from an inner side to an outer side in the vehicle width direction; and a dangerous situation control unit that outputs dangerous situation control signals such that, when a determination signal indicates a determination result that there is a risk of collision, the light-emitting units for both the left-turn signal and the right-turn signal light up sequentially from the outer side to the inner side.

A vehicular light source system includes: first and second laser emitters configured to emit first and second lasers; a thermometer configured to measure peripheral temperature; and a light source controller. The strength of the first laser at a temperature lower than a threshold temperature is higher than that of the second laser at that temperature. The strength of the first laser at a temperature higher than the threshold temperature is lower than that of the second laser at that temperature. The light source controller is configured to control the first and the second laser emitters such that: the strength of the first laser becomes higher than that of the second laser if the peripheral temperature is lower than the threshold temperature; and the strength of the second laser becomes higher than that of the first laser if the peripheral temperature is higher than or equal to the threshold temperature.

A vehicle door includes a powered latch configured to selectively retain the door in a closed position when the powered latch is latched, and permits the door to be opened when the powered latch is unlatched. The vehicle door further includes an exterior door handle having an outer side that faces away from the door structure, and an inner side that is spaced apart from an outer surface of the door to define a gap. A force sensor on the exterior door handle detects impact forces on the handle. The door also includes an unlatch switch that can be actuated by a user to request unlatching of the powered latch. A controller is configured to deny an unlatch request generated by actuation of the unlatch switch if the force sensor detects an impact on the exterior handle.

A vehicle door includes a powered latch configured to selectively retain the door in a closed position when the powered latch is latched, and permits the door to be opened when the powered latch is unlatched. The vehicle door further includes an exterior door handle having an outer side that faces away from the door structure, and an inner side that is spaced apart from an outer surface of the door to define a gap. A force sensor on the exterior door handle detects impact forces on the handle. The door also includes an unlatch switch that can be actuated by a user to request unlatching of the powered latch. A controller is configured to deny an unlatch request generated by actuation of the unlatch switch if the force sensor detects an impact on the exterior handle.

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 gas pressure container for an airbag system of a motor vehicle is disclosed having a tube element with a high bursting resistance when internal pressure is being applied. The tube element includes a steel alloy and a first longitudinal portion of the tube element has a tensile strength Rm,.sub.11 higher than (>) 800 MPa, a transition temperature Tu,.sub.11 of at least −40° C., and an outer circumference U1. The tube element also includes at least one second longitudinal portion and/or additional longitudinal portions, which extend axially from the first longitudinal portion. The second longitudinal portion or the additional longitudinal portions and the first longitudinal portion are formed from a seamless or welded single-piece tube made of a uniform material, and more specifically from a hot-rolled or cold-drawn tube.

In an apparatus for monitoring an adjacent lane to a lane in which an own vehicle that is a vehicle carrying the apparatus is traveling, a travel trajectory calculation unit calculates a travel trajectory of the own vehicle based on odometry information of the own vehicle. An adjacent lane estimation unit estimates an adjacent-lane region based on the travel trajectory of the own vehicle. An other-vehicle determination unit determines whether or not a target (the other vehicle) is present in the adjacent lane based on a position of the target detected by an other-vehicle detector and the estimated adjacent-lane region.

The present invention addresses the problem that a host vehicle changes lanes and comes into contact with a following vehicle or causes the following vehicle to rapidly decelerate when the other vehicle rapidly approaches the host vehicle from outside a recognizable zone in the presence of another vehicle traveling in the lane to which the host vehicle is about to travel. Provided is a vehicle control system characterized in that a driver is notified that a lane change is not possible, the vehicle control system having: an external recognition means for detecting the lane markers of the lane in which the host vehicle is traveling and/or detecting another vehicle in the surrounding area of the host vehicle; a limit-distance calculation means for determining the detectable limit distance of the external recognition means; a relative-speed calculation means for calculating the speed relative to a hypothetical vehicle present outside the detectable limit distance when no other vehicle is present within the distance; and a required detection distance calculation means for determining the required detection distance of the external recognition means required for the host vehicle to change lanes on the basis of the relative speed.

Provided is an automobile door (600) including: an exterior material (110); a first impact absorbing member (122); and a second impact absorbing member (124), in which the first impact absorbing member (122) is disposed to traverse the exterior material (110) so as to extend between both end portion regions in a vehicle height direction, the first impact absorbing member (122) is disposed on a vehicle interior side from the second impact absorbing member (124), the second impact absorbing member (124) is disposed to traverse the exterior material (110) so as to extend between both end portion regions in a vehicle length direction, the second impact absorbing member (124) is disposed adjacent to an inner surface of the exterior material (110), and at a portion excluding both of the end portion regions in the vehicle height direction, both of the end portion regions in the vehicle length direction, and an intersection portion, bending rigidity in a vehicle width direction of a cross section perpendicular to an extending direction of the first impact absorbing member (122) is larger than bending rigidity in the vehicle width direction of a cross section perpendicular to an extending direction of the second impact absorbing member (124).

An amusement ride restraint system includes an amusement ride car. A lap pad is configured to selectively engage a lap of the rider while the rider is positioned within the seat. A first linkage is pivotally coupled to the lap pad and pivotally coupled relative to the floor of the ride car, the first linkage operable to rotate the lap pad into i) an engaged position in which the rider is restrained in the seat, and ii) a loading position in which the rider can be loaded into or unloaded from the seat. The lap pad is constrained to pivotal motion relative to the first linkage such that the lap pad is oriented in a substantially vertical attitude relative to the seat when moved into the loading position and is oriented in a substantially horizontal attitude relative to the seat when moved into the engaged position.