An assembly for a ventilation system of a vehicle is provided. The assembly is configured to use a single actuator to control direction of a vent and additionally control the flow rate of that vent. The assembly may comprise a single rotatable control member with two routes, one route used for controlling flow rate and one route for controlling flow direction. Each route may have a straight portion and curved portion.

A drive unit (1) for actuating a plurality of functions of an air vent system or of an air distribution system, having an electric motor drive (3) with a drive shaft which can be driven in a first rotational direction or in a second rotational direction, and a switching mechanism with at least one first and one second output shaft (5), via which functions of the air vent system can be actuated, the switching mechanism being configured, during a drive of the drive shaft in the first rotational direction, to transmit a torque from the drive shaft only to the first output shaft (5), and, during a drive of the drive shaft in the second rotational direction, to transmit a torque from the drive shaft only to the second output shaft (5).

An air outlet device for an air-conditioning system of a vehicle includes an air outlet assembly disposed at air vents of the air-conditioning system and a control unit. The air outlet assembly includes a plurality of first air doors and a plurality of driving components, the plurality of driving components are respectively connected to the plurality of first air doors, and each driving component is configured to drive the corresponding first air door. The control unit is connected to the plurality of driving components, and is configured to control the plurality of driving components to drive the plurality of first air doors to open or close independently.

An air vent apparatus for a vehicle and a vehicle provided with the air vent apparatus includes: a controller mounted on a vehicle body; a mounting base mounted on the vehicle body and including a discharge port formed at a rear end portion of the mounting base; an air guide assembly mounted adjacent to the discharge port of the mounting base; and a drive assembly electrically connected to the controller and configured to drive the air guide assembly engaged to the drive assembly to rotate to a first position, a second position, or a third position under a control of the controller.

Ventilation control systems and methods for a vehicle are presented. The system includes a touch screen that is configures to display an object and receive a selection of a part of the object. The system also includes an air vent that comprises at least one controllable fin and a motor that can control the configuration of that fin. A control circuitry of the system configures the fin, using the at least one motor, to direct air from the air vent to a location that corresponds to the selected part of the object.

An assembly for a ventilation system of a vehicle is provided. The assembly is configured to use a single actuator to control direction of a vent and additionally control the flow rate of that vent. The assembly may comprise a single rotatable control member with two routes, one route used for controlling flow rate and one route for controlling flow direction. Each route may have a straight portion and curved portion.

An air duct assembly for a vehicle air distribution system includes a first duct defining a first passage and a second duct defining a second passage separate from the first passage. The first and second passages are fluidly connected to a common outlet for flowing air to a windshield of the vehicle. The assembly further includes a third duct defining a third passage for flowing air to a side glass of the vehicle. The second and third passages are fluidly connected to a common inlet for receiving air from the blower motor. The third passage is fluidly connected to a lateral outlet that is separate from the common outlet, with the lateral outlet flowing air to a side glass of the vehicle. The assembly further includes at least one acoustic baffle disposed within the second passage and configured to reduce a transmission of the blower noise through the second passage.

A blowing device includes: a casing which is connected to an air conditioner of a vehicle; a ventilation path which is formed from an inlet to an outlet of the casing; a second inclined portion which is provided on the side of the outlet in the casing; an intermediate portion which is formed between the inlet and the second inclined portion; a wind direction variable member that is provided in the ventilation path and is able to change a wind direction of an inflow wind through the inlet toward the intermediate portion or the outlet; and a cover member that is provided with a hole portion penetrating therethrough in an X direction and the cover member is disposed in the +X direction in relation to an end portion of the second inclined portion in the −X direction.

A motor driven air vent device for a vehicle can perform not only left/right angular rotation operation of a vertical wing for adjusting a left/right-directional airflow direction of air discharged indoors but also an opening/closing operation of a damper for interrupting or allowing an indoor discharge of air using a link bar for performing a straight line motion to the left or right thereof by driving a motor and a cam plate for angularly rotating by the link bar, etc. in a motor driven manner.

The present invention relates to an air nozzle device for a vehicle comprising a housing defining an interior volume and having an air inlet at one side, an air discharge opening at a second side and an air flow channel through the housing for transporting a flow of air between the air inlet and the air discharge opening, the device further comprising an air flow regulator mechanism comprising a rod member comprising a rack, at least one flap member comprising a pinion, and an assembly guide mechanism arranged to be moveable between an assembly position and a non-assembly position, wherein the rack and pinion is arranged to, in an assembled state, interact to rotate the at least one flap member about an axis between an open and a closed position to regulate the flow of air in the air flow channel, the assembly guide mechanism is, in the assembly position, arranged to interact with the at least one flap member and the rod member to assemble the rack and pinion, and the assembly guide mechanism is, in the non-assembly position, arranged to obstruct the assembly of the rack and pinion.