A projection instruction device includes a processor and a memory that specifies each of a plurality of packages and store package specifying information including information related to a destination of each of the packages in a factory. The projection instruction device generates a first projection image for instructing conveyance of the received package to a first destination that is a storage place based on the package specifying information for each package, instructs the image projection device to project the first projection image, in a case that the package specifying information for each package stored in the memory indicates a second destination, generates a second projection image for instructing conveyance of the package to the second destination, and instructs the image projection device to project the second projection image.

A remotely operated vehicle includes an arrangement to provide a pre-alert and tracking of a position of the vehicle following a travelling route relative to tracks laid out on rails in x-, y-directions on a rail system. The vehicle has first and seconds sets of wheels connected to drives for moving the vehicle in corresponding x-, y-directions on the rail system. The arrangement includes at least one sensor module provided with at least four sensors. A first sensor is directed vertically downwards to detect the rails in the x-direction on the sensor module. A second sensor is directed vertically downwards to detect the rails in the y-direction on the sensor module. A third sensor is positioned on the sensor module to detect a corner of an intersection between the rails in the x-direction and y-direction. A fourth sensor is configured to detect a remaining distance to the arrival of the vehicle at a set position, by detecting the rails in the x direction when travelling in the y direction, and detecting the rail in the y direction when travelling in the x direction. The fourth sensor is placed at a predefined position on the sensor module. A controller is provided on the vehicle to receive the output from at least one of the sensors and to pre-alert the remaining distance of the arrival of the vehicle at the position.

A multi-zone automated storage and retrieval system (ASRS) and a method for controlling operation of robotic storage/retrieval vehicles (RSRVs) therein are provided. The multi-zone ASRS includes first and second storage zones isolated by at least one barrier and including first and second groups of storage locations respectively for accommodating storage units therein. The multi-zone ASRS includes one or more portals opening through the barrier(s) between the storage zones, and at least one track layout. The track layout(s) includes first and second track areas occupying the first and second storage zones respectively, and one or more connective track segments interconnecting the first and second track areas through the portal(s). The RSRVs deposit and retrieve the storage units to and from the storage locations and travel on the first and second track areas via the connective track segment(s) to respectively access the first and second groups of storage locations therefrom.

A picking system includes a multi-tier sorting device having ports in a plurality of tiers at different levels in a top-bottom direction, and sorts and discharges each of articles to one of the ports in the plurality of tiers; a plurality of first transport devices respectively corresponding to the ports in the plurality of tiers; and a second transport device configured to receive the articles from the first transport device and transport the articles. The second transport device has a second transport surface movable upward and downward, and, in a state where the second transport surface is located at a height corresponding to a terminal end portion of the first transport surface of one of the plurality of first transport devices, the second transport device receives the articles discharged from the terminal end portion of the first transport surface and transports the articles, with use of the second transport surface.

This disclosure is directed to automated warehouse facilities that are configured to assemble mixed pallets. The warehouse facilities can include one or more layer handling devices that are configured to remove layers from pallets in a delayering operational mode, and to add layers to pallets in a palletizing operation mode. The warehouse facilities also may include one or more item retrieval devices that are configured to retrieve individual items from storage racks. The warehouse facilities can include other automated devices as well.

A system includes a shelving unit, a sensor and a processor. The shelving unit includes a pocket. The sensor is associated with the pocket and is configured to obtain a parameter indicative of a weight of the pocket. The processor configured to execute instructions stored in a nontransitory computer-readable medium. The instructions include obtaining the parameter indicative of the weight of the pocket from the sensor, determining the weight of the pocket based on the parameter, comparing the weight of the pocket to a predetermined value, generating a paint chip order that includes a request in response to the weight of the pocket being below the predetermined value, and transmitting the paint chip order to a computing system.

The present disclosure provides a method and apparatus for controlling a warehousing system, a guard door, and a warehousing system. The method includes: obtaining a door-opening-request signal of a guard door, and determining a target region corresponding to the guard door; determining that a state of a first goods-carrying tool in the target region is a non-operating state; and controlling a state of the guard door to be an open state. The safety of the target region where a user enters is ensured. In addition, the state of the goods-carrying tool in the target region corresponding to the guard door is controlled to be a non-operating state and a goods-carrying tool in a non-target region is kept to operate normally, and therefore, when compared with the related art of stopping all goods-carrying tools, the warehousing efficiency is improved and a hardware loss caused to the goods-carrying tool due to repeated starting and stopping is reduced.

A transfer operation control unit changes, according to an operating state index indicating a level of an operating state of a plurality of transport vehicles (1) present on a travel path, a setting of a transfer operation such that a required transfer time (Tr) from start to completion of the transfer operation is increased as the level of the operating state is reduced, while maintaining at least one setting of a traveling speed of the transport vehicles (1).

Disclosed are a shelf device, a robot and a warehousing system. The shelf device comprises: at least two shelves spaced apart, a channel being defined between two adjacent shelves; a track assembly located above the channel and detachably connected to tops of the two adjacent shelves. The track assembly is provided with a track extending in a passing direction of the channel. The track is adapted to be fitted with a robot moving along the channel to limit its position. The stability of the overall structure of the shelf device can be improved and the deformation efficiency of the shelves can be reduced, thereby improving the stability and success rate of the robot to access the material boxes.

A method for picking objects is specified, in which at least one object is removed from a source loading aid and placed into a target loading aid using a robot. After the operation of removing the object, a first sensor system of the robot is used to check whether at least one object is held by the robot. A number and/or a type of the at least one removed object is ascertained using the second sensor system. The operation of placing the at least one object into the target loading aid is aborted or modified if no object is held by the robot or the number and/or the type of the at least one removed object does not contribute to completing the picking order, which defines a desired number and/or desired type of objects in the target loading aid. Furthermore, a device and a computer program product for performing the presented method is specified.