A hinge assembly for an engine hood of a motor vehicle, having a hinge substructure, which can be attached to a body component of the motor vehicle, and having a hinge upper part, which can be attached to the engine hood. The hinge upper part is retained on the hinge substructure so as to pivot about a pivoting axis. The hinge assembly includes at least one support element, which enables deformation of the hinge substructure in a first direction, in which the hinge substructure can be moved away from a limit stop area of the at least one support element. The at least one support element limits deformation of the hinge substructure in a second direction opposite the first direction by means of the limit stop area. Furthermore, the invention relates to a motor vehicle having at least one such hinge assembly.

A hinge for a hood assembly of the type used in a motor vehicles. The hinge includes at least one structural composite component, attached to one of the hood and the body of a vehicle, and configured to include a plastic portion overmolded into a core panel.

A hinge base member (5) and a hinge upper member (15) of a hinge (1) for an engine hood (3) are provided with main bodies (5, 17) each having a laterally facing major plane, and link members (9, 10) are connected between the main bodies of the hinge base member and the hinge upper member and overlies the main bodies of the hinge base member and the hinge upper member from a first lateral side. The hinge upper member is provided with an extension (17) fixedly attached to the side part of the hood and extending forward from the main body of the hinge upper member with an offset to a second lateral side opposite to the first lateral side with respect to the main body of the hinge base member.

A hood hinge for a motor vehicle includes a first part attached to a vehicle body part and a second part attached to a front hood. A lifting mechanism is configured to extend the attachment parts from a starting position into a cushioning position in which the front hood is raised from the starting position. A limiter exerts a limiting force on the attachment parts for limiting an extension movement thereof. A deformation element deforms when the force of the limiter acts on at least one attachment part. A stop may contact a counter stop for limiting the deformation of the deformation element.

A radiator grille charging door apparatus for an electric vehicle for charging the electric vehicle in which a charging port is positioned at an inner side of a radiator grille is provided. The apparatus includes a charging door that has one end formed with a hinge shaft and a hinge connector that is coupled to the hinge shaft of the charging door at one side of the hinge connector. A hinge bracket is coupled to an inside of the hinge connector and a plurality of hinge springs connect the hinge connector and the hinge bracket to each other.

A hinge assembly for securing a flap to a vehicle body includes a first hinge part which can be moved between a closed position and an open position for securing to a vehicle body, a second hinge part which can be moved between a closed position and an open position for securing the flap to be mounted relative to the vehicle body, and a deployment securing device for locking the second hinge part relative to the first hinge part. The deployment securing device has a first securing part which is paired with the first hinge part, a second securing part which is paired with the second hinge part, and a locking element and is configured such that the locking element is coupled to the first securing part in the closed position and is locked by the second securing part in a first locking position. The second securing part unlocks the locking element in the course of the movement of the second securing part from the closed position into the open position and thereby releases the locking element. The deployment securing device is configured such that after the locking element is unlocked in the first locking position, the locking element is moved into a second locking position in which the locking element produces a coupling between the first securing part and a third securing part paired with the first hinge part and locks the first securing part and the third securing part in the open position.

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 hinge apparatus (1) for a front hood (2) of a motor vehicle has an integrated pedestrian protection that includes a hood-side fastening arrangement (4) articulated to a body-side fastening arrangement (6) via a link arrangement (5) that has a stop link (50). The hood-side fastening arrangement (4) has a hinge upper part (40) and a coupling (41), and the body-side fastening arrangement (6) has a lock (60) that acts on the coupling (41) to lock the hood (2) in a normal state and to unlock it by a pyrotechnical actuator (9) that acts on the lock (60) and the stop link (50). The pyrotechnical actuator (9) has a piston rod (90) and an ignition in a housing (92). A free end (91) of the piston rod (90) is articulated on the lock (60), and an opposite end (93) of the housing (92) is articulated on the stop link (50).

A hinge assembly for attaching a hood to a body of a vehicle includes a body-side bracket fixedly attached to the body and a hood-side bracket fixedly attached to the hood. A pivot mechanism is configured to place the hinge assembly in: a stowed position, in which the hood is adjacent the body; an access position, in which the hood rotates toward a rear of the vehicle; and an active position, in which the hood rotates toward a front of the vehicle. The hinge assembly also includes an actuator that configured to move the pivot mechanism to, or toward, the active position. A pin is attached to the body-side bracket and an upstop link is attached to the hood-side bracket. The upstop link defines a slot. The pin becomes engaged with the slot when the pivot mechanism is in the active position.

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.