A moveable ramp and method of moving cargo using a moveable ramp. The moveable ramp includes a ramp structure comprising a plurality of planar portions including a lower inclined portion, an upper inclined portion, a first horizontal portion extending between the lower inclined portion and the upper inclined portion and a second horizontal portion extending from an upper end of the upper inclined portion wherein the horizontal portions act as landing zones for a delivery tug moving the cargo onto and off of the ramp. The ramp also includes a locking mechanism at the top end to secure the ramp to a pallet, for sample. The ramp may further include automatic struts such as gas struts.

A manufacturing machine includes a feeding system that has first and second processing conveyors arranged in series along the processing path, and a transfer unit interposed between there-between that cyclically transfers the products from the first processing conveyor to the second processing conveyor, picking up the products in a pick-up station arranged in the area of the first processing conveyor and releasing the products in a release station arranged in the area of the second processing conveyor. The transfer unit has a plurality of trays, each having a series of seats designed to house a product, a moving system, which cyclically moves the trays between the pick-up and release stations, a first transferring and second transfer devices arranged in the pick-up station and release stations, respectively to transfer the products from the first processing conveyor to a tray, and from a tray to the second processing conveyor, respectively.

A carrier for transporting goods includes a supporting mechanism, a lifting mechanism, a first detection component, and a controller. The supporting mechanism includes at least one entrance and connected to a mobile robot. The lifting mechanism includes a lifting driving member and a bearing part. The lifting driving member is arranged on the supporting mechanism, and the bearing part is arranged on the lifting driving member to be driven to be elevated or lowered by the lifting driving member. The first detection component is arranged on the bearing part and is located in front of the at least one entrance for detecting a position of the goods. The controller is arranged on the supporting mechanism and is respectively communicatively connected with the lifting driving member, the first detection component, and the mobile robot. A mobile lifting conveyor having the carrier is also provided.

Embodiments of the present disclosure provide adaptive autonomous guided vehicles capable of performing a myriad of specialized task operations. Some embodiments include a base vehicle, a vertical carousel including at least one carousel conveyor shelf, where the vertical carousel is affixable to a top of the based vehicle, and a rotatable top conveyor affixable to a top of the vertical carousel. Some embodiments include processing circuitry communicatively coupled to with each of the base vehicle, the vertical carousel, and the rotatable top conveyor, where the processing circuitry executes computer-coded instructions that at least partially cause the processing circuitry to control each of the base vehicle, the vertical carousel, and/or the rotatable top conveyor. The processing circuitry controls such components to perform any of a number of specific task operations. Some embodiments align multiple adaptive autonomous guided vehicles that interact to perform specific task operation(s).

Among other things, a connection assembly for motion along a rail is disclosed. The connection assembly can include a first plate assembly, a second plate assembly, and a release assembly. The first plate assembly can include a first stop mounted to a first base. The second plate assembly can include a second stop mounted to a second base and a post mounted to the second base. The release assembly can include a rod and a spring. The rod can include an outward extension. The spring can be disposed between the extension and the second stop. The release assembly can be configured to occupy: a first state such that the spring pushes the extension against the first stop and thereby biases the first base away from the second base; and a second state such that the spring pushes the extension against the post.

Among other things, a connection assembly for motion along a rail is disclosed. The connection assembly can include a first plate assembly, a second plate assembly, and a release assembly. The first plate assembly can include a first stop mounted to a first base. The second plate assembly can include a second stop mounted to a second base and a post mounted to the second base. The release assembly can include a rod and a spring. The rod can include an outward extension. The spring can be disposed between the extension and the second stop. The release assembly can be configured to occupy: a first state such that the spring pushes the extension against the first stop and thereby biases the first base away from the second base; and a second state such that the spring pushes the extension against the post.

Automated and/or autonomous material handling equipment include conveyors and/or baggage carts that can be used in material handling systems for safe and efficient package movement and management within facilities such as warehouses, airports, campuses and/or other locations. In some examples, material handling systems include a conveyor that can be tilted and/or raised in a motorized and automated manner. In some embodiments, the autonomous baggage carts include a cart body defining an interior space configured for receiving baggage items, driven wheels attached to the cart body, an onboard microcomputer and antenna configured for wireless communication with a remotely located computerized baggage handling management and control logistics system, and a door conveyor movably attached to the cart body. In some examples, an automated conveyor system described herein can be used separately from the baggage cart.

A robotic item retrieval and transport apparatus includes at least one item retrieval mechanism that is minimally exposed while stored and/or engaged in loading or unloading of objects relative to a deck (e.g., upper surface) thereof. Actuators and at least major portions of one or more movable implements are arranged below the deck. Loading and/or unloading of objects may include lateral sliding, such as by pulling the object while it is supported by an extrinsic support surface. At least substantial portions of an item retrieval mechanism may remain outside a central target area of a deck, to provide a unobstructed or minimally obstructed deck surface for holding objects. The apparatus may be used with at least one movable pallet element. A pallet element and/or a retrievable item may include one or more features detectable by a sensor.

A robotic item retrieval and transport apparatus includes at least one item retrieval mechanism that is minimally exposed while stored and/or engaged in loading or unloading of objects relative to a deck (e.g., upper surface) thereof. Actuators and at least major portions of one or more movable implements are arranged below the deck. Loading and/or unloading of objects may include lateral sliding, such as by pulling the object while it is supported by an extrinsic support surface. At least substantial portions of an item retrieval mechanism may remain outside a central target area of a deck, to provide a unobstructed or minimally obstructed deck surface for holding objects. The apparatus may be used with at least one movable pallet element. A pallet element and/or a retrievable item may include one or more features detectable by a sensor.

Provided are systems, methods, and devices for storing and transporting articles with a multi-shelf storage unit. A system for article handling includes a multi-shelf storage unit and a robotic unit. The multi-shelf storage unit includes a plurality of shelves disposed on a frame, the plurality of shelves including at least one vertically moveable shelf configured to move in first and second vertical directions relative to the frame, and a lift mechanism configured to automatically drive, in response to receiving a drive input, the at least one vertically moveable shelf in the first or second vertical direction. The robotic unit includes an end effector disposed on a robotic manipulator for engaging an article and a lift mechanism actuator that is connectable to the lift mechanism and configured to provide the drive input to actuate the lift mechanism.