Disclosed herein is an apparatus and method of autonomous Controlled Environment Agriculture (CEA) comprising a fully autonomous growing environment. More specifically, disclosed herein is an apparatus and method in which a plurality of frame assembly may be stored and manipulated within a track assembly that is configured within a rack through the motivational input a carriage-mounted manipulators. Each frame assembly is configured to be coupled to an adjacent frame assembly supported by the track assembly by at least one coupler disposed on a forward end and a rearward end of each frame assembly. With the frame assembly including a low friction bearing surface to orient within a track assembly, it may be configured to satisfy various utilities necessary within the farm, such as but not limited to the housing grow media for the cultivation or the housing of electromechanical systems.

The invention refers to tray (1) for a storage lift and a method for producing a tray (1). In order to provide a tray (1) that has an increased load-bearing capacity, which is at the same time compact and easy to manufacture, it is provided according to the invention that the bottom (3) is plastically deformed at at least one area (19) spaced from at least one edge region (12, 14).

In a first aspect, the invention relates to a storage device comprising a frame and a compartment system suspended within the frame, the compartment system providing at least two n levels of storage compartments, accessible from a front side of the device, and suitable for storing general cargo, the device further being adapted for vertical movability of the compartment system. In particular, the compartment system is rectangularly suspended from four lifting belts extending vertically upwards. In a further aspect, the invention provides the use of the storage device.

A cage can be positioned around a medical balloon, such as an angioplasty balloon, to assist in a medical procedure. The cage can include a plurality of strips, each extending between a set of rings including first and second rings. As the balloon expands, the first and second rings move closer together and allow the strips to expand outward. The cage may have wedge dissectors on the strips.

A cage can be positioned around a medical balloon, such as an angioplasty balloon, to assist in a medical procedure. The cage can include a plurality of strips, each extending between a set of rings including first and second rings. As the balloon expands, the first and second rings move closer together and allow the strips to expand outward. The cage may have wedge dissectors on the strips.

Asynchronous item delivery utilizes a system including a first depot and a first mobile robot at a first site and a second depot and a second mobile robot at a second site. A centralized control system manages asynchronous delivery of items through the first depot and the second depot such that the first mobile robot can retrieve an item from the first depot and deliver the item to a transportation systems for transition to the second site, such that the second depot at the second site can, in an asynchronous fashion, receive the item and deliver the item to the second mobile robot for transportation to the ultimate destination at the second site. Two or more sites can be coordinated by the centralized control system for management of movement of items through a supply chain using asynchronous item delivery and movement through each respective site to an ultimate destination.

In one embodiment, an inventory storage module has a first conveyor segment, a second conveyor segments offset from the first segment along a vertical direction, a first vertical lift at a first end of the module, and a second vertical lift at a second end of the module, which together define a movement path that is elongate along a longitudinal direction between the first and second ends. The storage module can translate inventory storage containers around the movement path until a desired one of the inventory storage containers is presented at one of the first end and the second end. In another embodiment, a plurality of instances of the storage module are arranged in a vertical stack of independently controllable storage modules.

A goods-storage and order-fulfillment system having a rack store consisting of stackable rack units forming a multi-level shelving rack, with each shelf configured to store a plurality of articles, and including an automated depositing and retrieving machine that has its own travel drive and is automatically controlled and contactlessly guided for depositing trays or articles into and/or retrieving the same from the shelving racks. The system includes an automated transport unit for receiving articles from or transferring articles to the depositing and retrieving machine to transport an individual article unloaded from the tray to a picking station or to transfer an individual article to the tray or to the machine, the transport unit being floor-bound and having its own travel drive and being automatically controlled and contactlessly guided. The system includes at least one picking station supplied with individual articles by the transport unit for at least partial order fulfillment.

An automated warehouse system and method are provided for controlling the internal microclimate of receptacles within a warehouse or order fulfilment facility. The system provides independent environmental condition monitoring and regulation for each tote. The system enables individual totes to be maintained at adequate or substantially ideal conditions, independent of its position within a storage system or the environmental conditions of adjacent totes in the storage system. The totes may include self-contained environmental control systems and/or the storage system may include environmental control inputs to adjust or maintain the environmental conditions within a particular tote. The system is operable to monitor and control the microclimate of a tote while it is stored at a storage location within the storage system or in a buffer, and may be operable to monitor and/or control the microclimates of the totes while they travel throughout the system.

An automated warehouse system and method for climate controlled storage and order fulfilment comprises a control system, an automated storage and retrieval system (“ASRS”) with a storage rack defining storage locations for storage receptacles for containing goods, where either at least some of the storage receptacles are individually temperature controllable or the storage rack is at least partially disposed in a frozen environment. A transportation system is coupled with the ASRS for transporting storage receptacles to and from the automated storage and retrieval system, and a workstation is in communication with the transportation system for picking goods to a temperature-controlled order receptacle. The control system directs order fulfilment operations comprising directing goods requiring stable temperature control from the ASRS to the workstation and directs an operator to pick the goods from the storage receptacle to the temperature-controlled order receptacle to maintain the goods within a required temperature range.