Powered retractable vehicle step assist systems and methods are provided. The steps systems are configured for installation (e.g., after market installation) and use with a vehicle. The system can include a stepping member movable between a retracted position and a deployed position with respect to the vehicle. The system can further include a vehicle interface. A controller of the step system can be configured to process information received from the vehicle interface and, based at least partly on the processing of the information, cause movement of the stepping member between the retracted position and the deployed position.

An axle carrier for a motor vehicle is disclosed having at least two attachment points, a metallic upper shell and a lower shell of fiber composite material coupled to the metallic upper shell. A first load path extending through the metallic upper shell between the at least two attachment points in an edge region, and a second load path shorter that the first load path extending through the lower shell.

Vehicle step assist systems and methods are provided. The steps systems are configured for installation (e.g., after market installation) and use with a vehicle. The system can include a stepping member. The system can further include a vehicle interface configured to electronically communicate with an existing communication bus of the vehicle, such as through a connection with an existing electronics port of the vehicle. A controller of the step system can be configured to process information received from the vehicle interface and, based at least partly on the processing of the information, perform certain operations.

A pedal assembly for a vehicle, including a pedal arm, a pivot shaft operatively attached to the pedal arm and defining a pivot axis, and identical and housing components. The housing components each have a body defining an inner surface and an outer surface, a mount formed on the body and adapted for attachment to the vehicle, a receiver formed on the body extending away from the outer surface, a coupler formed on the body extending away from the outer surface and disposed in spaced relation with the receiver, and a bore defined along the inner surface arranged between the receiver and the coupler to support at least a portion of the pivot shaft. Each respective receiver engages the corresponding coupler in an interlocked configuration with the bores being aligned about the pivot axis to rotatably support the pivot shaft for rotation about the pivot axis.

A lens for a lamp assembly is provided herein. The lens has a radial portion including a plurality of grooves extending radially from a central point and a plurality of concentrically aligned channels intersecting the plurality of grooves. The outer channel and two adjacent grooves define a sector. Each sector includes one or more ridges. A central portion of the lens includes a generally flat outer surface.

A lens for a lamp assembly is provided herein. The lens has a radial portion including a plurality of grooves extending radially from a central point and a plurality of concentrically aligned channels intersecting the plurality of grooves. The outer channel and two adjacent grooves define a sector. Each sector includes one or more ridges. A central portion of the lens includes a generally flat outer surface.

Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.

A tonneau cover access panel assembly connectable to a vehicle that eliminates the need for side rails to both locate and tension a tonneau cover. The assembly also reduces weight and complexity. The assembly incorporates a readily accessible rear latching system that reduces or eliminates interference with the tonneau cover during operation. The assembly also incorporates a tonneau cover tensioning system. The tension seals out environmental elements and holds the tonneau cover and locating bows in place. The assembly holds the tonneau in the closed tension state keeping the tonneau cover secured and tight until the cover is opened by an operator. The assembly is movable between a closed position and a fully open/stowable position and any intermediate positions. The assembly is also movable between at least a first open position and the deployed position for more limiting access to the cargo bed of the vehicle when desired.

A work vehicle includes a cabin to cover an operator's seat on a traveling body. A cabin frame that constitutes a framework of the cabin includes a pair of left and right front pillars, a pair of left and right rear pillars, a front beam, a rear beam, and side beams. The front beam couples upper end portions of the front pillars to each other. The rear beam couples upper end portions of the rear pillars to each other. Each of the side beams couples to each other upper end portions of each of the front pillars and each of the rear pillars that stand at a front and rear. The rear beam is formed to have a U-shaped cross-section by presswork of a metal plate material.

A vehicle body assembly is described herein, including a first structural component and a second structural component. The first structural component may be a roof component or a side panel, and include a first part including a first metal and a second part including a second metal different than the first metal. The second part is formed on a peripheral edge portion of the first part and defines a mounting flange for the first structural component. The second part is joined to the first part via an ultrasonic additive manufacturing (UAM) interface. The second structural component is including the second metal and is joined to the second part at the mounting flange via a resistance spot weld (RSW) joint.