A dispatcher system associated with a manufacture execution system (MES) of a plant, where the MES uses a production database storing a table containing state information of a plurality machines in the plant to manage operation of the plurality of machines, the dispatcher system including a cache device to store a random accessible data sheet mapped to the table; and a processing device to provide a user interface to receive a dispatch application constructed based on a plurality of dispatch rules, the dispatch application comprising a database command directed to access the state information stored in the production database, convert the database command into a key-based search instruction in a target programming language, execute the key-based search instruction using a key to access the random accessible data sheet to generate a production plan, and issue the production plan to the MES to manage the operation of the plurality of machines.

System (1) for sharing device-related data by means of remote data transmission, in particular machining-specific parameters, of machining devices (30, 35), in particular wood machining devices, for machining of workpieces preferably consisting at least in sections of wood, wood material, synthetic material and/or glass, comprising: a main computer (15) for creating and providing a database (10) in which the device-related data can be managed, a first workstation (20) of a first machining device (30) which can be connected to the main computer (15) via a data communication link, and a second workstation (25) of a second machining device (35) which can be connected to the main computer via a data communication link, with device-related data being able to be stored in the database (10) of the main computer (15) by at least one of the two workstations (20, 25) and thereby being able to be made available for the other of the two workstations (20, 25).

A manufacturing system (20) comprises: one or more stores (84; 80A-80C; 92) for raw materials, work-in-progress (WIP), and finished goods; a plurality of manufacturing cells (40A-40F), each cell includes: one or more machines (42A-42C) for manufacturing an assembly; and a programmable logic controller (PLC) (44) for controlling the machines; one or more devices (60, 70) for moving raw material, WIP, and finished goods; and one or more servers (32) for communicating with the PLCs and the devices. The one or more servers further have programming for: instructing (642) the plurality of manufacturing cells to assemble finished goods from the raw materials; instructing (628, 632) the one or more devices to move said raw materials and finished goods; and just in sequence (JIS) skipped assembly recovery steps (730) for the manufacturing cells and devices.

A system for managing data in an industrial production environment includes a distributed database system stored on a plurality of embedded controller devices. Each respective embedded controller device comprises: a distributed database instance and a database management application. The distributed database instance is configured to store data collected from the industrial production environment by the respective embedded controller device. The database management application is configured to facilitate distributed queries and transactions on the plurality of embedded controller devices.

A system for monitoring a process step during manufacturing of an assembly sheet includes a detection camera configured to capture a first image of the assembly sheet, the first image including a locating feature of the assembly sheet, a vacuum hold-down device for selectively inhibiting advancement of the assembly sheet along a process step line for a predetermined measurement time, and a measurement camera configured to capture a second image of the assembly sheet responsive to the vacuum hold-down device inhibiting advancement of the assembly sheet, the second image including one or more features of a coupon of the assembly sheet.

A control system configured to use a database and a data storage area includes a control device for controlling a process executed on an object; and an image processing device arranged in association with the control device for taking an image of the object and processing image data acquired from taking the image of the object. The control device and the image processing device may work independently or collaboratively to send the database at least one of an attribute value or results information, and designation information in association with each other for the same object, the attribute value managed by the control device and corresponding to any attribute defined in the database, the results information representing a process result from the image processing device, and the designation information specifying a storage destination in the data storage area for the image data acquired from taking an image of the object.

A method of compressing signal data in an intelligent programmable logic controller includes the controller creating a process image area in a volatile computer-readable storage medium operably coupled to the controller. The intelligent programmable logic controller updates the process image area with contents comprising signal data associated with a production unit and applies a compression algorithm to the contents to generate compressed signal data. The compressed signal data is stored on a non-volatile computer-readable storage medium operably coupled to the controller. The controller annotates the signal data with automation system context information to generate contextualized data. Next, the controller performs a statistical comparison of the signal data and the compressed signal data to generate statistical comparison results. Then, one or more compression parameters used by the compression algorithm may be automatically adjusted based on at least one of the statistical comparison and the contextualized data.

To more effectively utilize data related to machining by a machine tool. An integrated machining system includes: a database that stores, as hierarchized structured data, production data related to steps from design until machining, including data of machining commands to be executed by a machine tool, and data of machining history corresponding to the data of machining commands; and a production data management device that includes a provided information generation unit that generates provided information to be provided externally, by way of acquiring at least either of the data of machining commands and the data of machining history from the database, and referencing a hierarchized structure to acquire elements of data related to specific information.

An industrial monitoring system is disclosed. In an embodiment it includes a device layer, a device driving layer, a data sharing layer, a data routing layer, a data scheduling layer, a service layer, and a presentation layer. The data sharing layer, the data routing layer, and the data scheduling layer are organized by using a non-relational database, or organized in a hybrid way by using the non-relational database and a relational database. The industrial monitoring system disclosed can implement processing such as real-time storage and sharing of a large amount of data, and data mining and retrieval.

A system for managing data in an industrial production environment includes a distributed database system stored on a plurality of embedded controller devices. Each respective embedded controller device comprises: a distributed database instance and a database management application. The distributed database instance is configured to store data collected from the industrial production environment by the respective embedded controller device. The database management application is configured to facilitate distributed queries and transactions on the plurality of embedded controller devices.