A vehicle radiator assembly includes: a common inlet tank having a high temperature inlet chamber and a low temperature inlet chamber; a common outlet tank spaced apart from the common inlet tank and including a high temperature outlet chamber and a low temperature outlet chamber; a high temperature radiator core including a plurality of high temperature tubes connecting the high temperature inlet chamber and the high temperature outlet chamber, and a plurality of high temperature cooling fins arranged with the plurality of high temperature tubes; a low temperature radiator core including a plurality of low temperature tubes connecting the low temperature inlet chamber and the low temperature outlet chamber, and a plurality of low temperature cooling fins arranged with the plurality of low temperature tubes; and a bimetal interposed between the high temperature radiator core and the low temperature radiator core.

A vehicle radiator assembly includes: a common inlet tank having a high temperature inlet chamber and a low temperature inlet chamber; a common outlet tank spaced apart from the common inlet tank and including a high temperature outlet chamber and a low temperature outlet chamber; a high temperature radiator core including a plurality of high temperature tubes connecting the high temperature inlet chamber and the high temperature outlet chamber, and a plurality of high temperature cooling fins arranged with the plurality of high temperature tubes; a low temperature radiator core including a plurality of low temperature tubes connecting the low temperature inlet chamber and the low temperature outlet chamber, and a plurality of low temperature cooling fins arranged with the plurality of low temperature tubes; and a bimetal interposed between the high temperature radiator core and the low temperature radiator core.

A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

The invention relates to a control device (1), in particular for a motor vehicle, for controlling at least one flap configured to be moved between an open position and a closed position by an actuator, said device (1) comprising at least one member (8) made of shape memory material configured to be supplied with electric power so as to deform between a first state and a second state in order to disconnect said at least one flap from the actuator if the actuator fails.

According to the invention, said device (1) has a track holder (10) that is mounted in said device (1) in a rotationally retained manner and has at least two conductive tracks (101) for supplying said at least one member (8) made of shape memory material with electric power, and said at least one member (8) made of shape memory material has at least two contactor elements (87) configured to each be arranged in electrical contact with an associated conductive track (101) at least when said at least one member (8) made of shape memory material is in the first state.

The invention also relates to a corresponding frame.

A mounting device with an anti-rotation feature is provided. The mounting device includes a base including a cavity adapted to receive a portion of a shock absorber assembly. The base provides for movement of the shock absorber assembly relative to a vehicle body in at least one degree of freedom. The base substantially prevents movement of the shock absorber assembly relative to the vehicle body in at least another degree of freedom. The mounting device includes a pin integrated with the base on a side distal from the cavity. The pin is substantially parallel to an axis of the shock absorber assembly. The pin is adapted to engagingly couple to one or more cushions and a vehicle frame.

A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

A flap control device spring driven toward open position upon actuator failure.

A shield assembly is employed for a friction brake used to decelerate a road wheel of a vehicle. The vehicle has a body with a first body end configured to face an incident ambient airflow, a second body end opposite of the first body end, and an underbody section spanning a distance between the first and second ends. The shield assembly includes a first shield component arranged proximate the brake and rotationally fixed relative to the vehicle body. The shield assembly also includes a second shield component operatively connected to the first shield component for shifting relative thereto. The shield assembly additionally includes an actuator employing a shape memory alloy element to shift the second shield component relative to the first shield component in response to a temperature of the brake to thereby direct at least a portion of the airflow to the brake and control temperature thereof.

A mounting device with an anti-rotation feature is provided. The mounting device includes a base including a cavity adapted to receive a portion of a shock absorber assembly. The base provides for movement of the shock absorber assembly relative to a vehicle body in at least one degree of freedom. The base substantially prevents movement of the shock absorber assembly relative to the vehicle body in at least another degree of freedom. The mounting device includes a pin integrated with the base on a side distal from the cavity. The pin is substantially parallel to an axis of the shock absorber assembly. The pin is adapted to engagingly couple to one or more cushions and a vehicle frame.