A motor vehicle includes a body, a side door hinged to the body so that it can rotate about an axis towards a side of the motor vehicle between a closed configuration and an open configuration; a motorized opening device, which is controllable to move the door from the closed configuration towards the open configuration; command receiving means to receive an opening request command for the door from the outside of the motor vehicle; and a control unit (ECU) configured to control the opening device so that the door rotates from the closed configuration towards the open configuration in response to the opening request command.

A vehicular storage box that includes a compartment for holding articles, the compartment comprising four sides, a bottom and a top lid. The compartment is fabricated from an engineered plastic or a polymer matrix composite. The box further includes a locking assembly situated within the lid. The locking assembly comprises a central locking wheel connected to a linkage, a plurality of pawls for each of at least three of the sides of the compartment, and a solenoid switch. The locking wheel is movably connected to the plurality of pawls. Further, the solenoid switch is connected to the linkage to move the wheel to drive the plurality of pawls into and out of the at least three of the sides of the compartment into a respective locked position of the lid and an unlocked position of the lid.

A transmission mechanism applied to a lock and for controlling the lock to switch between an unlocked state and a locked state. The lock includes a first handle set including a first cover plate which includes a first fitting portion. The transmission mechanism includes a transmission element and a moving component. The transmission element is connected to the first handle set in a manner that the transmission element is incapable of moving along a rotating axis and has an abutting portion. The moving component is disposed on the transmission element in a manner that the moving component is capable of moving along the rotating axis and includes a first engaging groove, a second engaging groove and a second fitting portion. When the transmission element is operated to rotate, the abutting portion is capable of switching between the first engaging groove and the second engaging groove.

A vehicle door device includes a first link mechanism formed of first and second link arms having a first rotary coupling point with respect to a vehicle body and a second rotary coupling point with respect to a door of a vehicle, and a second link mechanism formed of the first and second link arms provided independently of the first and second link arms forming the first link mechanism. First and second doors respectively supported by the first and second link mechanisms open and close independently in different directions based on operations of the first and second link mechanisms. At least one of the first and second link arms forming the first link mechanism and the first and second link arms forming the second link mechanism is provided with a coupling length variable mechanism that allows a coupling length between the first and second rotary coupling points to vary.

A vehicle tailgate with an integrated collapsible door comprises a tailgate having an outer wall, an inner wall and a cavity there between, a door section of the tailgate having an inboard wall and an outboard wall and being moveable between a closed position and an open position substantially within the envelope of the tailgate, the inboard wall and the outboard wall being connected by a linkage to permit relative movement there between, a first track to guide the motion of the inboard wall and a second track to guide the motion of the outboard wall, and a power drive unit to power the motion of the door section, such that in the closed position of the door section the inboard wall is flush with the inner wall of the tailgate and the outboard wall is flush with the outer wall of the tailgate, and in the open position of the door section at least a portion of the inboard wall and at least a portion of the outboard wall lie within the cavity between the outer wall and the inner wall of the tailgate.

An actuator assembly of an actuation system for a closure member of a vehicle is provided. The actuator assembly includes an actuator housing including a sensor housing. The actuator assembly also includes an electric motor disposed in the actuator housing and configured to rotate a driven shaft operably coupled to an extensible member that is coupled to one of a body or the closure member for opening or closing the closure member. The actuator assembly also includes an actuator controller disposed in the sensor housing of the actuator housing and coupled to electric motor and an accelerometer configured to sense movement of the closure member. The actuator controller is configured to detect the movement of the closure member using the accelerometer. The actuator controller then controls the opening or closing of the closure member based on the movement of the closure member using the electric motor.

A switched-mode light-emitting diode (LED) display unit satisfying fire-fighting smoke exhaust and ventilation requirements includes an LED display unit, a mounting member, an opening-closing actuator and a pressing member. The LED display unit is mounted on the mounting member and the mounting member is mounted on a display panel by an opening-closing actuator and pressed against the display panel by a pressing member. The switched-mode LED display unit provides the pressing member that works to release the pressed mounting member after obtaining a triggering command and the opening-closing actuator that turns on the LED display unit subsequently, thereby meeting the fire smoke exhaust ventilation requirement of the internal surface or the external surface of a building.

The pop-up apparatus includes a door check, a check link, the check link being configured to perform relative movement with respect to the door check between the one end and another end of the check link while being applied with a pushing force by the door check, a popup arm arranged on a side closer to the another end of the check link, the popup arm being configured to turn about a turning axis, the popup arm being configured to apply a force with a side of one end of the popup arm so as to perform the relative movement of the check link in a direction in which the vehicle door is opened, a cam portion having an outer peripheral surface and being configured to turn about a cam axis, and a crank lever configured to move along the outer peripheral surface of the cam portion.

A holder to be attached to a vehicle window plate includes a bottom portion, a first side portion provided to extend in a first direction perpendicular to the bottom portion and a second side portion opposite to the first side portion. A value t/w is 1.5 or more when a smallest value of distances between end portions of the first side portion and end portions of the second side portion is expressed by w, and a distance between a central portion of the first side portion and a central portion of the second side portion is expressed by t.

An electric vehicle (1) has a charging flap (10) articulated on a support structure by way of a four-bar linkage arrangement (14) so that the charging flap (10) can be moved between a closed position (FIG. 3A) and an open position (FIG. 3F). To simplify the actuation of the charging flap, the mechanism for actuating the charging flap (10) has a push-push element (20) combined with a spring device (15) that is assigned to the four-bar linkage arrangement (14).