A method and machine for automating the layer-by-layer manufacturing of an object according to a solid-solid additive manufacturing method, includes a vacuum table and at least one machining tool movably mounted above the table. The machine also includes a turning station having a cross member which is movable in a longitudinal direction above the table and in a vertical direction. There is a device gripping a plate mounted such that it can rotate about an axis parallel to the cross member. The machine also includes a device supporting a plate to allow the plate to be gripped on either of the two sides thereof by the device gripping the plate. There is an X and Y wedge device suitable for determining the position for, and positioning a plate, a set or a sheet.

An industrial data pipeline architecture described supports annotation of raw data streams into scalable and durable cloud-level storage. A dynamic data mapping process collects industrial data from data tags that have been annotated with metadata indicating that the tags are to be made available for visualization, and connects data from these tags to a data aggregator object of a node-level or edge-level visualization tool. The data aggregator object dynamically adjusts its data collection footprint to include the annotated data tags, which are dynamically associated with the physical layout of the industrial equipment in the visualization. Visualization objects for a specified plant configuration act as data context containers that can be added to a plant visualization panel, and allows the annotated tags to be selected to build visualizations of selected data items.

Disclosed is a system for collecting data from an automated plant having a field device connected for communication and for exchanging telegrams with a superordinate unit by means of a communication loop using a first protocol. The system includes a hat rail; and a terminal module mounted on the hat rail and embodied to monitor telegrams transmitted from the field device to the superordinate unit via the communication loop. The terminal module is further embodied to convert monitored telegrams into a second protocol and to output the converted telegrams. The system further includes a head module mounted on the hat rail and connected with the terminal module. The electronics unit of the head module is embodied to convert telegrams output from the terminal module into a third protocol to output them via the first network interface.

Example implementations described herein involve systems and methods that can involve extracting features from each of a plurality of time-series sensor data, the plurality of time-series sensor data associated with execution of one or more operations; clustering the extracted features into a plurality of tasks that occur from execution of the one or more operations, each of the plurality of tasks associated with a clustering identifier (ID) from the clustering; and calculating a cycle time of the cycle based on the initiation and end of the cycle recognized by referencing a cycle pattern model, wherein the cycle pattern model comprises configuration information of a cycle including a set from a plurality of the clustering IDs.

An industrial controller including a controller for controlling one or multiple field bus(es) in an automation system, first pieces of configuration information for configuring a communication link to a first cloud platform, second pieces of configuration information for configuring a communication link to a second cloud platform, and to for transfer process data of the automation system to the first and the second cloud platform.

A stored control program includes subperiods into which an operation period from a start to an end of an operation of an automated manufacturing machine is divided. Each subperiod is assigned with an actuator to act and action information about the actuator. The subperiods are sequentially selected one by one as a control target, and feedback control is performed on an action of the actuator assigned to the selected subperiod. This reduces the number of actuators controlled at the same time for controlling the operation of an automated manufacturing machine including many actuators. The control program can thus be executed promptly with an operation control apparatus having ordinary processing capability.

An interface arrangement for connecting at least one control device to a plurality of field instruments, includes: a carrier board having a plurality of signal channels, and a connector designed for electrical and mechanical connection to a second, complementary connector of a signal processing device, being arranged between a first and a second connecting device of each signal channel. Each signal channel has an electrical interface which is designed for releasable connection of respective surge protection modules, each interface electrically connected to an electrical resistor and to a surge arrester which is arranged at least partially on and/or in the carrier board and is designed for arresting surge voltages and/or surge currents which may occur.

A system and method for controlling automation includes a machine performing at least one operation and including a sensor for generating data in response to a performance of the operation by the machine. Data generated by the sensor is stored for retrieval by a server in data memory storage. The server includes at least one display template for displaying the data, and the server generates a data display by populating the at least one display template with the data. The data template can be populated with data in real time, to display the data display immediate to the generation of the data. The display template includes a data feature which is differentiated for displaying the data feature in a mode determined by the data populating the data display. The data display can be displayed in real time by a user device in communication with the server.

A method for configuring peer-to-peer communication in an industrial automation system including at least two control devices, each control device being arranged for hosting as separate instances an OPC UA server, an OPC UA subscriber service, and an OPC UA publisher service, the method including retrieving an OPC UA object list for each control device, the object list indicating all OPC UA objects managed by each respective control device, and presenting the OPC UA objects and control devices for user input. The method further including obtaining user input, configuring for each control device publisher and subscriber service parameters in a configuration file for each respective control device, and transferring the configuration file to the publisher and subscriber services of each respective control device. Also disclosed are an industrial automation system and industrial control devices configured to implement the disclosed method.

A method for enabling automation templates as a service for data processing includes: receiving a selection of an automation template among automation templates available for performing an automation request; retrieving, from a cloud system, an inputs form template corresponding to the selected automation template; receiving inputs to be inputted to the inputs form template; submitting, to the cloud system, the inputs form to trigger an automation execution based on the selected automation template and the inputs form; performing data ingestion based on input data sources specified in the inputs form and pre-defined set of rules specified in the selected automation template; executing an automation process based on a pre-defined set of calculations, transformations, and/or arrangements specified in the automation template; and pushing results of the executing based on destination information specified in the inputs form and the pre-defined set of rules specified in the automation template.