A pop-up hood apparatus includes a hood, a hood lock mechanism, an actuator for raising, and an auxiliary support section configured to support a side edge portion of the hood from below upon an actuation of the actuator. The auxiliary support section includes a load receiving block configured to support the side edge portion of the hood from below, a biasing member configured to bias the load receiving block upward, a displacement restricting member configured to restrict upward displacement of the load receiving block, and a restriction releasing section configured to release upward displacement restriction of the load receiving block according to upward displacement of the hood lock mechanism. The displacement restricting member is displaced to a position that abuts a lower surface of the load receiving block when the load receiving block that has been released upward displacement restriction is displaced upward by a predetermined amount or more.

Aspects of the disclosure relate to adjusting a shear pin to minimize an impact force felt by an object in a collision with a vehicle. For example, one or more second computing devices may receive, from one or more first computing devices, information indicating that an impact with an object is imminent. In response to the received information, the second computing devices may determine a first shear force for a first shear pin, wherein the first shear force is a desired amount of shear force necessary to break the first shear pin. The second computing devices may send a triggering signal to activate an actuator prior to an impact with the identified impact target. The actuator, in response to receiving the triggering signal, may adjust the first shear pin in a first pinhole, so the first shear pin will break at the first shear force.

Aspects of the disclosure relate to adjusting a shear pin to minimize an impact force felt by an object in a collision with a vehicle. For example, one or more second computing devices may receive, from one or more first computing devices, information indicating that an impact with an object is imminent. In response to the received information, the second computing devices may determine a first shear force for a first shear pin, wherein the first shear force is a desired amount of shear force necessary to break the first shear pin. The second computing devices may send a triggering signal to activate an actuator prior to an impact with the identified impact target. The actuator, in response to receiving the triggering signal, may adjust the first shear pin in a first pinhole, so the first shear pin will break at the first shear force.

A protection device (1) has a sensor (3) to sense an impact of a road user outside a motor vehicle. A control device (4) is connected to the sensor (3) and evaluates signals sensed by the sensor (3). A rear actuator (6) is connected to the control device (4) and to a hinge arrangement (21) of a front hood (2) of the vehicle. The rear actuator (6) transfers a rear part of the front hood (2) into an impact position for damping an impact sensed by the sensor (3). A front actuator (7) is connected to the control device (4) and to a hood lock (20) in a front region of the front hood (2). The front actuator (7) transfers a front region of the front hood (2) into an impact position for damping the impact. The control device (4) activates the two actuators (6, 7) in a time-delayed manner.

A protection device (1) has a sensor (3) to sense an impact of a road user outside a motor vehicle. A control device (4) is connected to the sensor (3) and evaluates signals sensed by the sensor (3). A rear actuator (6) is connected to the control device (4) and to a hinge arrangement (21) of a front hood (2) of the vehicle. The rear actuator (6) transfers a rear part of the front hood (2) into an impact position for damping an impact sensed by the sensor (3). A front actuator (7) is connected to the control device (4) and to a hood lock (20) in a front region of the front hood (2). The front actuator (7) transfers a front region of the front hood (2) into an impact position for damping the impact. The control device (4) activates the two actuators (6, 7) in a time-delayed manner.

An airbag arrangement for a motor vehicle includes an airbag, which can be unfolded by filling with a gas, and a sheathing, in which the airbag is arranged before and after filling. The airbag is provided and is to be arranged on the motor vehicle in such a way that, before filling, it is located in the region of a first end of the sheathing and/or a vehicle pillar of the motor vehicle and can be unfolded by filling inside the sheathing and along at least one section of the vehicle pillar up to a second end of the sheathing and/or the vehicle pillar. The invention further relates to a motor vehicle having such an airbag arrangement.

An airbag arrangement for a motor vehicle includes an airbag, which can be unfolded by filling with a gas, and a sheathing, in which the airbag is arranged before and after filling. The airbag is provided and is to be arranged on the motor vehicle in such a way that, before filling, it is located in the region of a first end of the sheathing and/or a vehicle pillar of the motor vehicle and can be unfolded by filling inside the sheathing and along at least one section of the vehicle pillar up to a second end of the sheathing and/or the vehicle pillar. The invention further relates to a motor vehicle having such an airbag arrangement.

The present disclosure relates to a hinge arrangement of a vehicle, the hinge arrangement being transitable between a normal state and a deployed state. The hinge arrangement comprises a body portion, a bracket portion, a hinge portion and a deployment guiding element. The hinge portion comprises a first member and a second member, the deployment guiding element pivotally connecting the bracket portion and the first member of the hinge portion. The bracket portion is arranged to be in a fixed position relative to the first member during movement in a hinged connection. The bracket portion is arranged to be translationally displaced as a whole in relation to the first member of the hinge portion during the transition of the hinge arrangement between the normal state and the deployed state, the deployment guiding element being adapted to guide the transition and the hinged connection being inactive during the transition.

The present disclosure relates to a hinge arrangement of a vehicle, the hinge arrangement being transitable between a normal state and a deployed state. The hinge arrangement comprises a body portion, a bracket portion, a hinge portion and a deployment guiding element. The hinge portion comprises a first member and a second member, the deployment guiding element pivotally connecting the bracket portion and the first member of the hinge portion. The bracket portion is arranged to be in a fixed position relative to the first member during movement in a hinged connection. The bracket portion is arranged to be translationally displaced as a whole in relation to the first member of the hinge portion during the transition of the hinge arrangement between the normal state and the deployed state, the deployment guiding element being adapted to guide the transition and the hinged connection being inactive during the transition.

A pop-up hood apparatus includes a hood, a hood lock mechanism, a support mechanism of the hood lock mechanism, and an actuator that displaces the hood lock mechanism upward. The support mechanism includes a movable block that supports the hood lock mechanism and a base block and that supports the movable block such that the movable block is slidable upward and downward. The base block has a long hole that extends along a vertical direction. A protrusion part that is slidably inserted in the long hole is provided on the movable block. A resistance-applying part that comes into contact with the protrusion part and that applies a resistance to the protrusion part is provided in at least a higher region of the long hole than a required elevation position of the hood.