A gutter member has a flow path portion that receives the water dripping from a front windshield and flows the received water in the vehicle width direction and a drain portion that drains the water to a drain member on the inner side in the vehicle width direction of the flow path portion, in which at least a part of the flow path portion overlaps with the drain path in vehicle plan view, the gutter member has guide portions that guide the water dripping from the drain portion to the drain path, and the guide portions, include a cushioning material that absorbs an impact load at least in the vertical direction.

The invention relates to a front end panel assembly for an electric vehicle, the assembly comprising a front cover having side edges, the front cover extending in a bended shape such that a first angle α is enclosed between a first portion and a second portion of the front cover; and a carrier structure comprising a base and a peripheral wall extending from the base, wherein the carrier structure comprises a first part and a second part that enclose a second angle β; wherein the upstanding wall connects to the front cover at or near at least part of the side edges of the front cover, such that a space is formed and enclosed between the front cover and the carrier structure, wherein the first portion of the front cover covers the first part of the carrier structure, and the second portion of the front cover covers the second part of the carrier structure. The invention also relates to a vehicle provided with such a front end panel assembly.

The invention relates to a front end panel assembly for an electric vehicle, the assembly comprising a front cover having side edges, the front cover extending in a bended shape such that a first angle α is enclosed between a first portion and a second portion of the front cover; and a carrier structure comprising a base and a peripheral wall extending from the base, wherein the carrier structure comprises a first part and a second part that enclose a second angle β; wherein the upstanding wall connects to the front cover at or near at least part of the side edges of the front cover, such that a space is formed and enclosed between the front cover and the carrier structure, wherein the first portion of the front cover covers the first part of the carrier structure, and the second portion of the front cover covers the second part of the carrier structure. The invention also relates to a vehicle provided with such a front end panel assembly.

The invention relates to a front end panel assembly for an electric vehicle, the assembly comprising a front cover having side edges, the front cover extending in a bended shape such that a first angle α is enclosed between a first portion and a second portion of the front cover; and a carrier structure comprising a base and a peripheral wall extending from the base, wherein the carrier structure comprises a first part and a second part that enclose a second angle β; wherein the upstanding wall connects to the front cover at or near at least part of the side edges of the front cover, such that a space is formed and enclosed between the front cover and the carrier structure, wherein the first portion of the front cover covers the first part of the carrier structure, and the second portion of the front cover covers the second part of the carrier structure. The invention also relates to a vehicle provided with such a front end panel assembly.

The invention relates to a front end panel assembly for an electric vehicle, the assembly comprising a front cover having side edges, the front cover extending in a bended shape such that a first angle α is enclosed between a first portion and a second portion of the front cover; and a carrier structure comprising a base and a peripheral wall extending from the base, wherein the carrier structure comprises a first part and a second part that enclose a second angle β; wherein the upstanding wall connects to the front cover at or near at least part of the side edges of the front cover, such that a space is formed and enclosed between the front cover and the carrier structure, wherein the first portion of the front cover covers the first part of the carrier structure, and the second portion of the front cover covers the second part of the carrier structure. The invention also relates to a vehicle provided with such a front end panel assembly.

Methods and systems for autonomous vehicle recharging or refueling are disclosed. Autonomous vehicles may be automatically refueled by routing the vehicles to available fueling stations when not in operation, according to methods described herein. A fuel level within a tank of an autonomous vehicle may be monitored until it reaches a refueling threshold, at which point an on-board computer may generate a predicted use profile for the vehicle. Based upon the predicted use profile, a time and location for the vehicle to refuel the vehicle may be determined. In some embodiments, the vehicle may be controlled to automatically travel to a fueling station, refill a fuel tank, and return to its starting location in order to refuel when not in use.

A deformation structure includes at least one first layer and a second layer, which are arranged spaced apart from one another in a deformation direction and such that they can be displaced relative to one another. The first layer and the second layer have complementary protrusions and recesses, which are designed in such a way that the protrusions of the first layer and recesses of the second layer, as well as the protrusions of the second layer and recesses of the first layer can dip into one another. The first layer and the second layer are connected to one another via deformable web elements in such a way that, with a high impulse in the deformation direction, the protrusions of the first layer dip into recesses of the second layer, and protrusions of the second layer dip into recesses of the first layer, such that a deformation of the deformation structure occurs at a low force level in the deformation direction, and with a low impulse in the deformation direction, the protrusions of the first layer impinge on the protrusions of the second layer such that a deformation of the deformation structure occurs at a high force level in the deformation direction.

A deformation structure includes at least one first layer and a second layer, which are arranged spaced apart from one another in a deformation direction and such that they can be displaced relative to one another. The first layer and the second layer have complementary protrusions and recesses, which are designed in such a way that the protrusions of the first layer and recesses of the second layer, as well as the protrusions of the second layer and recesses of the first layer can dip into one another. The first layer and the second layer are connected to one another via deformable web elements in such a way that, with a high impulse in the deformation direction, the protrusions of the first layer dip into recesses of the second layer, and protrusions of the second layer dip into recesses of the first layer, such that a deformation of the deformation structure occurs at a low force level in the deformation direction, and with a low impulse in the deformation direction, the protrusions of the first layer impinge on the protrusions of the second layer such that a deformation of the deformation structure occurs at a high force level in the deformation direction.

A hinge assembly for a hood of a vehicle is provided. The hinge assembly includes a body member and a hood member. The hood member is pivotally coupled with the body member through a pivot pin. The hood member or the body member partially wraps around the pivot pin such that the hood member or the body member defines a notch. The hood member or the body member is adapted to disengage from the pivot pin on application of an impact force on the hood member.

A hinge assembly for a hood of a vehicle is provided. The hinge assembly includes a body member and a hood member. The hood member is pivotally coupled with the body member through a pivot pin. The hood member or the body member partially wraps around the pivot pin such that the hood member or the body member defines a notch. The hood member or the body member is adapted to disengage from the pivot pin on application of an impact force on the hood member.