A device conveying a solid material into a radially-arranged stockpile. The device has a trailer chassis, with at least one wheeled axle at a first end thereof and, at a second end thereof, means provided for attaching the chassis to a tractor in a mobile condition and for fixed mounting in an operational condition. A stacking conveyor is mounted near the first end of the chassis. A power unit for generating electrical and hydraulic power is positioned on the chassis. A feed system is mounted to the chassis and extends generally along the length thereof from the second end to the first end, to receive the solid material at the second end and transport the solid material to the stacking conveyor.

A device conveying a solid material into a radially-arranged stockpile. The device has a trailer chassis, with at least one wheeled axle at a first end thereof and, at a second end thereof, means provided for attaching the chassis to a tractor in a mobile condition and for fixed mounting in an operational condition. A stacking conveyor is mounted near the first end of the chassis. A power unit for generating electrical and hydraulic power is positioned on the chassis. A feed system is mounted to the chassis and extends generally along the length thereof from the second end to the first end, to receive the solid material at the second end and transport the solid material to the stacking conveyor.

An autonomous robot vehicle includes a front side and an energy absorbing system. The front side includes a front bumper and a front face including a frame defining a cavity. The energy absorbing system includes an energy absorbing member mounted in the cavity of the frame, and an inflatable airbag. The energy absorbing member is configured to reduce impact on an object struck by the autonomous robot vehicle. The inflatable airbag is mounted on the front side of the autonomous robot vehicle such that when the inflatable airbag is deployed, the inflatable airbag is external to the autonomous robot vehicle.

An autonomous robot vehicle includes a front side and an energy absorbing system. The front side includes a front bumper and a front face including a frame defining a cavity. The energy absorbing system includes an energy absorbing member mounted in the cavity of the frame, and an inflatable airbag. The energy absorbing member is configured to reduce impact on an object struck by the autonomous robot vehicle. The inflatable airbag is mounted on the front side of the autonomous robot vehicle such that when the inflatable airbag is deployed, the inflatable airbag is external to the autonomous robot vehicle.

An apparatus is provided for moving and securing articles in a pickup truck cargo bed. The pickup truck cargo bed may have opposing sidewalls, cab wall, tailgate, and floor. The apparatus comprises a plurality of tracks configured to connect to the pickup truck cargo bed, the plurality of tracks extending substantially along a longitudinal length of the pickup truck cab and defining a channel. A push plate slidably is mounted to the plurality of tracks with a movement member, and the push plate configured to stand perpendicular to the floor. The apparatus also comprises an actuator in mechanical communication with the push plate, the actuator configured to move the push plate to a desired position in the pickup truck cargo bed. An adjustable enclosed area is defined by the push plate, opposing side walls, and tail gate.

An autonomous system for loading or unloading an autonomous vehicle, in accordance with aspects of the present disclosure, includes one or more module(s) that include at least one of a compartment or a sub-compartment where the module(s) are located in an autonomous vehicle, a robotic movement apparatus configured to autonomously move items to or from the module(s), one or more processors, and at least one memory storing instructions which, when executed by the processor(s), cause the autonomous system to autonomously move an item, using the robotic movement apparatus, to or from the at least one module of the autonomous vehicle.

An autonomous system for loading or unloading an autonomous vehicle, in accordance with aspects of the present disclosure, includes one or more module(s) that include at least one of a compartment or a sub-compartment where the module(s) are located in an autonomous vehicle, a robotic movement apparatus configured to autonomously move items to or from the module(s), one or more processors, and at least one memory storing instructions which, when executed by the processor(s), cause the autonomous system to autonomously move an item, using the robotic movement apparatus, to or from the at least one module of the autonomous vehicle.

A telescoping extendable boom and a foldable telescoping extendable boom for transporting an item, are disclosed. The foldable telescoping extendable boom having tubular elements (12) and (14) and (15, 17, 18, 19) and (20) each arranged with a longitudinally extending track (25, 29) inside the tubular element. Each longitudinally extending track (25, 29) supports a single shuttle (26) and (30) respectively, internally inside its tubular element (17) and (15), respectively, for movement therealong. Each shuttle (26) and (30) is equipped with a clamp (27) and (30) to selectively clamp the item (298). The longitudinally extending tracks (25, 29) of immediately connecting telescoping tubular elements (17) and (15) are located opposite each other. The inner tubular elements inside said telescoping extendable boom are arranged at their near ends to allow their shuttles to access shuttles of outer tubular elements to enable the clamps (27) and (31) thereof to transfer a said item (298) therebetween.

A managing apparatus for positioning rental vehicles includes a memory storing instructions and a processor configured to execute the instructions to cause the managing apparatus to access model information and location information for a plurality of autonomous vehicles, receive a request including a delivery location and a chosen model for renting, select an autonomous vehicle of the chosen model from among the plurality of autonomous vehicles based on the model information, the location information, and the delivery location, instruct the selected autonomous vehicle to fully-autonomously or semi-autonomously travel to the delivery location, and instruct the selected autonomous vehicle to switch to manual operation mode at the delivery location for manual operation by a vehicle rental customer.

A managing apparatus for positioning rental vehicles includes a memory storing instructions and a processor configured to execute the instructions to cause the managing apparatus to access model information and location information for a plurality of autonomous vehicles, receive a request including a delivery location and a chosen model for renting, select an autonomous vehicle of the chosen model from among the plurality of autonomous vehicles based on the model information, the location information, and the delivery location, instruct the selected autonomous vehicle to fully-autonomously or semi-autonomously travel to the delivery location, and instruct the selected autonomous vehicle to switch to manual operation mode at the delivery location for manual operation by a vehicle rental customer.