The disclosure relates to a device for a packaging process, wherein the device is provided in the form of a step-by-step packaging machine, or is configured as a step-by-step packaging line. The device is configured to perform a recipe change from a first packaging recipe to another, second packaging recipe step by step at a plurality of work stations provided on the device. Furthermore, the disclosure relates to a corresponding method.

Method for manufacturing a workpiece with a predefined sequence of machine tools by a computer-controlled manufacturing machine with an optimal tool configuration, wherein the initial locations of the tools are allocated, first and second time transfer time functions are calculated for all tools, possible tool location sequences are generated, for possible tool location sequences a respective first cost factor is calculated, obtained tool location sequences are ranked in accordance with the respective first cost factor, the tools are transferred from their initial locations to the optimal locations in accordance with an optimal tool configuration, and the workpiece is manufactured with the optimal tool configuration by the manufacturing machine.

Systems and methods for distributed weld monitoring using jobs and job sessions are described. In some examples, a distributed monitoring system comprises a central monitoring station in communication with a user device and a local monitoring station. A user may use the user device to enter weld monitoring data that is subsequently received by the central monitoring station and stored in a central data repository. The central data repository may associate the weld monitoring data with welding data received from a welding device, as well as with a job session that is, in turn, associated with a job.

A task assistance device assists a worker who performs tasks by a predetermined task procedure, the tasks including: a first task with a first driver that is state-switchable between usable and unusable; and a second task performed by the worker without the first driver. The task assistance device includes: a communicator that obtains a start signal indicating a start and an end signal indicating an end of each task; a generator that generates a first control signal that makes the first driver usable when the communicator obtains the start signal of the first task and/or the end signal of the second task, and generates a second control signal that makes the first driver unusable when the communicator obtains at least one of the end signal of the first task or the start signal of the second task; and a communicator that outputs the first control signal and the second control signal generated by the generator to the first driver.

The information projection system includes stereo cameras, a controller, and projectors. The controller has a communication device, an analysis unit, a registration unit, and a projection control unit. The communication device acquires sets of appearance information in which each stereo camera detects an appearance of a workplace. The analysis unit analyzes the sets of appearance information, and creates a map information indicating shapes and positions of objects existing in the workplace. The registration unit creates and registers a work status information based on the map information that is individually created from the sets of appearance information respectively detected by the plurality of stereo cameras. The projection control unit creates an auxiliary image for assisting a work based on the work status information, and outputs the auxiliary image to each projector.

Provided is a work management system enabling real-time inspection by simultaneously performing work and measurements. The work management system includes a tool including a communication unit and a trigger switch, a camera unit including a communication unit, a camera capable of identifying 3D camera coordinates from an image, a posture detecting device configured to acquire camera posture information, a control unit, and a prism, and a surveying instrument including a communication unit, a tracking unit, a distance-measuring unit, an angle-measuring unit, and a control unit, wherein upon detection that the trigger switch has been used, the camera unit collects camera posture information by the posture detecting device, a tool image by the camera, position coordinates of the prism measured by the surveying instrument, and orientation information of the camera unit viewed from the surveying instrument, and obtains and stores position coordinates of a tip end position of the tool.

One embodiment provides a method, including: obtaining historical information for equipment having at least one control, wherein the historical information indicates a setting for the at least one control during operation of the equipment and identifies operating performance of the equipment corresponding to the indicated setting; receiving a goal for the equipment, wherein the goal is related to a desired operating performance of the equipment; identifying, a plurality of sets of contiguous good reference segments, wherein a contiguous set of good reference segments comprises a plurality of operating time segments where the desired operating performance goal was achieved for a predetermined of time; identifying, a subset of sets comprising reference segments that are achievable from a current operating state of the equipment; selecting, a reference segment that is attainable based upon exogenous factors related to an operating environment of the equipment; and providing a recommendation to an operator of the equipment.

System and method for facilitating engineering of an industrial system (250) are disclosed. The method comprising: generating a query (306) based on at least one of a user input and a user interaction with a Graphical User Interface (GUI) configured to enable engineering of the industrial system (250); mapping the query (306) to a knowledge database (140, 240) comprising engineering-data generated across multi-disciplinary platforms associated with at least one of design, engineering, commissioning, operation and maintenance of the industrial system (250), wherein the engineering-data is made available by one or more crawlers (122, 222-228) associated with the multi-disciplinary platforms and wherein the engineering-data is indexed in the knowledge database (140, 240) based on an engineering ontology of the industrial system (250); and displaying a notification (116, 172) on the GUI with a response the query (306), consequent to at least one of the user input and the user interaction, wherein the response comprises at least a list (174) of engineering-data related to the query (306), wherein the notification comprises at least recommendation to further engineering of the industrial system (250).

A method for improving a cycle time of a process of a product is provided. The method includes: collecting process profile data from a plurality of tool groups running the process, and calculating values of a plurality of key-performance-indicators (KPIs) of each tool group including calculating a standard deviation of an output of a stage of a bottleneck tool group of the tool groups; feeding the values of the KPIs and a work-in-progress (WIP) of each tool group into a neural network model in order to output an impact on the WIP for each KPI of each tool group by the neural network model; selecting a set of major KPIs of each tool group from the KPIs according to the impact of each tool group; and controlling the tool groups according to the impact of the set of major KPIs of each tool group in order to reduce a total WIP.

A method may include generating visualizations via a control system that controls one or more operations of one or more industrial devices. Each of the visualizations is representative of one or more live operational parameters associated with the one or more industrial devices. The method may also include continuously streaming one or more of the visualizations to a first computing system via the control system and receiving the one or more of the visualizations via a second computing system. Additionally, the method may include identifying one or more data fields in the one or more of the visualizations and retrieving values from each of the one or more data fields over a period of time via the second computing system. Each value may correspond to one or more frames of image data including the one or more of the visualizations. Furthermore, the method may include storing the values in a database.