A hinged-panel opening and closing system includes: an anchor designed to be located on a hinged panel; a gear motor designed to be located on a supporting structure; and a movement-enabling component capable of angularly displacing the hinged panel relative to a receiving structure. The movement-enabling component includes: (a) a movement-enabling shaft located on the supporting structure and, at one shaft end, coupled to the gear motor; (b) a spindle located on supporting structure and coupled to the movement-enabling shaft; and (c) a linear element attaching, at a first end, to the spindle and attaching, at a second end, to the anchor such that said linear element extends between the spindle and the anchor.

A cover system for covering a vehicle tow hitch connector includes at least a first retention member including a first retention slot, and a first door support coupled to the first retention member. A second door support is positioned opposite the first door support. A door is rotatably coupled to the first and second door supports. The door includes a first retention projection structured to be received in the first retention slot to position the door in a closed orientation.

A cover system for covering a vehicle tow hitch connector includes at least a first retention member including a first retention slot, and a first door support coupled to the first retention member. A second door support is positioned opposite the first door support. A door is rotatably coupled to the first and second door supports. The door includes a first retention projection structured to be received in the first retention slot to position the door in a closed orientation.

A fuel filler flap module of a motor vehicle includes a carrier, a fuel filler flap which is pivotably mounted on the carrier and is designed to be movable between a closed position and an open position, and a movement mechanism designed to move the fuel filler flap from the closed position into the open position and back into the closed position. The movement mechanism has a mechanical deployment element which is arranged on the carrier and which is designed to exert a deployment force acting into the open position on the fuel filler flap, wherein the movement mechanism has a motor-driven deployment means which is designed to push the fuel filler flap with an auxiliary force from the closed position up to an initial deployment position, which lies between the closed position and the open position, wherein the auxiliary force is greater than the deployment force.

A fuel filler flap module of a motor vehicle includes a carrier, a fuel filler flap which is pivotably mounted on the carrier and is designed to be movable between a closed position and an open position, and a movement mechanism designed to move the fuel filler flap from the closed position into the open position and back into the closed position. The movement mechanism has a mechanical deployment element which is arranged on the carrier and which is designed to exert a deployment force acting into the open position on the fuel filler flap, wherein the movement mechanism has a motor-driven deployment means which is designed to push the fuel filler flap with an auxiliary force from the closed position up to an initial deployment position, which lies between the closed position and the open position, wherein the auxiliary force is greater than the deployment force.

The system comprises a lever (2) that is rotatable about a point fixed to the vehicle and articulately joined to the upper edge (6) of the leaf (1); a horizontal guide (3) through which a carriage (4) slides; push-pull means (10,11) that articulately link the upper edge (6) to the carriage (4); and actuation means (12) simultaneously linked to the lever (2) and the carriage (4), which are adapted to distribute their action on the lever (2) and the carriage (4) depending on the force to overcome in order to open and close the leaf (1), such that their action is automatically distributed on the lever (2) when greater power is required to move the carriage (4), this is essentially during the initial opening operation from the end closing position, and during the closing and locking operation from an imminent closing position.

The system comprises a lever (2) that is rotatable about a point fixed to the vehicle and articulately joined to the upper edge (6) of the leaf (1); a horizontal guide (3) through which a carriage (4) slides; push-pull means (10,11) that articulately link the upper edge (6) to the carriage (4); and actuation means (12) simultaneously linked to the lever (2) and the carriage (4), which are adapted to distribute their action on the lever (2) and the carriage (4) depending on the force to overcome in order to open and close the leaf (1), such that their action is automatically distributed on the lever (2) when greater power is required to move the carriage (4), this is essentially during the initial opening operation from the end closing position, and during the closing and locking operation from an imminent closing position.

A power sliding door actuator according to the present disclosure includes an actuator unit in which a motor, a gear configured to amplify torque caused by the motor, a drum provided to be rotatable by the gear, and a cable configured to move according to rotation of the drum and open or close a door are provided, a tensioner unit configured to provide a restoration force to the actuator unit, and a housing unit configured to provide a path along which the actuator unit moves.

A power sliding door actuator according to the present disclosure includes an actuator unit in which a motor, a gear configured to amplify torque caused by the motor, a drum provided to be rotatable by the gear, and a cable configured to move according to rotation of the drum and open or close a door are provided, a tensioner unit configured to provide a restoration force to the actuator unit, and a housing unit configured to provide a path along which the actuator unit moves.

A confinement cabin has a load-bearing structure, confinement walls connected to the load-bearing structure to delimit an inner space of the cabin, an access opening to the inner space, and a door connected to the load-bearing structure to close the access opening. The door is movable in opening and closing with a pivoting-tilting movement and has a movable arm which at a first end is rotationally connected to the load-bearing structure to rotate around a hinging axis, and a closing panel rotationally connected to a second end of the movable arm to rotate around a tilting axis. Rotation of the panel around the tilting axis is synchronized with rotation of the movable arm around the hinging axis by an elastic transmission system between a first pulley coaxial to the hinging axis and a second pulley coaxial to the tilting axis. Rotation of the panel around the tilting axis is in the opposite direction to rotation of the movable arm around the hinging axis.