In some embodiments, a mobile tote system includes a closeable mobile tote comprising an enclosure that includes a first radio-frequency-reflective surface and at least one radio-frequency-transparent layer. The system may include an engagement component that includes an RFID scanner having an RFID antenna. The engagement component may be configured to engage the mobile tote and to align the RFID scanner with the at least one radio-frequency-wave-transparent interface of the mobile tote to permit transmissions between the RFID antenna and the interior of the enclosure to pass through the radio-frequency-wave-transparent interface.

A method in which a probability of the occurrence of a disruption is issued and/or a measure is initiated which reduces the probability of the occurrence of this disruption if the occurrence of a disruption is probable, bases the probability on unit load properties of a conveyed unit load. In this method, the transport of this unit load is classified with regard to whether or not a disruption occurs during the transport of this unit load. The unit load properties are fed into a learning algorithm together with the transport classification. By repeating the steps for a number of unit loads, the probability of the occurrence of a disruption during the transport of the unit loads can be computed. Further, a picking system carries out the method presented.

A warehouse storage and retrieval system including an array of multilevel storage racks having at least one transfer deck, picking isles and storage areas disposed along picking isles, the storage areas being configured to hold differing loads, and a controller including a management module configured to variably size the storage areas of the array of multilevel storage rack modules and assign each of the variably sized storage areas to a corresponding one of the differing loads, wherein the storage and retrieval system is arranged to transport the differing loads for placement in the variably sized storage areas assigned by the controller.

A control device according to an embodiment includes a communication unit and a processor. The communication unit is configured to communicate with a transport vehicle and a host server, the transport vehicle being configured to move a movable shelf storing an article. The processor is configured to acquire from the host server, by the communication unit, a removal instruction indicating an article to be removed; specify, based on the removal instruction, the movable shelf having a plurality of shelves for storing the article and a shelf height at which the article is stored on the movable shelf; and switch between moving, by the transport vehicle, the specified movable shelf to a first position and a second position suitable for removing an article from a second shelf higher than the first shelf, based on the specified height.

Disclosed are systems and methods for determining a pick area arrangement for a storage facility. A method can include retrieving, by a computer system, historic pallet information for pallet SKUs and pick area information, determining, based on the information, a number of bays to allocate for each pallet SKU, determining, based on the information, a number of dynamic bays to allocate in the pick area, which receive pallet SKUs in high demand during a particular time, determining, based on the information, quantities of aisles to allocate as pick aisles in the pick area by simulating aisle arrangements with pallet SKUs from the historic pallet information and determining average travel times to complete pick orders having the pallet SKUs in the aisle arrangements, selecting the quantity of aisles providing a lowest average travel time, and assigning each pallet SKU from the historic pallet information to bays in the quantity of aisles.

A storage system having racks and an outer container that receives the racks, each rack receiving a plurality of sample boxes, each box having a wireless ID tag. In certain embodiments, the storage system has reader electronics external to and distinct from the racks and that directly read the wireless ID tag of each box in at least one rack without relying on any reader electronics of any rack. In other embodiments, each rack has a set of rack reader electronics that read the wireless ID tag of each box in at least one rack, and the storage system has at least one removable reader access device removably connectable to the set of rack reader electronics of a rack in order to transmit the ID number of the wireless ID tag of each box in the rack outside of the outer container.

Embodiments of the present disclosure can provide an automated mass rearing system for insect larvae. The automated mass rearing system can facilitate hatching, feeding, monitoring the growth and emergence of insect larvae and pupae. In some embodiments, the automated mass rearing system can include a production unit, a transportation unit, a storage unit, a dispensing unit, and a monitoring unit. In some embodiments, this automated mass rearing system can facilitate mass mosquito growth from egg hatching all the way through to full adults or certain stages in between such as the larvae rearing process (i.e., from larvae to pupae) with little or no human intervention. By automating the rearing and transportation of insect eggs, larvae, and pupae, deaths or developmental issues can be minimized. Various techniques and apparatuses are used in this automation that causes minimal disturbance to the insects during development, and thereby maximizing survival rate and fitness of the insects.

Embodiments of the disclosure include a computer implemented system including at least one processor and memory storing instructions. In one embodiment, a system receives a batch identifier, determines a number of containers, sends the number of containers to a user device, and receives a first container identifier from a user device. The system retrieves a location identifier of a first item, sends the location identifier to the user device, and receives a physical location identifier from the user device. The system sends to the user device the first item when the physical location identifier matches the location identifier. The system receives a physical item identifier of the first item and sends a destination to the user device to bring the container.

A baggage management system includes: a storage rack including a plurality of receptacles shaped and structured to retain one or more baggage items; a baggage transportation system including a plurality of automated guided vehicles (AGVs) configured to transport one or more baggage items between a pick up point, a drop off point, and the storage rack, each AGV including a a wireless communication unit and a controller configured to control movement of the specific AGV based on received control instructions; and a baggage administration server including a processor, a memory unit, and a wireless communication interface, and configured to receive a request to store or retrieve a baggage item from the storage rack, determine the position of the one or more AGVs, identify the one or more AGVs required to either store or retrieve a baggage item as defined in the request, and transmit control instructions to the AGVs.

A warehousing and shipping operation support system stores first coded information contained in an optical recognition code attached to each of a plurality of objects, acquires the first coded information contained in an optical recognition code attached to a target object out of the plurality of objects, automatically acquires location information of a working radio communication terminal, and associates the stored first coded information with the acquired location information of the working radio communication terminal.