An object processing system is disclosed that includes an object induction station at which objects are provided for processing. The object induction station includes at least one perception unit for providing perception data regarding an object, and an object processing system for receiving objects from the object induction station, and for urging an object into a first end of one of a plurality of chute location, each of which including a first end that is accessible by the carrier and a second end that is accessible by a mobile destination container of a plurality of mobile destination containers.

A factory interface for an electronic device manufacturing system can include a load lock disposed within the interior volume of a factory interface and a factory interface robot disposed within the interior volume of the factory interface. The factory interface robot can be configured to transfer substrates between a first set of substrate carriers and the first load lock. The factory interface robot can comprise a vertical tower, a plurality of links, and an end effector.

The invention relates to an arrangement for checking contours of pallets (18) to be put into storage in a rack system, said arrangement comprising: a pallet transfer station (12) which is designed to receive pallets (18) to be put into storage in the rack system; at least one sensor device (16a-16d) which is designed to detect whether a pallet (18) standing on the pallet transfer station (12) and objects supported by the pallet (18) are completely within a predefined contour; and an output unit (24) which is operationally coupled to the sensor unit (16a-16d) and is designed to output the detection result. The invention also relates to a rack system comprising at least one rack row, at least one stacker crane and at least one arrangement for checking contours, the pallet transfer station of which is designed such that pallets can be placed thereon from outside the rack system, which pallets can then be picked up by the stacker crane so as to be put into storage.

Goods storage and retrieval systems and materials handling vehicles are provided. The goods storage and retrieval system includes a multilevel warehouse racking system; a materials handling vehicle comprising a mast assembly, a picking attachment, and vehicle-based cart engagement hardware; a mobile storage cart; and a transporter comprising transporter-based engagement hardware. The transporter-based engagement hardware enables the transporter to engage, transport, and disengage the mobile storage cart. The vehicle-based cart engagement hardware is coupled to the mast assembly to (i) engage and disengage the mobile storage cart and (ii) transport the mobile storage cart to multiple levels of the multilevel warehouse racking system. The mast assembly and the picking attachment are configured to access multiple levels of the multilevel warehouse racking system. The picking attachment is configured to transfer totes between the multilevel warehouse racking system and the mobile storage cart.

Embodiments provide for systems and methods related to kiosks for personalizing a packaged article. The kiosks may also be used for storage, inventory management, retrieval, packaging, and/or personalization of packaged articles. The kiosks discussed herein differ from non-kiosk personalization systems, such as personalization systems installed on a factory or warehouse floor, in that the kiosks are self-contained personalization systems. In some embodiments, the kiosks are portable and can be moved between different sites or events. This portability allows the kiosks to personalize packaged articles for concerts, festivals, conventions, trade shows, and the like.

Embodiments provide for systems and methods related to kiosks for personalizing a packaged article. The kiosks may also be used for storage, inventory management, retrieval, packaging, and/or personalization of packaged articles. The kiosks discussed herein differ from non-kiosk personalization systems, such as personalization systems installed on a factory or warehouse floor, in that the kiosks are self-contained personalization systems. In some embodiments, the kiosks are portable and can be moved between different sites or events. This portability allows the kiosks to personalize packaged articles for concerts, festivals, conventions, trade shows, and the like.

A substrate processing apparatus includes: a carrier block including carrier placement parts and configured to load/unload a substrate into/from a carrier; a processing block provided on one side of the carrier block to process the substrate; first and second carrier placement parts of the carrier placement parts and provided side by side in a front-rear direction in a plan view; substrate placement parts provided to be arranged step by step vertically on one side of a substrate transfer region formed between the first and second carrier placement parts; a first substrate transfer mechanism provided in the substrate transfer region to deliver the substrate between the carrier of the first carrier placement part and a first substrate placement part of the substrate placement parts; and a second substrate transfer mechanism for moving upward and downward so as to deliver the substrate between first and second substrate placement parts.

A storage system includes a plurality of storage areas for receiving stored goods, the storage areas being situated in at least one storage level and being accessible by an associated handling device to store stored goods at the storage areas or retrieve them from these storage areas. A conveyor is provided which is designed as a continuous conveyor and is led on a storage level through the arrangement of the storage areas.

A conveyance device (100) comprises: a base member (81); a holding member (83) that moves along the base member (81); a motor (M) for advancing and retracting the holding member (83); a target (T) provided on the holding member (83); an optical distance sensor (86) positioned so as to face the target (T) when the holding member (83) is in the advanced position; and a control device (70). A processor (71) is configured such that: a basic rotation speed is applied to the motor (M) to advance the holding member (83); the actual distance from the optical distance sensor (86) to the advanced target (T) is measured by the optical distance sensor (86); a corrected distance for moving the holding member (83) to the advanced position is calculated on the basis of the measured actual distance; and the motor (M) moves the holding member (83) on the basis of the calculated corrected distance.

A two-dimensional rail system includes a first set of parallel rails arranged to guide movement of container handling vehicles in a first direction across the top of the frame structure, and a second set of parallel rails arranged perpendicular to the first set of rails to guide movement of the container handling vehicles in a second direction which is perpendicular to the first direction. The first and second sets of parallel rails dividing the rail system into a plurality of grid cells. A container handling vehicle for operation on the rail system includes a wheel base unit including sets of wheels for guiding the container handling vehicle along the rail system in the first and second directions; a body unit; and a lifting device. The body unit includes: a lower section which is provided on the wheel base unit; a support section extending vertically from the lower section; and a cantilever section extending horizontally from the support section. The lower section has a footprint with a horizontal extent which is equal to or less than the horizontal extent of one of the grid cells and a top surface which is at a first height. The support section has a footprint with a horizontal extent which is smaller than the footprint of the lower section. The cantilever section extends beyond the footprint of the lower section. The lifting device includes a lifting frame that is suspended from the cantilever section of the body unit. The lifting frame has a lowermost part at a second height when the lifting frame is docked in an upper position adjacent the cantilever section. The second height of the lowermost part of the lifting frame, when the lifting frame is docked in its upper position, is above the first height of the top surface of the lower section of the body unit.