Implementations disclosed and claimed herein provide a wheel cover system. In one implementation, an inward force exerted against a wheel cover of the wheel cover assembly in an inward direction towards the hub is received. The inward force overcomes a spring bias of a spring of the receiver and translates the wheel cover assembly in the inward direction. A first rotational force rotating the wheel cover assembly in a first direction is received. The first post guides and engages the first hook, and the second post guides and engages the second hook during rotation. A first positive feedback is generated in response to the inward force and the first rotational force. The wheel cover assembly is releasably locked to the receiver by translating the wheel cover assembly in the outward direction using an outward force generated by the spring bias. The outward force provides a second positive feedback.

A transportation refrigeration system including: a transportation refrigeration unit comprising a motor; a power conversion unit configured convert an amplitude, a frequency and a phase of an input electrical power signal, wherein the power conversion unit comprises a first power bridge, a DC link and a second power bridge; an energy storage device configured to supply electrical power to the motor via the power conversion unit during a road mode; a first switch configured to selectively connect the first power bridge to the energy storage device or the motor; and a second switch configured to selectively connect the second power bridge to the motor or a power grid; wherein the first switch and second switch are positioned to connect the first power bridge and second power bridge to specified sources and outputs during each of the road mode and the standby mode.

The invention concerns a trim panel arrangement for trimming a body element of a vehicle, with a pivotably mounted air guide device which is movable by means of a kinematic arrangement into a retracted first function position and a fully extended second function position and vice versa. At low speeds and also at high speeds, this should ensure an optimum aerodynamics of the motor vehicle in the air flow. This is achieved in that the air guide device is formed in two parts and comprises a first and a second trim part which are pivotably connected together, and that the kinematic arrangement is formed from a primary and a secondary lever drive. The invention furthermore concerns a method for forced movement of the air guide device.

An air flap apparatus for a motor vehicle, encompassing: a frame having an air passthrough opening; a first air flap arrangement and a second air flap arrangement respectively encompassing at least one displaceable first and second air flap; a common motion drive system for displacing the first and the second air flap arrangement; a motion coupling for coupling both the first and the second air flap arrangement to the motion drive system,
the first air flap arrangement and the second air flap arrangement being respectively displaceable between a blocking position having a greater degree of coverage of the air passthrough opening and a passthrough position having a lesser degree of coverage of the air passthrough opening;
the motion coupling the first and the second air flap arrangement to the motion drive system in such a way that the first and the second air flap arrangement are drivable by the motion drive system asynchronously for a displacement motion, the motion coupling encompasses a toggle lever linkage having a first and having a second toggle lever that are connected to one another, pivotably around a toggle joint axis, to form a toggle joint; the first toggle lever being motion-transferringly coupled to the first air flap arrangement; and the second toggle lever being motion-transferringly coupled to the second air flap arrangement; and the motion drive system being motion-transferringly coupled to the first and/or to the second toggle lever.

A sealed actuator with internal clutching assembly including an output shaft, output detent ring, moving detent ring, and a wave spring, which is fit inside a sealed housing. The moving detent ring is able to move axially to the output shaft and the output detent ring is able to rotate on the output shaft. Intermeshing ramped teeth of these rings are held together by a wave spring and allow the output shaft to rotate and transmit torque of a motor through a main gear operably coupled to an output gear mounted on the output shaft to the outside of the housing. During predetermined high loads, the output and moving detent rings ramped teeth create an axial force that overcomes the load from the wave spring, which allows moving detent ring to disengage and output shaft to rotate freely to help prevent damage to the actuator.

A vehicle body front structure (10) includes: a shutter mechanism (19), an under cover (20), and a cooling duct (21). The shutter mechanism includes an upper shutter (54) and a lower shutter (55). The under cover covers a power device, a cooling device, and a peripheral component from below. Air is sent from the lower shutter to the cooling duct, and the cooling duct includes: an intake port portion (75), a first discharge port portion (91), and a second discharge port portion (98). Air is sent from the lower shutter to the intake port portion. The first discharge port portion and the second discharge port portion are positioned at the back of a vehicle body of the power device, and send air toward the peripheral component.

A device for regulating an air stream for an air inlet of a motor vehicle may include a duct defining a flow channel in which an air stream flows. A cooling unit is arranged in the duct and includes at least one heat exchanger and a motor-fan unit. Additionally, the duct includes at least one sound absorption means arranged so that it at least partially limits the propagation of noise annoyance to the outside of the duct. A motor vehicle may include the regulation device.

An aerodynamic bicycle rim comprising: a circumferential outer portion comprising a circumferential outer surface, the circumferential outer portion adapted to seat a bicycle tire; a nose; and a set of sidewalls, each sidewall extending radially from the nose of the aerodynamic bicycle rim to a corresponding transition to the circumferential outer surface to form a rim body having a maximum rim body width that is greater than a maximum width of the bicycle tire. The aerodynamic bicycle rim is operable to seat the bicycle tire so that the aerodynamic bicycle rim and the bicycle tire form an asymmetrical cross-sectional shape.

Methods and systems for providing multi-zone climate control for a vehicle. One system includes a power source, a plurality of switches, a first zone heating/cooling device, a second zone heating/cooling device, and an electronic controller. The electronic controller is configured to operate the plurality of switches to supply current bi-directionally through the first zone heating/cooling device, bi-directionally through the second zone heating/cooling device, or bi-directionally through a series connection of the first zone heating/cooling device and the second zone heating/cooling device.

A motor vehicle body includes an air-guiding device and a trailer coupling mounting device. The air-guiding device is formed in a rear-end region of the motor vehicle body, and the trailer coupling mounting device is adjustable into a rest position and into an active position. The trailer coupling mounting device, in at least the rest position, is at least partially covered by the air-guiding device, which is settable into a first operating position and a second operating position. For positioning of the trailer coupling mounting device into its active position, the trailer coupling mounting device is movable along a body longitudinal axis of the motor vehicle body, and, before or together with the positioning of the trailer coupling mounting device into its active position, the air-guiding device is settable into an intermediate position which has a pivot angle greater than a pivot angle of the second operating position.