The present disclosure relates to a vehicular lighting device, the vehicular lighting device including a duct provided in a front bumper in such a manner as to be positioned in front of a front wheel, an opening and closing unit rotatably coupled to the front bumper in such a manner as to open and close the duct, a lamp installed inside the duct in such a manner as to be positioned behind the opening and closing unit, and a reflector installed inside the duct and reflecting light, emitted by the lamp, toward the opening and closing unit.

A vehicle includes one or more actuatable mudflap portions provided to the vehicle, capable of deployment and retraction to respectively increase and decrease deflection of wheel-spray and receives vehicle sensor information indicating driving conditions. The vehicle examines the sensor information to determine the presence of a first condition predefined as suitable for deployment of at least one of the mudflap portions. Further, the vehicle examines the sensor information to determine that no one or more of second conditions predefined as blocking deployment are met and, responsive to the presence of the first condition and the absence of the second conditions, automatically deploys the at least one mudflap portion.

A protective frame position control system includes a wheel protective frame for a working vehicle. The wheel protective frame is mounted on a wheel via at least one bearing aligned with a center of rotation of the wheel, and a position guide 55 is associable with an upper cast of a suspension via a pin 56 to prevent rotation of the wheel protective frame and also maintain a position of the wheel protective frame at any height of the suspension of the working vehicle. The position guide comprises includes a geometry oriented vertically and compatible with a path travelled by a first end of a damping element, which is associated with the center of rotation of the wheel.

A morphing fender skirt includes a rigid, open-ended arched base, stretchable exterior skin connected across the base, and a structural, bendable rib array connected over the base subjacent to the skin. The rib array is configured to bend between a flattened shape over the base, whereby the rib array imparts the flattened shape to the skin across the base, and a domed shape over the base, whereby the rib array imparts the domed shape to the skin across the base.

A mud flap is attachable to a selected group of through-holes of a vehicle running board. Plugs clamp to inclined surfaces of the through-holes, thereby firmly affixing a bracket portion of the integrally molded mud flap body to the running board. A flap portion of the mud flap body is connected to the bracket portion of the mud flap body only by a hinge portion. The hinge portion has a straight front surface, a straight rear surface and a thickness that is less than the overall thickness of the mud flap body. The flap portion has at least one wall portion that does not conform to any yz plane, stiffening the flap portion and inducing it to rotate around the hinge portion as a unit when a front-to-rear shear force impinges on the flap portion. A notch may be formed to interrupt an otherwise convexly curved rear flap portion surface so to receive a downwardly depending running board reinforcing member when the flap portion flexes out of its rest position.

A variable fender garnish structure of a vehicle is provided and includes a fender garnish coupled to an outer edge part of a wheel guard of a vehicle and made with a shape covering a wheel of the vehicle, a flap member positioned in the rear part of the fender garnish and rotatably coupled to the fender garnish, a driving member rotating the flap member, and a controller driving the driving member to control whether the flap member is rotated or not.

An deflection system for a vehicle to deflect flying debris may comprise an elongated support assembly configured to be supported on the vehicle such that the support assembly extends laterally with respect to the vehicle, and a deflection structure extending downwardly from the support assembly. The deflection structure may comprise a plurality of deflection elements including a first deflection element and a second deflection element positioned rearwardly of the first deflection element. The first deflection element may comprise a plurality of deflection bristles and the second deflection element may comprise at least one deflection panel.

An aerodynamic system for a wheel housing of a vehicle that according to one embodiment includes a flap that can be displaced between a deployed position and a retracted position, a rotating actuator, and a transmission mechanism coupled to the actuator and configured for transmitting the movement of the actuator to the flap. The aerodynamic system also includes at least one air flow shutter device in the wheel housing, where the shutter device faces at least one air duct and where the shutter device can be displaced between a closed position and an open position. The transmission mechanism is also configured for transmitting the movement of the actuator to the shutter device.

A spray protection device (1) for a wheeled vehicle (20) having at least one wheel (21) standing on the ground, said device (1) comprising a spray shield (2), suitable for being arranged at least in part behind the wheel (21), and connection means (3) for connecting the shield (1) to said vehicle (20), the spray shield (2) presenting a face suitable for facing towards the wheel (21) to be protected and an opposite face, referred to as the back of the shield (2), the connection means (3) for connecting the shield (2) to the vehicle (20) being configured, when the shield (2) is coupled to the vehicle (20), to enable the shield (2) to move between a high position, at a distance from the ground, and a low position, close to the ground. The device (1) comprises resilient shield (2) return means in the high position and a surface carried by the shield (2) and suitable for being exposed to the airflow generated when the wheeled vehicle (20) is moving forwards, said surface being configured, under the action of said airflow, to enable the shield (2) to move in a direction that is opposite to the direction of the return force.

A mud flap is attachable to a selected group of through-holes of a vehicle running board. Plugs clamp to inclined surfaces of the through-holes, thereby firmly affixing a bracket portion of the integrally molded mud flap body to the running board. A flap portion of the mud flap body is connected to the bracket portion of the mud flap body only by a hinge portion. The hinge portion has a straight front surface, a straight rear surface and a thickness that is less than the overall thickness of the mud flap body. The flap portion has at least one wall portion that does not conform to any yz plane, stiffening the flap portion and inducing it to rotate around the hinge portion as a unit when a front-to-rear shear force impinges on the flap portion. A notch may be formed to interrupt an otherwise convexly curved rear flap portion surface so to receive a downwardly depending running board reinforcing member when the flap portion flexes out of its rest position.