Disclosed herein is an active air flap for vehicles, which includes a flap part configured to open and close an outside air inlet of a grill located at a front of a vehicle through a plurality of paths, a drive unit configured to provide a driving force to the flap part, and a link unit configured to transmit the driving force of the drive unit to the flap part, wherein the link unit includes a loader shaft configured to rotate in conjunction with an actuator shaft of the drive unit, a link bar having one end connected to both ends of the loader shaft in a longitudinal direction, and the other end located at both ends of the flap part, and a link panel configured to connect the other end of the link bar and both ends of the flap part.

Disclosed herein is an active air flap for vehicles, which includes a frame unit having a hollow structure configured to communicate with an outside air inlet of a radiator grill, a flap part connected to the frame unit, and including a flap unit configured to open and close the outside air inlet and a fixing protrusion protruding from both ends of the flap unit, a drive unit configured to provide a driving force to the flap part, a link unit disposed between the flap part and the drive unit to transmit the driving force of the drive unit to the flap part, and a fixing unit configured to restrain the movement of the flap unit closing the outside air inlet on an opening/closing path of the flap unit to prevent the flap part from being pushed or twisted by an external force, wherein the frame unit includes a first guide groove having a straight section and a curved section configured as a single path to guide the opening/closing path of the flap unit, and a second guide groove having a stepped portion spaced from the first guide groove to guide a straight path of the flap unit.

A hybrid vehicle includes active air flaps provided on a front-end module and a controller that controls the active air flaps based on a coolant temperature according to an outdoor air temperature, an inverter temperature of a drive motor according to an outdoor air temperature, an inverter temperature of an starter-generator according to an outdoor air temperature, a temperature of a low DC converter according to an outdoor air temperature, a transmission oil temperature according to an outdoor air temperature, or an engine oil temperature according to an outdoor air temperature, controls the active air flaps based on a refrigerant pressure according to an outdoor air temperature, controls the active air flaps based on an operation mode of a cooling fan, or controls the active air flaps based on an intake temperature according to an outdoor air temperature for each of driving modes of the vehicle.

Disclosed is a method for controlling a thermal regulation circuit of a vehicle, the circuit comprising first (2) and second (4) heat exchangers situated in series in a circulation direction of an air flow intended to pass through them in this order, the circuit further comprising an additional heat exchanger (16) situated upstream from the first heat exchanger (2) in the circulation direction of the air flow, the circuit being configured to allow the circulation of a refrigerant fluid in the first exchanger (2) and the circulation of a heat transfer fluid in the second exchanger (4) and in the additional exchanger (16), the method comprising a step of generating or increasing a flow rate of the heat transfer fluid in the additional exchanger (16) depending on operating modes of the circuit.

A vehicle shutter device includes first and second flaps, one actuator, and a link mechanism. The link mechanism includes a connecting rod that couples the flaps to each other such that the flaps rotate in synchronization with each other. The shutter device is provided with stoppers configured to prohibit each of the flaps from being displaced beyond a normal opening and closing range when the link mechanism is in a normal state. When coupling between the connecting rod and the first flap is released in the first pivotally attaching portion in a state where coupling between the connecting rod and the second flap is maintained in the second pivotally attaching portion, the actuator is allowed to rotate beyond a normal rotation range of the actuator corresponding to the normal opening and closing ranges of the first and second flaps.

The invention relates to a cooling system for a vehicle, the cooling system comprising a cooling fan comprising a ram air turbine disposed in an aperture of a fan shroud, the fan shroud comprising: an opening, a shutter mechanism movable between a closed position in which it closes the opening, and an open position in which it opens the opening so that a ram air flow can pass through the opening, wherein the fan shroud further comprises: a velocity sensor configured to measure ram air flow velocity, a temperature sensor configured to measure ram air flow temperature, and an actuator configured to move the shutter mechanism between the closed position and the open position based on measured ram air flow velocity and measured ram air flow temperature.

A transmission element for a controllable air inlet of a motor vehicle and configured to produce a pivoting movement to pivotably mounted closing elements. Each closing element is connected by a link part which is arranged outside the pivot axis, to a corresponding link element of the transmission element (Ü).

An air guide apparatus for a vehicle includes a front wheel housing at least partially surrounding a front wheel, and having an air outlet which is open to the front wheel, a first vane assembly including a plurality of first vanes which are tiltable in a position adjacent to the air outlet, and a first driving mechanism by which the plurality of first vanes are driven, and a second vane assembly including a plurality of second vanes which are tiltable in a position adjacent to the plurality of first vanes, and a second driving mechanism by which the plurality of second vanes are driven.

An active dual roll shutter apparatus for a vehicle has two lead screws rotated by power from a single motor. First and second roll screens are simultaneously operated upward and downward in opposite directions along the two lead screws to open a flow path when the lead screws rotate, thereby improving sealability of the flow path and aerodynamic performance of the vehicle.

Adjustment device for adjusting an air influencing element of a motor vehicle between at least a first position and a second position, comprising a driving unit for adjusting the air influencing element between at least the first position and the second position, provided with an input shaft and an output shaft which is at a distance from the axis of the input shaft, wherein the driving unit has a first part which is provided around the input shaft of the driving unit, and has a second part which is provided around the output shaft of the driving unit, wherein the adjustment device is furthermore provided with a failsafe mechanism, wherein the failsafe mechanism engages the first part of the driving unit.