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 apparatus for modifying aircraft cabin airflow includes a redirector configured to receive an airflow from an inlet of an aircraft cabin. The redirector is configured to downwardly redirect at least a portion of the airflow. In one embodiment, the redirector includes a dividing portion configured to be oriented generally parallel to the airflow received at the redirector from the cabin inlet, and further includes a redirecting portion configured to be oriented in a generally downward direction. In another embodiment, the redirector includes an elongated protrusion configured to be positioned on a ceiling of the aircraft cabin.

An air outlet nozzle, in particular for a motor vehicle, includes: a tube-shaped nozzle body; a first air guide element which is arranged in the tube-shaped nozzle body, and which is in contact with the tube-shaped nozzle body and forms a screw shape; a second air guide element which is arranged in the tube-shaped nozzle body, and which is in contact with the tube-shaped nozzle body and forms a screw shape. The first air guide element and the second air guide element are offset from one another in the tube-shape nozzle body, such that a first airway and a second airway are formed in the tube-shaped nozzle body. A moving adjustment element closes the first airway in a first position, and releases the first airway in a second position.

For air-conditioning within a vehicle interior of a motor vehicle, an air vent is provided with at least one air-directing device located in the region of an air outlet opening. The air vent is configured to allow air flowing out of the air outlet opening to flow, by way of the Coanda effect, in a directed manner along a surface which is adjacent to the air outlet opening. The air-directing device and the adjacent surface are inclined in relation to each other by an angle of inclination which is between 23° and 27°, and the directed air has a volumetric flow of between 30 m.sup.3/h and 700 m.sup.3/h.

A vehicle air conditioning unit is installed in a vehicle, and the vehicle travels with self-driving that eliminates need for an occupant to operate the vehicle by a foot of the occupant and normal driving that requires the occupant to operate the vehicle by the foot. The vehicle air conditioning unit includes a foot outlet portion that defines a foot outlet open in a vehicle cabin, blown air flowing through the foot outlet toward the foot of the occupant, and an outlet changing device that changes a position to which the blown air flowing through the foot outlet flows. A controller of the vehicle is configured to control the outlet changing device such that the blown air is directed further rearward during the self-driving compared to during the normal driving.

In the manufacturing of an operating element (10) for an air vent, a first partial element (12) is manufactured from a hard component in a first injection molding process and a second partial element (14) is manufactured from a soft component in a second injection molding process. The second partial element (14) forms a bearing (20) for a support of the operating element (10) on a vane (22) of the air vent. During its manufacture, the second partial element (14) is connected with the first partial element (12) by adhesion and/or by geometric shaping. The two partial elements (12, 14) that are captively connected with each other constitute a prefabricated unit.

Embodiments of the invention provide air conditioning system for use in a motor vehicle, the air conditioning system comprising a controller, at least one primary vent and an air delivery apparatus for location in a dashboard of a motor vehicle, the apparatus comprising: at least one secondary vent; and means for moving the at least one secondary vent between a retracted position in which the at least one secondary vent lies rearward of an A surface of the dashboard and a deployed position in which the at least one secondary vent is exposed for delivery of air to a zone of the vehicle, the controller being operable to: control the air conditioning system to provide a flow of air from the at least one primary vent while the air delivery apparatus is in a retracted position; and control the at least one vent to assume the deployed position responsive to a demand for a flow of air from the at least one secondary vent.

An air outlet assembly for airflow in a vehicle interior is disclosed. The air outlet assembly may comprise a housing, a vertical guide assembly, a horizontal guide assembly and an operator control to actuate a vertical guide mechanism and a horizontal guide mechanism. The operator control may comprise a knob and a shaft providing an axis. Rotation of the operator control may comprise rotation of the shaft about the axis; pivoting of the operator control may comprise linear movement of the knob between a raised position and a lowered position. The operator control may translate to actuate an air door assembly to permit airflow and to obstruct airflow. Translation of the operator control may comprise linear movement of the shaft in a direction along the axis. The operator control may actuate the vertical guide mechanism independently of the horizontal guide mechanism.

A user-actuated control mechanism that controls airflow to an air nozzle device in a vehicle includes a push button, an actuating mechanism, and a flow control valve. The button, in a first actuating sequence, translates from an initial position to an end position and back to the initial position, so that the mechanical actuating mechanism displaces the control valve from an open position to a closed position. In a second actuating sequence, the button translates from the initial position to the end position and back to the initial position, so that the mechanical actuating mechanism displaces the flow control valve from the closed position to the open position. The valve is displaced in both sequences when the button is translated from the initial position to the end position, or is displaced in both sequences when the button is translated from the end position to the initial position.

So as to guide an air current flowing out of an air vent for a motor vehicle, an air deflection element, which can be moved transversely in an air channel of the air vent, is disposed upstream of an air guide body in a flow direction, which includes air passages, for which the air deflection element includes congruent windows.