Methods and systems are provided for cooling assembly configured to control a temperature of a vehicle component relying on cooling from a cooling air stream. In one example the cooling assembly may include a plurality of blades fixed to a surface of a cooling device. The cooling assembly may be bimetallic so that a position of the blades is self-regulatory and automatically adjusted based on heat conduction.

To provide a shutter grille device that can reduce the number of opening and closing operations and extend product life. A shutter grille device includes: a shutter grille provided in an air intake for guiding air into a power station in which a power source of a vehicle is provided; and a controller that controls opening and closing of the shutter grille. The controller disables closing of the shutter grille during a first interval after opening of the shutter grille, and has a second interval before enabling opening of the shutter grille after closing; and the first interval is set longer than the second interval.

An air flap device for a motor vehicle, having an air flap member with a flow-through opening and having a plurality of air flaps, which protrude into the flow-through opening or pass through it and which are each mounted on the air flap member so that they can move between a blocking position as a working position and a feed-through position as another working position, wherein each air flap in its blocking position interferes with flow through the flow-through opening as intended to a greater extent than in the feed-through position, wherein the air flap device has, as one operating position, a closed position, in which each air flap of the plurality of air flaps is in the blocking position as the working position associated with the closed position, and has an open position as another operating position, in which each air flap of the plurality of air flaps is in the feed-through position as the working position associated with the open position, the air flap device having a drive device for supplying a driving force for the movement of the air flaps between the blocking position and the feed-through position and a coupling device for transfer of the driving force supplied by the drive device to the air flaps, the coupling device is coupled to the plurality of air flaps such that at least some of the air flaps, because of an adjustment operation of the air flap device into a target operating position, reach their target working positions associated with the target operating position at different points in time.

An air flap device for a motor vehicle, having an air flap member with a flow-through opening and having a plurality of air flaps, which protrude into the flow-through opening or pass through it and which are each mounted on the air flap member so that they can move between a blocking position as a working position and a feed-through position as another working position, wherein each air flap in its blocking position interferes with flow through the flow-through opening as intended to a greater extent than in the feed-through position, wherein the air flap device has, as one operating position, a closed position, in which each air flap of the plurality of air flaps is in the blocking position as the working position associated with the closed position, and has an open position as another operating position, in which each air flap of the plurality of air flaps is in the feed-through position as the working position associated with the open position, the air flap device having a drive device for supplying a driving force for the movement of the air flaps between the blocking position and the feed-through position and a coupling device for transfer of the driving force supplied by the drive device to the air flaps, the coupling device is coupled to the plurality of air flaps such that at least some of the air flaps, because of an adjustment operation of the air flap device into a target operating position, reach their target working positions associated with the target operating position at different points in time.

Disclosed is an engine temperature regulating device installed to a cool air inlet of a casing of an engine. The engine temperature regulating device includes a power source, a link rod module connected to the power source, a control module and a fan cover module including a fixed casing and a movable casing. The control module is provided for detecting a temperature when the engine is turned on to control the power source to drive the link rod module, so as to control the rotation of the connected movable casing and further adjust an air intake hole of the fixed casing to a smooth or obscured state.

Disclosed is an engine temperature regulating device installed to a cool air inlet of a casing of an engine. The engine temperature regulating device includes a power source, a link rod module connected to the power source, a control module and a fan cover module including a fixed casing and a movable casing. The control module is provided for detecting a temperature when the engine is turned on to control the power source to drive the link rod module, so as to control the rotation of the connected movable casing and further adjust an air intake hole of the fixed casing to a smooth or obscured state.

An active air flap control apparatus for a vehicle and an active air flap control method are provided. The active air flap control apparatus includes: a storing unit storing a plurality of critical values with respect to each of a cooling water temperature, a refrigerant pressure, and an intake air temperature; a first sensor measuring the cooling water temperature; a second sensor measuring the refrigerant pressure; a third sensor measuring the intake air temperature; and a controller combining the measured cooling water temperature, the measured refrigerant pressure, and the measured intake air temperature with each other. Based on the plurality critical values stored in the storing unit, the controller determines an opening rate of an active air flap.

An active air flap control apparatus for a vehicle and an active air flap control method are provided. The active air flap control apparatus includes: a storing unit storing a plurality of critical values with respect to each of a cooling water temperature, a refrigerant pressure, and an intake air temperature; a first sensor measuring the cooling water temperature; a second sensor measuring the refrigerant pressure; a third sensor measuring the intake air temperature; and a controller combining the measured cooling water temperature, the measured refrigerant pressure, and the measured intake air temperature with each other. Based on the plurality critical values stored in the storing unit, the controller determines an opening rate of an active air flap.

A thermoactuator easily installed in an object without compromising the operating characteristics of the thermo-element has an element case, containing wax that expands and contracts with changes in temperature; a supporting portion attached at one end to the element case by crimping, slidably supporting a shaft at another end; a cylindrical casing having an opening in one end, at least a portion of the supporting portion pressed through the opening in the one end of the cylindrical casing; and a flange expanding outward from the one end of the cylindrical casing, in which through-holes are formed for mounting the thermoactuator to an object to which the thermoactuator is to be attached. The element case is supported by one end of the supporting portion housed within the object to which the thermoactuator is to be attached and the casing is mounted on the object via the flange.

A thermoactuator easily installed in an object without compromising the operating characteristics of the thermo-element has an element case, containing wax that expands and contracts with changes in temperature; a supporting portion attached at one end to the element case by crimping, slidably supporting a shaft at another end; a cylindrical casing having an opening in one end, at least a portion of the supporting portion pressed through the opening in the one end of the cylindrical casing; and a flange expanding outward from the one end of the cylindrical casing, in which through-holes are formed for mounting the thermoactuator to an object to which the thermoactuator is to be attached. The element case is supported by one end of the supporting portion housed within the object to which the thermoactuator is to be attached and the casing is mounted on the object via the flange.