An order fulfillment and delivery system for autonomously fulfilling orders while en route to a delivery location. The system includes a delivery vehicle having a storage area, a robotic system at least partially disposed within the storage area and one or more processors. The one or more processors being configured to receive an order of one or more inventory items, generate container retrieval instructions for the robotic system to perform based on the received order and transmit to the robotic system the container retrieval instructions to perform. The robot system includes a container retrieval device movable in at least two dimensions to engage and move a container, based upon the container retrieval instructions, from a first location within the delivery vehicle to a second location within the delivery vehicle.

A system and method are provided for facilitating selective delivery of aggregate material in bulk from a back of a dump truck or other truck bed to one or more wheelbarrows in a controlled manner. The disclosed embodiments further provide a system that could be operated by a single individual, including the single individual that is then manually moving the wheelbarrow from the truck to the particular location of the delivery site where the aggregate material is to be finally dispensed. The disclosed systems provide a self-contained mechanical device that is comparatively-easily mountable to the back of a dump truck or other truck bed for use, and is electrically, or electric over hydraulically, powered through the electrical system of the vehicle in order to avoid any need for additional power requirements.

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.

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.

Methods for handling bulk material in a manner that reduces dust, noise, and emissions are provided. The presently disclosed techniques use portable containers to transfer bulk material from a transportation unit to a blender inlet. The containers may be carried to the location on the transportation unit, where a hoisting mechanism is used to remove the container from the transportation unit and place it in a desired location. When bulk material is needed at the blender inlet, the hoisting mechanism may position the container of bulk material onto an elevated support structure. Once on the support structure, the container may be opened to release bulk material to a gravity feed outlet, which routes the bulk material from the container directly into the blender inlet. The disclosed containerized bulk material transfer system and method allows for reduced dust, noise, and emissions on location.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base have omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base, one or more modular containers, and the lid may be electrically linked to provide information to be used in a number of ways. For example, the electrical link may allow two or more modular robots to communicate with each other, enable external displays of multiple modules to act as one large unit, control the motion of the drawers, e.g., allowing them to open/close, and allow the processor(s) in the lid to communicate with the drive system of the omni-directional wheels. A set of alternating interlocking rails and tracks on corresponding surfaces enable the various layers of the modular robot to interlock with one another. Interlocking of multiple modular containers may be established by sliding one surface over the other. These sections may be used to create modular robots of varying sizes.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base have omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base, one or more modular containers, and the lid may be electrically linked to provide information to be used in a number of ways. For example, the electrical link may allow two or more modular robots to communicate with each other, enable external displays of multiple modules to act as one large unit, control the motion of the drawers, e.g., allowing them to open/close, and allow the processor(s) in the lid to communicate with the drive system of the omni-directional wheels. A set of alternating interlocking rails and tracks on corresponding surfaces enable the various layers of the modular robot to interlock with one another. Interlocking of multiple modular containers may be established by sliding one surface over the other. These sections may be used to create modular robots of varying sizes.

Provided is an assembly including a dump body configured to be supported by a frame to be moved relative to the frame between a dump position and a load position. The dump body includes first and second sidewalls, a front wall, a floor having a first opening, a tailgate, and an apron below the tailgate, the apron having a second opening substantially perpendicular to the first opening. The assembly also includes an endless conveyor configured to direct material to the second opening and being removably attached to the dump body below the floor such that material is prevented from exiting the dump body through the first opening.

Provided is an assembly including a dump body configured to be supported by a frame to be moved relative to the frame between a dump position and a load position. The dump body includes first and second sidewalls, a front wall, a floor having a first opening, a tailgate, and an apron below the tailgate, the apron having a second opening substantially perpendicular to the first opening. The assembly also includes an endless conveyor configured to direct material to the second opening and being removably attached to the dump body below the floor such that material is prevented from exiting the dump body through the first opening.

The present invention relates to an automated guided vehicle (1) having a frame (10) designed to receive a material handling accessory (3). The automated guided vehicle (1) is characterized by at least one displacement element (14) which is designed to be moved in and out in at least one horizontal direction (Y) relative to the frame (10) at least to one side beyond the external dimensions of said frame, wherein the displacement element (14) is further designed to carry the material handling accessory (3) along with it.