An active grille shutter arrangement having an assembled modular frame with a plurality of primary frame pieces formed by extrusion. Each one of the plurality of primary frame pieces has a first end, a second end and at least one key slot extending between the first end and the second end. Each of the plurality of frame pieces also includes a hollow bore extending through the each one of the plurality of primary frame pieces forming an aperture at the first end and an aperture at the second end. When the modular frame is assembled there is an upper frame portion and lower frame portion, both formed from one of the plurality of primary frame pieces. The arrangement also includes a number of alternate frame and vane pieces that allow several different active grille shapes and configurations to be formed.

A radiator shutter for a motor vehicle for controlled engine ventilation, having a frame in which at least two louvres are mounted rotatably to pivot from a closed position to an open position. A motor which drives a single louvre is provided in or on the frame on an engine side of the frame. On the same side is a coupling element which synchronously transmits the rotation of the louvre to the other louvres. A locking disc is provided for each louvre on the mounting side of the frame facing away from the engine side of the frame, in the region of the mounting provided there for the louvres. The locking discs have a form which, if at least one of the locking discs does not rotate synchronously with all the other locking discs, blocks the rotational movement of the locking discs in a force-fitting and form-fitting manner.

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.

The invention relates to a device for adjusting (80) an air stream for an air inlet of a motor vehicle, comprising a housing (81) defining a flow duct (82) into which an air stream flows and in which a cooling unit comprising at least one heat exchanger (83) is at least partially arranged, the housing comprising a flap (85) designed to be placed in an open position providing access to the heat exchanger, said flap being designed to close the access in the closed position, said access (86) being designed in particular to enable removal of the heat exchanger through a substantially translational movement.

Disclosed embodiments include apparatuses, vehicles, machines, equipment, and methods for selectively allocating airflow between different heat exchangers. In an illustrative embodiment, an apparatus includes a first heat exchanger configured to dissipate heat from at least one first system. A second heat exchanger is configured to dissipate heat from at least one second system. An airflow controller is configured to receive an intake airflow and to direct an output airflow to selectively direct at least a portion of the output airflow to either or both of the first and second heat exchangers.

The present invention provides a front end structure in which cooling performance can be improved. A front end structure according to an aspect of the present invention includes a frame portion 41 that surrounds an outer circumferential part of a heat exchanger and supports the heat exchanger; a duct portion 42 that is connected to an inner circumferential edge of the frame portion 41 and guides outside air, which is taken in through a first introduction port 61, in at least an up-down direction through a space between the duct portion 42 and a front surface of the heat exchanger; and a division portion 43 that is provided in at least one of the frame portion 41 and the duct portion 42 and partitions the heat exchanger into a heat exchange area in which outside air is able to pass through in a front-rear direction and a support area which is positioned on a side circumferentially outward from the heat exchange area and is supported by the frame portion 41.

The invention relates to a device (2) for closing a motor vehicle cooling module, comprising a first and a second closing element (4a, 4b) for closing air inlets (6) in a motor vehicle, a first and a second guide element (8a, 8b) for guiding the closing elements (4a, 4b) during an opening and a closing movement, respectively a first and a second control element (10a, 10b) for controlling an opening and a closing movement of the closure elements (4a, 4b), the closure elements (4a, 4b) and the guide elements (8a, 8b) being arranged relative to one another and being controllable by the control elements (10a, 10b) in such a way that air inlets (6) in a motor vehicle are guided by the closure elements (4a, 4b) along a vehicle width (B), it being possible for two air inlets (6) arranged opposite one another along a vehicle width (B) to be opened and closed simultaneously by the closure elements (4a, 4b), the closure elements (4a, 4b) and the guide elements (8a, 8b) are arranged relative to one another and can be controlled by the control elements (10a, 10b) in such a way that the closure elements (4a, 4b) can be opened during an opening movement from the vehicle centre (M) towards the vehicle outer regions (A1, A2) and can be opened during a closing movement from the vehicle outer regions (A1, A2) towards the vehicle centre (M).

A front-end section for a motor vehicle, having at least one air inlet opening for supplying a cooling air volume flow to a cooling module arranged behind the air inlet opening. In the air inlet opening, there is arranged in each case one slat device with multiple adjustable slats which are arranged adjacent to one another and which are each pivotable about a pivot axis between a closed slat position and an open slat position. The slats each have, at their end facing toward the cooling module, an air-guiding element which is configured such that, in an at least partially open slat position, the cooling air volume flow is diverted in the direction of the cooling module by the air-guiding element.

An air guiding element, in particular a cooling air louver for an air inlet of a motor vehicle body, with a flat main body and with a bearing region. The air guiding element is arranged such that it can be pivoted by way of its bearing region about a pivot axis. The flat main body is formed from two shells, and with a carrier element which is arranged between the shells. The carrier element is molded between the two shells by an injection molding method such that the two shells are connected to one another in this way.

A module for accommodating electronic circuitry which advantageously is able to take advantage of air in a climate system for cooling of the electronic circuitry. In one aspect, there is provided a module for accommodating electronic circuitry in a vehicle, the module includes: at least one attachment surface for attachment of electronic circuitry thereon, an air guiding structure for receiving an air flow for cooling of the attachment surface, the air guiding structure having a wall member including the attachment surface such that the wall member provides a thermal path between the attachment surface and the air in the air guiding structure, wherein the air guiding structure includes an inlet configured to receive air for cooling of the attachment surface wherein the air flow is an air flow used for climate control in the vehicle.