A bumper assembly for a material handling vehicle is provided. The bumper assembly includes a main body which includes at least one cutout. The bumper assembly also includes a window plate that may be removably coupled to the main body and cover the at least one cut out. The bumper assembly can also include a lower section that may be removably coupled to the main body and includes a protection plate extending below the at least one cutout.

A vehicle bumper includes: a bumper beam, a bumper face, covering a vehicle body front surface of the bumper beam, and a buffer component, provided between the bumper beam and the bumper face. The buffer component includes a platelike component configured to be folded upon collision load. The buffer component includes a folded part, and two surface parts that are connected through the folded part and are opposite to each other with a gap therebetween in a front-rear direction of the vehicle. A pressure pipe configured to be deformed by being clamped between the two surface parts so as to detect impact is provided in the gap. A lower space part that avoids interference between the bumper beam and a setting part for the pressure pipe in the buffer component is provided below the bumper beam.

Provided herein is an autonomous or semi-autonomous vehicle fleet comprising a plurality of autonomous or semi-autonomous vehicles coordinated by a fleet management module. Each vehicle may be configured to receive a modular unit, wherein the modular unit is configured to secure a consumer product.

A front end structure is provided for a vehicle that includes a bracket for attaching front crash sensors to the vehicle. The front end structure includes an engine compartment and a hood connected to the engine compartment by a hood latch and a pair of hinges. The bracket is connected to the hood latch and the front crash sensors to maintain palpability with the vehicle through the hood in a collision.

A pedestrian safety system is disclosed herein. The pedestrian safety system includes a vehicle crossing arm system, an alarm annunciator, a plurality of sensors and an in-vehicle display device. In one embodiment, the vehicle crossing arm system may include a crossing arm and a crossing arm motor. The pedestrian safety system may be useful for improving the ability to detect movement of pedestrians in proximity to a vehicle. In particular, for detecting movement of children in proximity to a school bus.

Motor vehicle exterior part comprising: a wall comprising a face intended to be visible from outside the vehicle, the face being coated with a first layer; a second layer covering the first layer; and a heating element arranged between the two layers on the first layer, the first layer comprising an area of increased thickness and the heating element being arranged only on the area of increased thickness of the first layer.

A vehicle is disclosed that includes a vehicle body and at least one sensor assembly that is supported on the vehicle body. The at least one sensor assembly is configured to detect an external object and includes a housing portion and a sensor that is supported within the housing portion such that the sensor is oriented at a fixed (e.g., downward) angle.

A bracket presenter for an ultrasonic welder includes a one-piece first bracket portion and a one-piece second bracket portion mounted relative to one another. First and second tapered features are respectively provided by the first and second bracket portions and are nested relative to one another. The first and second tapered features engage in an extended position and are spaced from one another in a compressed position to provide a clearance enabling the first and second bracket portions to float lateral relative to one another. A spring biases the first and second bracket portions apart.

A sensor attachment structure in which a sensor bracket that holds a sensor configured to detect an external world of a moving body is attached to an exterior member of the moving body and a structure member of the moving body, comprises: a first absorption mechanism configured to hold the sensor bracket such that the sensor bracket can retreat from an initial position of the sensor bracket in a state in which an external load does not act along a front-and-rear direction of the moving body in response to action of the external load; and a second absorption mechanism configured to hold the sensor bracket such that the sensor bracket can swing from the initial position in response to the action of the external load, while being held by the first absorption mechanism.

Systems and methods for autonomous delivery management are disclosed. In various embodiments, the system includes one or more processors and a memory storing instructions which, when executed by the processor(s), cause the autonomous delivery management system to provide a user interface for a customer to enter subscription information, receive subscription information from the user interface where the subscription information includes an item and a time interval for regularly delivering the item to the customer, store the subscription information, determine a handling itinerary for the item that includes delivery of the item in compliance with the time interval, and communicate instructions to an autonomous vehicle based on the handling itinerary.